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Characterising the mechanics of cell–cell adhesion in plants

Published online by Cambridge University Press:  15 February 2022

Asal Atakhani
Affiliation:
Department of Forest Genetics and Plant Physiology, Umeå Plant Science Centre, Swedish University of Agricultural Sciences, Umeå, Sweden
Léa Bogdziewiez
Affiliation:
Department of Forest Genetics and Plant Physiology, Umeå Plant Science Centre, Swedish University of Agricultural Sciences, Umeå, Sweden
Stéphane Verger*
Affiliation:
Department of Forest Genetics and Plant Physiology, Umeå Plant Science Centre, Swedish University of Agricultural Sciences, Umeå, Sweden
*
Author for correspondence: S. Verger, E-mail: [email protected]

Abstract

Cell–cell adhesion is a fundamental feature of multicellular organisms. To ensure multicellular integrity, adhesion needs to be tightly controlled and maintained. In plants, cell–cell adhesion remains poorly understood. Here, we argue that to be able to understand how cell–cell adhesion works in plants, we need to understand and quantitatively measure the mechanics behind it. We first introduce cell–cell adhesion in the context of multicellularity, briefly explain the notions of adhesion strength, work and energy and present the current knowledge concerning the mechanisms of cell–cell adhesion in plants. Because still relatively little is known in plants, we then turn to animals, but also algae, bacteria, yeast and fungi, and examine how adhesion works and how it can be quantitatively measured in these systems. From this, we explore how the mechanics of cell adhesion could be quantitatively characterised in plants, opening future perspectives for understanding plant multicellularity.

Type
Review
Creative Commons
Creative Common License - CCCreative Common License - BY
This is an Open Access article, distributed under the terms of the Creative Commons Attribution licence (https://creativecommons.org/licenses/by/4.0/), which permits unrestricted re-use, distribution, and reproduction in any medium, provided the original work is properly cited.
Copyright
© The Author(s), 2022. Published by Cambridge University Press in association with The John Innes Centre

1. Multicellularity and cell-adhesion mechanics

All living organisms are exposed to physical stresses such as tension and compression, that are experienced during growth and development, or imposed by external stimuli. At the supracellular level, tension has been found to pull adjacent cells apart in mutant organisms in which the proper control of cell–cell adhesion is defective (Thomas et al., Reference Thomas, Boscher, Chu, Cuvelier, Martinez-Rico, Seddiki, Heysch, Ladoux, Thiery, Mege and Dufour2013; Verger et al., Reference Verger, Long, Boudaoud and Hamant2018). However, living organisms have evolved mechanisms to continuously respond and adapt to these mechanical forces to ensure the maintenance of their cellular and supracellular integrity (Hamant & Saunders, Reference Hamant and Saunders2020; Hannezo & Heisenberg, Reference Hannezo and Heisenberg2019; Trinh et al., Reference Trinh, Alonso-Serra, Asaoka, Colin, Cortes, Malivert, Takatani, Zhao, Traas, Trehin and Hamant2021). In turn, cell–cell adhesion not only enables adjacent cells to stick to each other in a passive manner, but it is also dynamically controlled and maintained over time during growth and development (Baum & Georgiou, Reference Baum and Georgiou2011; Leckband & de Rooij, Reference Leckband and de Rooij2014; Yap et al., Reference Yap, Duszyc and Viasnoff2018). The precise fine-tuning of adhesion tightening and loosening ensures tissue cohesion and integrity while allowing cell migration (in animals) or, for example, intrusive cell growth (e.g., fibre cell elongation in wood formation; Gorshkova et al., Reference Gorshkova, Brutch, Chabbert, Deyholos, Hayashi, Lev-Yadun, Mellerowicz, Morvan, Neutelings and Pilate2012; Marsollier & Ingram, Reference Marsollier and Ingram2018), developmentally controlled organ abscission (e.g., leaf or petal shedding in plants; Olsson & Butenko, Reference Olsson and Butenko2018) and cell separation (e.g., lateral root emergence, root cap shedding or intercellular space formation; Stoeckle et al., Reference Stoeckle, Thellmann and Vermeer2018) in plants. Understanding the mechanics of cell adhesion and how adhesion resists and adapts to separating forces is thus crucial to understand how multicellularity is successfully achieved through cell adhesion.

2. Cell-adhesion mechanics: strength, work and energy

The physics of adhesion is highly studied for a number of industrial applications, and some of this well-established knowledge can also be applied to the question of cell adhesion in living organisms (Creton & Ciccotti, Reference Creton and Ciccotti2016; Packham, Reference Packham2017). When characterising adhesion mechanics, it is common to refer to the term adhesion ‘strength’, but adhesion ‘work’ and ‘energy’ are two other parameters describing the adhesion mechanics that should also be considered. A first estimation of adhesion mechanics (strength and work) can be obtained by simply pulling apart the adhesive cells and measuring the force required to separate them. Strictly speaking, it isin fact not directly a measure of the adhesion; instead, adhesion mechanics is inferred from measuring the de-adhesion. When performing a de-adhesion experiment, both the amount of force applied and the deformation of the cells can be measured, extracting the relation of the exerted force due to the applied displacement. Using the geometry of the sample and the values of force and displacement, a stress–strain curve can be generated (Figure 1a,b). From this curve, both adhesion strength and work can be calculated. The de-adhesion strength is determined by the maximal (ultimate) stress that was applied before the cells separated (Figure 1b). De-adhesion work corresponds to the energy that is transferred to the sample during the stretching. It is a function of both the amount of force and displacement (pulling) and is thus calculated as the area under the stress–strain curve of the de-adhesion experiment (Figure 1b). By contrast, the adhesion energy, which corresponds to the force generated by the molecular bonds formed between the cells, is not directly measurable with these approaches (Maître & Heisenberg, Reference Maître and Heisenberg2011; Sackmann & Smith, Reference Sackmann and Smith2014; Winklbauer, Reference Winklbauer2015). Although it is in principle possible to infer the de-adhesion energy from a pulling experiment (Figure 1c), when energy is transferred to the sample by stretching, much of this energy can be dissipated in elastic and plastic deformation (extension) of the sample. The energy is either temporarily stored in the elastic deformation, or consumed in breaking molecular bonds within the sample, creating irreversible extension rather than separation at the cell–cell interface (Arroyo & Trepat, Reference Arroyo and Trepat2017). Other factors such as cell geometry and pre-existing stress can further contribute positively or negatively in dissipating the stress (da Silva et al., Reference da Silva, Öchsner and Adams2018; Lenne et al., Reference Lenne, Rupprecht and Viasnoff2021). It is thus complex to separate the effect of stress dissipation and infer the underlying de-adhesion energy and further the adhesion energy. Models from soft matter physics of adhesion have been proposed to predict adhesion energy in living cells, where cells are approximated to solid homogeneous spheres (Brochard-Wyart & de Gennes, Reference Brochard-Wyart and de Gennes2009; Chu et al., Reference Chu, Dufour, Thiery, Perez and Pincet2005).

Fig. 1. Mechanics of cell adhesion. (a) Force, stress and strain. When a force (orange arrow) is applied on an object, it generates a mechanical stress and a strain (deformation). The stress corresponds to the ratio of the force F applied to the cross-sectional area A of the object on which the force is applied. The strain is the ratio of the elongation ΔL of the object to the original length L 0 of the object. (b) De-adhesion strength and work. When a doublet of cells is stretched apart, the cells are deformed (strain) and the stress in the sample increases until the stress is high enough to break the links between the cells. The maximal amount of stress applied before the cells detached from each other corresponds to the de-adhesion strength (blue dashed line). The area under the stress–strain curve is measured as the de-adhesion work (blue hatched area). After separation, the cell shape can be changed due to their plasticity. (c) Adhesion energy can in principle be deduced from the work of de-adhesion by considering stress dissipation.

Because we know very little about the mechanics of cell–cell adhesion in plants, in this review, our aim is to explore our knowledge of cell adhesion in general and hypothesise on how the mechanics of adhesion could be quantitatively characterised in plants.

3. Cell–cell adhesion in plants

Adhesion between plant cells is mediated by their cell walls (Figure 2; Bou Daher & Braybrook, Reference Bou Daher and Braybrook2015; Jarvis et al., Reference Jarvis, Briggs and Knox2003; Knox, Reference Knox1992). While adhesion is first established during cell division, each cell then synthesises its own cell wall through the secretion of polysaccharides (cellulose, hemicelluloses and pectins) and structural glycoproteins (Anderson & Kieber, Reference Anderson and Kieber2020), creating a layered structure with a pectin-rich middle lamella between the walls of adjacent cells (Zamil & Geitmann, Reference Zamil and Geitmann2017). Beyond the middle lamella, tricellular junction and the edges of partially separated cells may represent mechanical hotspots in which mechanical stress is focused and adhesion is specifically reinforced (Jarvis, Reference Jarvis1998; Roland, Reference Roland1978; Willats et al., Reference Willats, Orfila, Limberg, Buchholt, van Alebeek, Voragen, Marcus, Christensen, Mikkelsen, Murray and Knox2001). On the other hand, while strategically located, the contribution of plasmodesmata (intercellular channels) for cell–cell adhesion strength remains to be characterised. Overall, the cross-linking of the cell wall polysaccharides creates a continuous polysaccharide network that ensures cell–cell adhesion (Figure 2; Anderson & Kieber, Reference Anderson and Kieber2020). Nevertheless, pectins, which are the main constituents of the middle lamella, are generally considered to be the main determinant of cell adhesion in the early stage of tissue growth and development (Bou Daher & Braybrook, Reference Bou Daher and Braybrook2015). Pectins are, in fact, a complex set of polysaccharides mainly composed of homogalacturonans (HGs), rhamnogalacturonans I, and rhamnogalacturonans II (RGIIs; Anderson, Reference Anderson2019). The HG is a linear chain of galacturonic acids (GalAs) that is synthesised in a highly methyl esterified form, and that can be de-esterified after secretion to the cell wall by proteins called pectin methylesterases (Hocq et al., Reference Hocq, Pelloux and Lefebvre2017). The de-esterification process leaves negatively charged residues on the GalAs, and if more than 9 consecutive de-esterified GalAs are present, they can form calcium-mediated bridges with another de-esterified HG under the so-called egg-box conformation, effectively cross-linking independent HG chains potentially coming from adjacent cells (Huxham et al., Reference Huxham, Jarvis, Shakespeare, Dover, Johnson, Knox and Seymour1999; Jarvis & Apperley, Reference Jarvis and Apperley1995; Liners et al., Reference Liners, Letesson, Didembourg and Van Cutsem1989; Willats et al., Reference Willats, Orfila, Limberg, Buchholt, van Alebeek, Voragen, Marcus, Christensen, Mikkelsen, Murray and Knox2001). Similarly, RGII, a very complex polysaccharide (Bar-Peled et al., Reference Bar-Peled, Urbanowicz and O’Neill2012), also allows cross-linking of polymers through dimerisation mediated by the presence of Boron (O’Neill et al., Reference O’Neill, Eberhard, Albersheim and Darvill2001). The importance of these types of cross-linking for cell adhesion has been supported by the characterisation of cell-adhesion defective mutants. For instance, in Arabidopsis, several mutations in genes involved in HG synthesis (Bouton et al., Reference Bouton, Leboeuf, Mouille, Leydecker, Talbotec, Granier, Lahaye, Höfte and Truong2002; Du et al., Reference Du, Kirui, Huang, Wang, Barnes, Kiemle, Zheng, Rui, Ruan, Qi, Kim, Wang, Cosgrove, Anderson and Xiao2020; Lathe et al., Reference Lathe, McFarlane, Khan, Ebert, Ramírez-Rodríguez, Noord, Bhalerao and Persson2021; Mouille et al., Reference Mouille, Ralet, Cavelier, Eland, Effroy, Hématy, McCartney, Truong, Gaudon, Thibault, Marchant and Höfte2007; Temple et al., Reference Temple, Phyo, Yang, Lyczakowski, Echevarría-Poza, Yakunin, Parra-Rojas, Terrett, Saez-Aguayo, Dupree, Orellana, Hong and Dupree2021), remodelling (Francis et al., Reference Francis, Lam and Copenhaver2006; Lionetti et al., Reference Lionetti, Cervone and De Lorenzo2015) or degradation (Ogawa et al., Reference Ogawa, Kay, Wilson and Swain2009; Rhee et al., Reference Rhee, Osborne, Poindexter and Somerville2003; Rui et al., Reference Rui, Chen, Yi, Purzycki, Puri and Anderson2019) harbour cell-adhesion phenotypes (loss of cell adhesion or incapacity of cell separation). Furthermore, selectively digesting the cell wall with pectin degrading enzymes, such as polygalacturonases, and even chelating the cell wall calcium with chelators, such as EDTA, can also lead to cell separation (Letham, Reference Letham1960; McCartney & Knox, Reference McCartney and Knox2002; Ng et al., Reference Ng, Parker, Parr, Saunders, Smith and Waldron2000; Zhang et al., Reference Zhang, Henriksson and Johansson2000). However, not all cell types can be separated with these approaches (McCartney & Knox, Reference McCartney and Knox2002). Different tissues, cell types and even cell faces have significantly different cell wall compositions, and adhesion in those different contexts may rely on a different combination of polysaccharides and cross-links. Other work suggests that these are not the only molecular links that are responsible for cell adhesion and ferulic acids (Ng et al., Reference Ng, Greenshields and Waldron1997) as well as xyloglucan-like polysaccharide may, for instance, be involved (Ikegaya et al., Reference Ikegaya, Hayashi, Kaku, Iwata, Sonobe and Shimmen2008; Ordaz-Ortiz et al., Reference Ordaz-Ortiz, Marcus and Paul Knox2009). Furthermore, during abscission events, many cell wall remodelling enzymes, other than pectin degrading enzymes, get expressed and likely act in concert with the pectin degrading enzymes to promote cell separation (Cai & Lashbrook, Reference Cai and Lashbrook2008; Lashbrook & Cai, Reference Lashbrook and Cai2008; Meir et al., Reference Meir, Philosoph-Hadas, Sundaresan, Selvaraj, Burd, Ophir, Kochanek, Reid, Jiang and Lers2010). The recent isolation and characterisation of the suppressor of an Arabidopsis mutant deficient in HG and showing cell-adhesion defect also revealed that adhesion could be restored without directly compensating for the HG deficiency in the cell wall (Verger et al., Reference Verger, Chabout, Gineau and Mouille2016). The loss of cell adhesion in these HG-deficient mutants may instead be largely due to secondary responses to cell wall integrity defects and further cell wall degradation (Du et al., Reference Du, Kirui, Huang, Wang, Barnes, Kiemle, Zheng, Rui, Ruan, Qi, Kim, Wang, Cosgrove, Anderson and Xiao2020). Thus, other components and cross-links in the primary cell wall likely also play an important role in cell–cell adhesion. Although much less described, when transitioning to secondary cell wall formation, the pectins appear to be largely replaced by lignins which in turn take up the role of keeping the cells attached (Ciesielski et al., Reference Ciesielski, Resch, Hewetson, Killgore, Curtin, Anderson, Chiaramonti, Hurley, Sanders, Himmel, Chapple, Mosier and Donohoe2014; Li & Chapple, Reference Li and Chapple2010; Yang et al., Reference Yang, Benatti, Karve, Fox, Meilan, Carpita and McCann2020). Similarly, other plant species, like most grass, have cell walls that contain very small amounts of pectins, such that adhesion should rely on different types of cross-links in these plants. Overall, a number of studies have started to investigate the chemical basis of cell adhesion. Furthermore, many of the cell wall properties and modifications identified as playing a role in adhesion have been correlated in other studies with specific mechanical properties (Grones et al., Reference Grones, Raggi and Robert2019; Zhang et al., Reference Zhang, Tang, Vavylonis and Cosgrove2019). For instance, de-esterification of the HG can lead to a stiffening of the cell wall due to increased calcium mediated cross-linking and could thus correlate with a stronger adhesion (Willats et al., Reference Willats, Orfila, Limberg, Buchholt, van Alebeek, Voragen, Marcus, Christensen, Mikkelsen, Murray and Knox2001). On the other hand, pectin de-esterification has also been associated with cell wall softening (Peaucelle et al., Reference Peaucelle, Braybrook, Le Guillou, Bron, Kuhlemeier and Höfte2011; Wang et al., Reference Wang, Wilson and Cosgrove2020). This could be a consequence of a higher susceptibility of de-esterified HG to pectin degrading enzymes [e.g., polygalacturonases (PGs)] or result from electrostatic repulsion of the carboxyl groups (Cosgrove & Anderson, Reference Cosgrove and Anderson2020; Haas et al., Reference Haas, Wightman, Meyerowitz and Peaucelle2020; Reference Haas, Wightman, Peaucelle and Höfte2021; Wang et al., Reference Wang, Wilson and Cosgrove2020). Thus, while pectin digestion by PGs would lead to cell separation, cell wall softening without HG degradation could instead make the cell–cell connection more elastic and resilient to external stress and strain (da Silva et al., Reference da Silva, Öchsner and Adams2018). Similarly, while increased calcium-mediated cross-linking is intuitively expected to make adhesion stronger, the matrix stiffening could instead make the cell–cell interface more brittle and increase the risk of cell wall fracture and cell separation. However, at this point, it remains very difficult to predict how chemical modifications of the cell wall affect the mechanical properties of the cell wall (Zhang et al., Reference Zhang, Zheng and Cosgrove2016) and furthermore how the mechanical properties of the cell wall affect adhesion strength, work and energy.

Fig. 2. Adhesion in plant and animal cells. The top drawings represent cell doublets, and the bottom drawings are close-up representations of the edge of the cell–cell interface. In both plant (left) and animal (right) cells, the cell shape is governed by an equilibrium between the internal hydrostatic pressure and the cortical tension. The plant cell adhesion is mediated by a cell wall mostly composed of cellulose and matrix polysaccharides. At the interface, the middle lamella is enriched in pectins and believed to play an important role in adhesion. The animal cell adhesion is mediated via proteins located at the plasma membrane. Cell-adhesion molecules are linked to the actin cytoskeleton which contributes to the cortical tension.

Beyond direct cell wall regulators, a number of molecular players are known to be involved in the regulation of cell-adhesion maintenance and developmentally regulated cell separation. So far, most interest has been given to the signalling events leading to cell separation (Olsson & Butenko, Reference Olsson and Butenko2018). Briefly, patterning transcription factors define abscission and dehiscence zones (Mao et al., Reference Mao, Begum, Chuang, Budiman, Szymkowiak, Irish and Wing2000), and auxin and ethylene act, respectively, as inhibitors and activators of the abscission process (Meir et al., Reference Meir, Philosoph-Hadas, Sundaresan, Selvaraj, Burd, Ophir, Kochanek, Reid, Jiang and Lers2010), which is then regulated by small peptides and receptor-like kinase signalling (Stenvik et al., Reference Stenvik, Tandstad, Guo, Shi, Kristiansen, Holmgren, Clark, Aalen and Butenko2008). This triggers a mitogen-activated protein (MAP) kinase signalling cascade which ultimately activates transcription factors that promote the expression of cell wall remodelling enzymes leading to cell wall digestion and cell separation (Shi et al., Reference Shi, Stenvik, Vie, Bones, Pautot, Proveniers, Aalen and Butenko2011). On the other hand, much less is known about the molecular mechanisms that contribute to maintaining cell adhesion during growth and development, but the isolation of various cell-adhesion defective mutants brings some clues. For instance, in Arabidopsis, mutants defective in actin filament nucleation (Le et al., Reference Le, El-Assal, Basu, Saad and Szymanski2003; Mathur et al., Reference Mathur, Mathur, Kernebeck and Hülskamp2003a; Reference Mathur, Mathur, Kirik, Kernebeck, Srinivas and Hülskamp2003b; Qiu et al., Reference Qiu, Jilk, Marks and Szymanski2002; Saedler et al., Reference Saedler, Zimmermann, Mutondo and Hülskamp2004), a putative mechanosensitive calcium channel (Galletti et al., Reference Galletti, Johnson, Scofield, San-Bento, Watt, Murray and Ingram2015; Tran et al., Reference Tran, Galletti, Neumann, Dubois, Sharif-Naeini, Geitmann, Frachisse, Hamant and Ingram2017) and epidermal identity transcription factors (Abe et al., Reference Abe, Katsumata, Komeda and Takahashi2003), show cell-adhesion defects. Interestingly, these mutants hint at a complex regulation of cell-adhesion maintenance through mechanical feedback as well as developmental control. Much remains to be clarified about the actual mechanochemical basis of cell–cell adhesion in plants. On the other hand, our understanding of cell adhesion in animals is much more advanced in part due to the existence of quantitative micromechanical methods to measure cell-adhesion mechanics.

4. Cell adhesion in animals, fungi, bacteria and algae

In animals, cell–cell and cell–substrate adhesion is primarily mediated by a group of proteins called cell-adhesion molecules (CAMs), that includes the cadherins (Halbleib & Nelson, Reference Halbleib and Nelson2006; Leckband & de Rooij, Reference Leckband and de Rooij2014) and integrins (Iwamoto & Calderwood, Reference Iwamoto and Calderwood2015; Lodish et al., Reference Lodish, Berk, Kaiser, Kaiser, Krieger, Scott, Bretscher, Ploegh and Matsudaira2008; Roberts et al., Reference Roberts, Alberts, Johnson, Lewis, Raff and Walter2002). The CAMs are transmembrane proteins that harbour an extracellular domain at the surface of the cell, that can either bind to another CAM, the extracellular matrix or a substrate (Figure 2). They organise in patches called cell junctions that are responsible for cell–cell and cell–substrate adhesion, and mediate the dynamics of motile cells. During cell–cell adhesion, the cadherins also interact with the actin network through the catenins and vinculin (Halbleib & Nelson, Reference Halbleib and Nelson2006; Harris & Tepass, Reference Harris and Tepass2010; Hartsock & Nelson, Reference Hartsock and Nelson2008). Together they form a mechanosensing complex sensitive to intrinsic (actin/myosin contractility) and extrinsic mechanical signals (Yap et al., Reference Yap, Duszyc and Viasnoff2018). Any force in the range of 5 pN, such as the force generated by the movement of myosin II motor in the cytoskeleton, can cause a conformational change of the α-catenin and increase the affinity to vinculin. The recruited vinculin promotes actin nucleation and the recruitment of additional cadherins, which changes the cell’s mechanical properties and cell-adhesion strength (Pinheiro & Bellaïche, Reference Pinheiro and Bellaïche2018; Yap et al., Reference Yap, Duszyc and Viasnoff2018). But comparing the cadherin binding energy (5 × 10−20 J per cadherin) to the cell–cell binding energy (0.02–4.1 mJ/m2) reveals the need for essential factors to justify the adhesion strength as the role of cadherin–cadherin junctions are less than 30%. The cadherin–cadherin adhesion tension is just enough to create contacts between the cells. Studying the cell junctions showed that the adhesion strength is either due to an increased overall cortical tension or the increase in cadherin density in the cortex (Winklbauer, Reference Winklbauer2015). In parallel to cell–cell adhesion, during cell–substrate adhesion, integrins interact with the substrate as well as with actin network through the talin and vinculin (Zamir & Geiger, Reference Zamir and Geiger2013). As for cell–cell adhesion, tension induces adhesion strengthening leading to the formation of focal adhesions sites at the end of so-called actin stress fibres (Haase et al. Reference Haase, Al-Rekabi and Pelling2014; Harris et al., Reference Harris, Peter, Bellis, Baum, Kabla and Charras2012; Kuo, Reference Kuo2014; Rosen & Dube, Reference Rosen and Dube2006). For more detailed information on the molecular mechanism of adhesion in animals, see Garcia and Gallant (Reference Garcia and Gallant2003), Harris and Tepass (Reference Harris and Tepass2010), Leckband and de Rooij (Reference Leckband and de Rooij2014) and Pinheiro and Bellaïche (Reference Pinheiro and Bellaïche2018).

Further away from the animal cells are fungi, bacteria and algae. Because of their cell wall, cell adhesion in these organisms may be more similar to plant cells. These organisms are found in the form of unicellular biofilms and multicellular organisms depending on the environmental conditions and species (Carpentier, Reference Carpentier2014; de Groot et al., Reference de Groot, Bader, de Boer, Weig and Chauhan2013; Hall-Stoodley et al., Reference Hall-Stoodley, Costerton and Stoodley2004; Nagy et al., Reference Nagy, Kovács and Krizsán2018; Raven & Giordano, Reference Raven and Giordano2014; Sheng et al., Reference Sheng, Ting and Pehkonen2007). In many of these organisms, cell–substrate adhesion has been intensively studied. In general, it is a two-stage process, starting with a passive adhesion followed by an active adhesion. The passive adhesion is the first stage of the attachment, and it is reversible (Jones, Reference Jones1994; Lebret et al., Reference Lebret, Thabard and Hellio2009; Razatos et al., Reference Razatos, Ong, Sharma and Georgiou1998). This is mediated by the pre-existing cell wall or extracellular matrix and happens due to the existence of Van der Waals Forces, short-range hydrophobic interactions, electrostatic interactions and hydrogen bonding between the cell wall and the substrate. In the active adhesion stage, the organisms further generate a glue-like substance in aqueous environments to enhance the adherence to the substrate or the host cell. There is a large diversity of components in the cell wall and the extracellular matrix of living organisms that can bind to and alter the substrate. This creates strong anchorage between an organism and its substrate or host cells (Epstein & Nicholson, Reference Epstein and Nicholson2016; Kostakioti et al., Reference Kostakioti, Hadjifrangiskou and Hultgren2013). For further information on the molecular mechanism of adhesion in fungi, bacteria and algae, see Nagy et al. (Reference Nagy, Kovács and Krizsán2018), Raven and Giordano (Reference Raven and Giordano2014) and Tuson and Weibel (Reference Tuson and Weibel2013).

Overall, research on the characterisation of cell–cell adhesion mechanics is already quite advanced concerning animal cells. Similarly, much research on mechanical characterisation of cell–substrate adhesion have been done in animals, bacteria, yeast, algae and fungi. On the other hand, mechanical and quantitative characterisation of cell adhesion in plants is largely lacking to date. The mechanics of adhesion is also different in principle from that of animal cells, since in plants and other walled organisms, adhesion is mediated by their large cell wall, whereas in animals, it is mediated by clusters of adhesion proteins located at the cell surface. During the de-adhesion process, walled cells may separate from crack initiation in the cell wall and propagation in a manner similar to a crack in a hydrogel (Arroyo & Trepat, Reference Arroyo and Trepat2017; Creton & Ciccotti, Reference Creton and Ciccotti2016) rather than by the dissociation of CAMs (proteins, e.g., cadherins). In plants, a distinct cell wall layer, the middle lamella (Zamil & Geitmann, Reference Zamil and Geitmann2017), plays the role of interface between adjacent cells, and when cells separate, such cracks may preferentially propagate along the middle lamella when it is weakened. Furthermore, compared to animals, adhesion in plants appears as a less dynamics process because it is mediated by their rigid cell wall. But adhesion in plants is not static as cells can detach, reattach and grow intrusively. Interestingly, the active stage of cell–substrate adhesion described for yeast, algae and fungi could share functional similarities with the mechanisms of cell–cell adhesion maintenance in plant or the mechanisms allowing plant grafting. In turn, unicellular green algae with cell wall composition similar to that of embryophytes (true plants) have been proposed as models to understand plant cell–cell adhesion (Domozych et al., Reference Domozych, Elliott, Kiemle and Gretz2007, Reference Domozych, Sørensen, Popper, Ochs, Andreas, Fangel, Pielach, Sacks, Brechka, Ruisi-Besares, Willats and Rose2014). As such, the methods applied to study cell–substrate adhesion in these ‘walled’ organisms could also be useful to understand cell–cell adhesion in plants.

5. Methods to quantify cell adhesion

5.1. Quantifying large-scale cell–substrate adhesion

Most of the early adhesion measurement methods that have been developed focused on measuring cell–substrate adhesion. They are based on applying shear stress on cells thanks to fluid flow or centrifugation and study a large number of cells at once to obtain a relative value for adhesion strength (i.e., percentage of cells detached by a given force). The plate-and-wash assay was the first quantitative method developed to measure cell-adhesion strength. In this method, the cells are placed in contact with a substrate for a certain time in order to let them adhere to the substrate (Klebe, Reference Klebe1974). Then a washing step is executed by removing the growth medium and replacing it with a new one. The flow created by the removal and addition of the medium creates shear stress that leads to the detachment of the least adhesive cells (Figure 3a). The number of cells attached is thus counted before and after this washing step. This technique gives a first idea of the adhesion between a cell type and a substrate; however, it lacks sensitivity, and the applied forces are weak and very difficult to control (Alam et al., Reference Alam, Kumar and Varadarajan2019). To contravene these limitations, more advanced fluidic-based assays have been developed (Figure 3). In the centrifugation assay, the sample and the substrate are placed in 96-well plates allowing multiple measurements at the same time. A controlled detachment force, perpendicular to the cell–substrate contact area, is applied directly on the cells removing the nonadherent cells from the substrate surface (Figure 3b). Again, the number of cells is counted before and after the application of a force which in this case can be calculated more precisely based on the properties of the centrifuge. In another type of approach based on hydrodynamic flow, a fluid flow passing in a channel over a large population of adherent cells creates a detachment shear force (Figure 3c; Garcia & Gallant, Reference Garcia and Gallant2003). In this case, the shear stress can also be determined precisely, and depends on the cross-sectional area of the channel containing the cells and through which the fluid is passing, the viscosity of the fluid and the flow rate (Ungai-Salánki et al., Reference Ungai-Salánki, Peter, Gerecsei, Orgovan, Horvath and Szabó2019). Several shapes of flow chambers exist like the radial flow chamber, the spinning disc or the parallel plate assay (Figure 3c; García et al., Reference García, Ducheyne and Boettiger1997; Kooten et al., Reference Kooten, Schakenraad, Mei and Busscher1992; Ungai-Salánki et al., Reference Ungai-Salánki, Peter, Gerecsei, Orgovan, Horvath and Szabó2019). More recently, microfluidic devices have replaced these flow chambers. Micrometer range channels ensure a laminar flow, and the microfabrication allows complex designs with multiple channels of increasing sizes which allows for a large range of fluid velocities, including high shear stress (Figure 3d; Christ et al., Reference Christ, Williamson, Masters and Turner2010; Lu et al., Reference Lu, Koo, Wang, Lauffenburger, Griffith and Jensen2004). This is a major improvement for this approach since many cell-adhesion measurement techniques are limited by the amount of force that can be applied to the cells. Overall, these methods have been proved very useful to understand cell–substrate adhesion and have been largely improved in terms of accuracy, but they are designed and often limited to the study of cell–substrate adhesion rather than cell–cell adhesion.

Fig. 3. Cell-adhesion quantification methods. (a) Plate and wash assay. After placing the cells in contact with the substrate for a period, the medium is replaced, removing the nonadherent cells. (b) Centrifugal assay. A 96-well plate is coated with a substrate. A cell suspension is added and allowed to adhere to the substrate. Then the wells are sealed, and the plate is spun at a specific speed and duration. (c) Hydrodynamic flow assays. (c1) The radial flow chamber. An outward radial flow. Different intensities of shear stress are applied on the cells depending on their position in the chamber according to a gradient inversely proportional to the radial position. (c2) The spinning disc assay uses a rotating flow to apply a hydrodynamic shear force on the sample. The cells are in contact with a substrate on a plate, which is rotating in a chamber containing liquid. The applied forces vary linearly with radial distance. (c3) The parallel plate. The cells are in a rectangular chamber, and a constant flow is maintained during one experiment. (d) Microfluidic chamber. The cells are in micrometre-range channels where a laminar flow is running. The smaller the channel is, the higher is the shear stress applied on the sample. (e) Cell shape-based imaging technique. The cell shape depends on an equilibrium between the internal hydrostatic pressure and the cortical tension. The strength of cell–cell adhesion can be deduced from the area of contact and the angle at the junction of cells. (f) Single-cell force spectroscopy. A cell is attached to the cantilever of an atomic force microscope then put in contact with a substrate. The cantilever first approaches and pushes the cell on the substrate. Then the cell is pulled from the surface. The adhesion force between the cell and the substrate will bend the cantilever until the cell detaches. A laser is reflected by the cantilever to a photodetector. This will draw a force curve giving information on the force of adhesion between the cell and the substrate. (g) Fluidic probe force microscopy. The same principle as the single-cell force spectroscopy, but the cantilever contains a microchannel that can suck the cell like a micropipette. (h) Step pressure assay. Two motorised micropipettes are connected to a microfluidic pump. First, the two cells are in contact to allow the adhesion. One micropipette keeps the cell in position with a high constant suction, whereas the other one pulls its cell away with a lower suction. If the adhesion is stronger than the measuring pipette suction, the cell will slip out the micropipette. The suction in this pipette is then increased until it is strong enough to separate the cells. (i) Extensometer used for tensile test. The tissue sample is held at each end and stretched with a specific force. The stretching and the tearing are monitored with microscopic observation. For additional information on the methods presented, including the quantitative/mathematical framework used to derive adhesion mechanics values, see Alam et al. (Reference Alam, Kumar and Varadarajan2019), Garcia and Gallant (Reference Garcia and Gallant2003) and Ungai-Salánki et al. (Reference Ungai-Salánki, Peter, Gerecsei, Orgovan, Horvath and Szabó2019).

5.2. Cell shape-based adhesion energy estimation

Computational imaging techniques can be used to study the cell–cell or cell–substrate adhesion mechanics in a noninvasive manner (Veldhuis et al., Reference Veldhuis, Ehsandar, Maître, Hiiragi, Cox and Brodland2017). They are based on studying the mechanical equilibrium between the cell’s cortical tension and adhesion (Figure 3e). More precisely, the cell’s hydrostatic pressure creates a cortical tension at the surface of the cell, such that a single cell tends to minimise its surface tension and therefore becomes spherical (Winklbauer, Reference Winklbauer2015). However, when two cells are attached to each other or a cell adheres to a substrate, a flat contact interface is formed where the adhesion takes place, which goes against minimising the cell’s surface tension. In this case, the adhesion energy is high enough to counteract the surface tension that would make the cell round. In turn, knowing the cortical tension and cell geometry, it is possible to deduce the adhesion energy when assuming the cells generally behave as fluids. This approach can be extended to a tissue where the cells still minimise their surface tension but are adherent to other cells and similarly the shape of the cells will then depend on an equilibrium of the adhesion and the cortical tension (Manning et al., Reference Manning, Foty, Steinberg and Schoetz2010; Veldhuis et al., Reference Veldhuis, Ehsandar, Maître, Hiiragi, Cox and Brodland2017; Winklbauer, Reference Winklbauer2015). Interestingly, with this approach and contrary to the other approaches that measure de-adhesion, it is directly the cell-adhesion energy that is predicted. However current methods depend on the assumption that cells behave like fluids.

5.3. Micromanipulation assays

Another range of techniques employs direct and precise cell micromanipulation, to grab, put cells in contact and pull them apart or from a substrate and measure the force necessary to do so. These uses either microaspiration of the cells with micropipettes or attachment of a cell to a cantilever. The dual pipette aspiration method uses a pair of micropipettes that can each grab a single cell by microaspiration. The two cells can then be placed in contact with each other for a given time to establish adhesion and then pulled apart to measure the adhesion that has developed (Sung et al., Reference Sung, Sung, Crimmins, Burakoff and Chien1986), while the manipulation takes place under a microscope to monitor the detachment of the cells. In recent implementations, the microaspiration is precisely controlled by microfluidic pumps providing negative pressure (suction) and the pipettes are held by motorised micromanipulators (Biro & Maître, Reference Biro and Maître2015). Adhesion strength is then measured using the step-pressure assay (Figure 3h). Once the cells adhere to each other, one micropipette is moved backwards to pull the cells apart. At low suction in the measuring pipette, the cell held by the measuring pipette will detach from it rather than from the other cell. In the next step, the measuring pipette is brought back to the cell, the suction inside the measuring micropipette is increased and the cells are pulled again. These cycles continue until the suction is strong enough to separate the cells. The minimal suction needed to detach the cells is then used to calculate a value for the de-adhesion strength. Another approach called single-cell force spectroscopy uses an atomic force microscope (AFM) to quantify cell de-adhesion strength and work. In single-cell force spectroscopy (SCFS), a cell is attached to an AFM cantilever (without tip) and then placed in contact with a substrate (tissue, cell or functionalised surface; Benoit et al., Reference Benoit, Gabriel, Gerisch and Gaub2000; Figure 3f). When attempting to detach the cell, the cantilever is first bent as the pulling force increases until the force is high enough to detach the cell and the cantilever then regains its original shape. The AFM measures this bending by quantifying the deflection of a laser pointed at the cantilever. In turn, knowing the spring constant of the cantilever, it is possible to calculate the force applied throughout the pulling experiment and derive a stress–strain curve from which the de-adhesion strength and work can be precisely calculated. The main difficulty of the SCFS is the necessity to coat the cantilever to attach the cell on it since the cell-cantilever adhesion must be higher than the cell–cell or cell–substrate adhesion and the coating can chemically disrupt the state of the cell and therefore modify its adhesion properties (Cohen et al., Reference Cohen, Sarkar, Hondroulis, Sabhachandani and Konry2017; Guillaume-Gentil et al., Reference Guillaume-Gentil, Potthoff, Ossola, Franz, Zambelli and Vorholt2014). This issue can be avoided by using fluidic probe force microscopy (Meister et al., Reference Meister, Gabi, Behr, Studer, Vörös, Niedermann, Bitterli, Polesel-Maris, Liley, Heinzelmann and Zambelli2009). In this case, the cantilever contains a microchannel and can thus act as a micropipette, which sucks the cell so that no coating of the cantilever is needed to hold the cell (Figure 3g). Overall, these micromanipulation techniques bring a much higher precision in the measurement of adhesion compared to the other methods described above but have a much lower throughput and are limited to the study of single cell–cell or cell–substrate adhesion.

5.4. Tissue-level measurements

Most of the methods existing to investigate the mechanics of cell adhesion are single-cell techniques. Measuring mechanical properties at the tissue level can be difficult because of the heterogeneity of the cells or extracellular material that compose a tissue, but a few methods exist. The 90° peel test method has been used on cell layers cultured on a substrate to measure the adhesion force of this cell layer to its substrate (Uesugi et al., Reference Uesugi, Akiyama, Hoshino, Akiyama, Yamato, Okano and Morishima2013). Tensile tests have also been developed to explore the mechanical properties of a tissue and have been applied to measure cell adhesion in the tissue context. For such methods, the sample is placed in an extensometer, a device that allows the stretching of the samples and a measurement of the load applied during stretching (Figure 3i). The sample is attached at its extremities and is then stretched while the deformations and cell detachments are monitored with a microscope (Harris et al., Reference Harris, Peter, Bellis, Baum, Kabla and Charras2012). Similarly, to the single-cell approaches, the tissue is stretched until the cells separate, and the de-adhesion strength is calculated locally from the observed strain and predicted stress during the stretching. While more complex to analyse, such a tissue-level approach brings more physiologically relevant information concerning cell–cell adhesion in the tissue context compared to single-cell approaches.

5.5. Cell-adhesion quantification methods in plants

While still very limited compared to other organisms, quantification of cell-adhesion mechanics has already been approached in plants. Following a method first established by Parker and Waldron (Reference Parker and Waldron1995), Leboeuf et al. (Reference Leboeuf, Thoiron and Lahaye2004) used ‘vortex-induced cell separation’ to study the differences in adhesion between Arabidopsis thaliana microcalli suspension cultures at several time points during growth. The method consists of measuring with a particle size analyser the size of cell clusters from in vitro cell cultures before and after vortexing at 40 Hz. However, this method remains rather imprecise, the force applied to detach the cells is not measured and it is not entirely clear whether cell clusters get fragmented because of cell detachments or cell ruptures. Tensile tests have also been used on plant samples to explore cell-adhesion establishment after grafting (Kawakatsu et al., Reference Kawakatsu, Sawai, Kurotani, Shiratake and Notaguchi2020; Lindsay et al., Reference Lindsay, Yeoman and Brown1974; Moore, Reference Moore1984; Notaguchi et al., Reference Notaguchi, Kurotani, Sato, Tabata, Kawakatsu, Okayasu, Sawai, Okada, Asahina, Ichihashi, Shirasu, Suzuki, Niwa and Higashiyama2020), but again it remains difficult to determine if cells are being separated or if tissues rupture. Melnyk et al. (Reference Melnyk, Gabel, Hardcastle, Robinson, Miyashima, Grosse and Meyerowitz2018) used an automated confocal micro-extensometer (ACME; Robinson et al., Reference Robinson, Huflejt, de Reuille, Braybrook, Schorderet, Reinhardt and Kuhlemeier2017) in such experiments to determine grafting adhesion. Since this device is coupled with a confocal microscope which allows live 3D imaging during the stretching, it revealed that indeed most cells at the grafting interface appear to break rather than separate when the sample is stretch until rupture, suggesting that cell adhesion of previously separated cells becomes stronger than the cohesive strength of the cell cortex (cell wall). Tensile tests have also been used at the level of the cell wall, in strips of microdissected onion outer epidermal cell wall containing cell–cell junctions (Zamil et al., Reference Zamil, Yi and Puri2014). Interestingly, it also revealed that the cell walls did not separate at the cell–cell junction but rather broke within the cell cortex. Another model of study of adhesion in plants is the pollen grain and its adhesion to a substrate or to the stigma. Jauh et al. (Reference Jauh, Eckard, Nothnagel and Lord1997) developed a method similar to the plate and wash assay to measure pollen adhesion on an artificial matrix. They blotted exudates from Lily (Lilium sp.) styles on nitrocellulose membranes and tested the adhesion of pollen grains after gently washing with a liquid buffer. Similarly, Zinkl et al. (Reference Zinkl, Zwiebel, Grier and Preuss1999) used a plate and wash-like liquid assay. They directly used unpollinated pistils, pollinated them and washed away the nonadherent pollen with a liquid buffer. While this method still lacks precision in terms of the force applied, they also developed a high-precision approach that resembles single-cell force spectroscopy to study pollen adhesion strength of a single pollen grain to the stigma. This system has similarities with the force measurement principle of an AFM but directly uses pistils to bind the pollen grain from each side. One pistil is maintained on a translation stage and serves as a substrate. Another pistil is glued to a glass fibre cantilever. A pollen grain is then placed in between the two stigmas, and the translation stage is moved away from the cantilever, while the bending of the cantilever is measured via a reflecting laser beam. When the force is too high for one of the pollen adhesion sites, the cantilever retracts and the adhesion strength can be determined. Finally, other researchers have approached the study of plant cell-adhesion mechanics form the modelling side by developing analytical models (Jarvis, Reference Jarvis1998) and finite element simulations of the middle lamella (Shafayet Zamil et al., Reference Shafayet Zamil, Yi and Puri2017) as well as de-adhesion mechanics (Diels et al., Reference Diels, Wang, Nicolai, Ramon and Smeets2019; Liedekerke et al., Reference Liedekerke, Ghysels, Tijskens, Samaey, Roose and Ramon2011) that were then compared with experimental data (Diels et al., Reference Diels, Wang, Nicolai, Ramon and Smeets2019). Overall, while these approaches have initiated the investigation of cell-adhesion mechanics measurements in plants, they are still either limited to a specific case (pollen, grafting), remain very imprecise in terms of the actual forces applied (vortex) or are theoretical (modelling). In the remainder of this review, we thus want to explore and hypothesise on the methods that could be implemented to precisely quantify cell–cell adhesion mechanics in plants.

6. Implementing cell-adhesion measurement methods in plants

Studying cell adhesion in plants brings additional challenges. Plants have large and relatively rigid cell walls which are under high tensions due to the high turgor pressure of the cells. Plants cells (with the exception of specific cases like pollen grains) do not seem to adhere specifically to substrates contrary to most animals, bacteria, algae and fungi. Furthermore, here our focus is to understand cell–cell adhesion in the context of multicellularity rather than to study how a plant cell would attach to a substrate. Nevertheless, many of the approaches presented above could in principle be adapted to study plant cell adhesion, including the cell–substrate adhesion quantification methods. As explained above, some versions of the plate and wash assay have already been applied to the study of pollen grain adhesion, but they will likely not be as straightforward to apply to other plant cell types. Similarly, important adaptations may be needed for hydrodynamic flow approaches. Indeed, in order to isolate single plant cells, it is necessary to first remove them from their tissue by digesting their cell wall. The protoplasts obtained are very fragile and lack the cell wall that is the structure that mediates cell adhesion in a physiological context. It is thus necessary to first wait for the cell wall to regenerate (Pasternak et al., Reference Pasternak, Paponov and Kondratenko2021). The adhesion of most plant cell types is actually cell–cell rather than cell–substrate, so another major adaptation will be the substrate to be used. A first possibility would be to use a live sample or a cell layer such as the inner side of an epidermal peel as a substrate for an approach similar to a plate and wash assay. However, this still brings the limitation of not being able to measure the actual force imposed on the cells during the washing step and may not be applicable to flow and microfluidic chamber approaches. Yet, it could still be a very useful approach to quantitatively compare adhesion of wild type and mutant cells or in response to treatments. An alternative would be to mimic an adjacent cell wall using purified cell wall components such as pectins, celluloses and hemicelluloses, cell wall extracts blotted on a nitrocellulose membrane or coated in flow or microfluidic chambers or even other artificial scaffolds as recently developed (Calcutt et al., Reference Calcutt, Vincent, Dean, Arinzeh and Dixit2021). While it remains to be determined whether such study of plant cell adhesion to a substrate would provide physiologically relevant information, using different substrates with different composition could be very informative to further understand the chemical determinants of cell adhesion and similarly to compare wild type, mutants and treatments in a context in which the force applied on a large number of cells can be precisely quantified.

The computational imaging-based techniques would be at first glance the easiest to apply to plant cells. Starting from isolated cells, it is possible to let the single cells divide and spontaneously form cell doublets. One important limitation, however, is that it is unlikely that we can consider plant cells with a regenerated cell wall to behave as liquid. In turn, the calculation of adhesion energy based on the shape and cortical tension of the cell doublet may not directly apply here. However, the observation of cell contact shape in wild type, mutants and treated samples could still be very informative (Calcutt et al., Reference Calcutt, Vincent, Dean, Arinzeh and Dixit2021). The cell doublets could be trapped in microfluidics chambers allowing time-lapse live observation while changing the osmolarity of the medium and thus the turgor pressure and cell wall tensions. Increases in cortical cell wall tension could in principle force the cells into more spherical shapes and induce partial separations. Using finite element simulation of the system and considering measurable physical properties, such as cell wall elasticity, plasticity, thickness, turgor pressure, cell shapes and strain, following the changes of pressure, could generate an informative prediction of the local stresses in the cell wall and at the cell–cell interface. This would bring the possibility to deduce the cell–cell adhesion strength of cells that would partially detach as a consequence of changes in tension (Diels et al., Reference Diels, Wang, Nicolai, Ramon and Smeets2019; Jarvis, Reference Jarvis1998). While still far from a physiological context, such approach would allow the study of actual cell–cell adhesion of the cell doublet and in a minimally invasive system. One limitation, however, may be that in many cases, including untreated wild-type cells, the tensions induced by the changes in pressure may not be sufficient to separate the cells, or that they would only induce cell wall extension rather than separation of the interface. Conversely, micromanipulation techniques could be used to directly apply separating forces to cell doublets until the cells would separate. The step pressure assay with motorised dual micropipette could be used to attempt to separate spontaneously generated cell doublets or be used to put in contact single plant cells and measure the cell–cell adhesion strength developing over time. Similarly, the fluidic probe-based single-cell force spectroscopy approaches could in principle be used to measure the adhesion of a plant cell to a synthetic cell wall-like substrate. While the suction developed by the currently available micropipette-based setups may not be sufficient to separate the potentially very strong plant cell–cell adhesion (e.g., in the case of wild-type untreated spontaneously generated cell doublet), new implementations using micropipettes with larger diameters adapted to the size of plant cells and high negative pressure fluidic pump could be developed to attempt to solve this issue. It remains that, as previously shown (Melnyk et al., Reference Melnyk, Gabel, Hardcastle, Robinson, Miyashima, Grosse and Meyerowitz2018; Zamil et al., Reference Zamil, Yi and Puri2014), the cell cortex strength may often be weaker than the cell–cell adhesion. In this context, such a setup would ideally be able to develop pulling forces high enough to bring the cell to rupture and allow to assess the maximal measurable adhesion strength. On the other hand, at the tissue scales, stretching until rupture is already achievable in plants with a micro-extensometer. Similarly, to the case of grafting, a tissue sample can be firmly attached to opposite arms of an extensometer and stretched until it ruptures while measuring the force applied. The ACME setup allows the 3D live imaging of cell detachment in mutant samples (Robinson & Durand-Smet, Reference Robinson and Durand-Smet2020) and could be particularly useful to compare different cell-adhesion-defective mutants or the effect of different treatments. Here, the main limitation rather lies in the complexity of the sample. Most tissues are composed of multiple-cell layers, including the epidermis, cortex and the vasculature. While previous work has shown that the epidermis is put under tension by the extensometer stretching (Robinson & Kuhlemeier, Reference Robinson and Kuhlemeier2018), it is not clear what is the load-bearing contribution of the different cell layers. In particular, the epidermis appears to be the first to yield and may at first be under the most tension, whereas the vasculature seems to be the last to yield. As such, quantifying the ultimate force and thus the strength of the samples will likely not really provide information regarding the properties of cell–cell adhesion in the samples, but rather on the toughness of the vasculature. In turn, a more complex analysis of the stress–strain curve in parallel with the microscopic observation with confocal microscopy (ACME) and coupled with computational mechanical simulation of the system (Diels et al., Reference Diels, Wang, Nicolai, Ramon and Smeets2019) would be required to determine adhesion strength in the epidermis or cortex and compare different mutants or treatments. Finally, an alternative to this problem would be to study epidermal peels. While these may be particularly difficult to obtain from adhesion-defective mutants since the epidermal cells would easily detach from each other, this may be a very useful tool to study the effect of treatments or even study adhesion in transgenic lines in which cell-adhesion defect could be induced by the controlled expression of cell-separating enzymes or the controlled knockdown of genes involved in cell adhesion.

To summarise, from these ideas and hypotheses, much remains to be done and tested to determine if or which of these approaches will be the most useful and applicable for the mechanical quantification of cell adhesion in plants. We can hope that this will be the case for many of them, offering a range of techniques from relative measurement of the adhesion of large populations of cells to the very precise measurements in single-cell adhesion or adhesion in the tissue context. A successful approach could also be a combination of some of the approaches proposed (e.g., combining micromanipulation with finite element methods), or require the design and development of completely new approaches.

7. Conclusion

When it comes to multicellular organisms, we know adhesion is responsible for their integrity. We also have some knowledge on how this adhesion is mediated and kept through the organism’s life span. In some organisms, like in animals, adhesion has been intensively studied at the single-cell level and molecular scale. Collaborations among biologists, physicists and engineers have led to the development of different devices and methods to determine or measure the adhesion strength from the molecular to the tissue scale. But the focus of previous studies and methods developed has been rather on the single cell–substrate adhesion than multicellular cell–cell adhesion. The lack of methods for measuring cell–cell adhesion in plants is currently the main bottleneck for the field, and largely hampers our current understanding of the mechanisms controlling cell–cell adhesion in plants. As shown for the animal cells, methods to quantify cell adhesion have had a major impact to understand the molecular basis of cell adhesion but also the complex biophysical implications such as the fact that beyond cell–cell adhesion strength, the regulation of cortical tension, as well as mechanical feedbacks, plays a major role in controlling and maintaining adhesion (Lenne et al., Reference Lenne, Rupprecht and Viasnoff2021). Future development of precise quantitative methods for measuring cell adhesion in plants should thus open the door for major breakthroughs in the field and have a broad impact on our understanding of plant biomechanics.

Acknowledgement

We are grateful to Rawen Ben-Malek and Grégory Mouille (IJPB, INRAE) for their helpful comments on the manuscript.

Conflicts of interest

The authors declare that no competing interests exist.

Financial support

This work was supported by grants from the Kempe Foundation (A.A.; grant number JCK-1912.2), Åforsk (L.B.; grant number 20.502) and the support of Bio4Energy (S.V.) and the UPSC Centre for Forest Biotechnology (L.B.).

Authorship contributions

All the authors wrote the manuscript. L.B. made the figures.

Data availability statement

No data or code was generated as part of this manuscript.

Footnotes

Atakhani and Bogdziewiez contributed equally to this work.

References

Abe, M., Katsumata, H., Komeda, Y., & Takahashi, T. (2003). Regulation of shoot epidermal cell differentiation by a pair of homeodomain proteins in Arabidopsis. Development, 130, 635643. https://doi.org/10.1242/dev.00292CrossRefGoogle ScholarPubMed
Alam, F., Kumar, S., & Varadarajan, K. M. (2019). Quantification of adhesion force of bacteria on the surface of biomaterials: Techniques and assays. ACS Biomaterials Science & Engineering, 5, 20932110. https://doi.org/10.1021/acsbiomaterials.9b00213 CrossRefGoogle ScholarPubMed
Anderson, C. T. (2019). Pectic polysaccharides in plants: Structure, biosynthesis, functions, and applications. In E. Cohen & H. Merzendorfer (Eds.), Extracellular sugar-based biopolymers matrices (pp. 487514). Springer. https://doi.org/10.1007/978-3-030-12919-4_12 CrossRefGoogle Scholar
Anderson, C. T., & Kieber, J. J. (2020). Dynamic construction, perception, and remodeling of plant cell walls. Annual Review of Plant Biology, 71, 3969. https://doi.org/10.1146/annurev-arplant-081519-035846 CrossRefGoogle ScholarPubMed
Arroyo, M., & Trepat, X. (2017). Hydraulic fracturing in cells and tissues: Fracking meets cell biology. Current Opinion in Cell Biology, 44, 16. https://doi.org/10.1016/j.ceb.2016.11.001 CrossRefGoogle ScholarPubMed
Bar-Peled, M., Urbanowicz, B. R., & O’Neill, M. A. (2012). The synthesis and origin of the pectic polysaccharide rhamnogalacturonan II—Insights from nucleotide sugar formation and diversity. Frontiers in Plant Science, 3. https://doi.org/10.3389/fpls.2012.00092 CrossRefGoogle ScholarPubMed
Baum, B., & Georgiou, M. (2011). Dynamics of adherens junctions in epithelial establishment, maintenance, and remodeling. The Journal of Cell Biology, 192, 907917. https://doi.org/10.1083/jcb.201009141 CrossRefGoogle ScholarPubMed
Benoit, M., Gabriel, D., Gerisch, G., & Gaub, H. E. (2000). Discrete interactions in cell adhesion measured by single-molecule force spectroscopy. Nature Cell Biology, 2, 313317. https://doi.org/10.1038/35014000 CrossRefGoogle ScholarPubMed
Biro, M., & Maître, J.-L. (2015). Chapter 14—Dual pipette aspiration: A unique tool for studying intercellular adhesion. In E. K. Paluch (Ed.), Methods in cell biology (Vol. 125, pp. 255267). Academic Press. https://doi.org/10.1016/bs.mcb.2014.10.007 Google Scholar
Bou Daher, F., & Braybrook, S. A. (2015). How to let go: Pectin and plant cell adhesion. Frontiers in Plant Science, 6. https://doi.org/10.3389/fpls.2015.00523 Google Scholar
Bouton, S., Leboeuf, E., Mouille, G., Leydecker, M.-T., Talbotec, J., Granier, F., Lahaye, M., Höfte, H., & Truong, H.-N. (2002). QUASIMODO1 encodes a putative membrane-bound glycosyltransferase required for normal pectin synthesis and cell adhesion in Arabidopsis. The Plant Cell, 14, 25772590. https://doi.org/10.1105/tpc.004259 CrossRefGoogle ScholarPubMed
Brochard-Wyart, F., & de Gennes, P.-G. (2009). Unbinding of adhesive vesicles. In P.G. De Gennes’ impact on science? (Vol. II, pp. 139145). World Scientific. https://doi.org/10.1142/9789814280648_0015 CrossRefGoogle Scholar
Cai, S., & Lashbrook, C. C. (2008). Stamen abscission zone transcriptome profiling reveals new candidates for abscission control: Enhanced retention of floral organs in transgenic plants overexpressing Arabidopsis ZINC FINGER PROTEIN2 . Plant Physiology, 146, 13051321. https://doi.org/10.1104/pp.107.110908 CrossRefGoogle ScholarPubMed
Calcutt, R., Vincent, R., Dean, D., Arinzeh, T. L., & Dixit, R. (2021). Plant cell adhesion and growth on artificial fibrous scaffolds as an in vitro model for plant development. Science Advances, 7, eabj1469. https://doi.org/10.1126/sciadv.abj1469 CrossRefGoogle Scholar
Carpentier, B. (2014). Biofilms. In C. A. Batt & M. L. Tortorello (Eds.), Encyclopedia of food microbiology (2nd ed., pp. 259265). Academic Press. https://doi.org/10.1016/B978-0-12-384730-0.00039-2 CrossRefGoogle Scholar
Christ, K. V., Williamson, K. B., Masters, K. S., & Turner, K. T. (2010). Measurement of single-cell adhesion strength using a microfluidic assay. Biomedical Microdevices, 12, 443455. https://doi.org/10.1007/s10544-010-9401-x CrossRefGoogle ScholarPubMed
Chu, Y.-S., Dufour, S., Thiery, J. P., Perez, E., & Pincet, F. (2005). Johnson–Kendall–Roberts theory applied to living cells. Physical Review Letters, 94, 028102. https://doi.org/10.1103/PhysRevLett.94.028102 CrossRefGoogle ScholarPubMed
Ciesielski, P. N., Resch, M. G., Hewetson, B., Killgore, J. P., Curtin, A., Anderson, N., Chiaramonti, A. N., Hurley, D. C., Sanders, A., Himmel, M. E., Chapple, C., Mosier, N., & Donohoe, B. S. (2014). Engineering plant cell walls: Tuning lignin monomer composition for deconstructable biofuel feedstocks or resilient biomaterials. Green Chemistry, 16, 26272635. https://doi.org/10.1039/C3GC42422G CrossRefGoogle Scholar
Cohen, N., Sarkar, S., Hondroulis, E., Sabhachandani, P., & Konry, T. (2017). Quantification of intercellular adhesion forces measured by fluid force microscopy. Talanta, 174, 409413. https://doi.org/10.1016/j.talanta.2017.06.038 CrossRefGoogle ScholarPubMed
Cosgrove, D. J., & Anderson, C. T. (2020). Plant cell growth: Do pectins drive lobe formation in Arabidopsis pavement cells? Current Biology, 30, R660R662. https://doi.org/10.1016/j.cub.2020.04.007 CrossRefGoogle ScholarPubMed
Creton, C., & Ciccotti, M. (2016). Fracture and adhesion of soft materials: A review. Reports on Progress in Physics, 79, 046601. https://doi.org/10.1088/0034-4885/79/4/046601 CrossRefGoogle ScholarPubMed
da Silva, L. F. M., Öchsner, A., & Adams, R. D. (2018). Handbook of adhesion technology. Springer.CrossRefGoogle Scholar
de Groot, P. W. J., Bader, O., de Boer, A. D., Weig, M., & Chauhan, N. (2013). Adhesins in human fungal pathogens: Glue with plenty of stick. Eukaryotic Cell, 12, 470481. https://doi.org/10.1128/EC.00364-12 CrossRefGoogle ScholarPubMed
Diels, E., Wang, Z., Nicolai, B., Ramon, H., & Smeets, B. (2019). Discrete element modelling of tomato tissue deformation and failure at the cellular scale. Soft Matter, 15, 33623378. https://doi.org/10.1039/C9SM00149B CrossRefGoogle ScholarPubMed
Domozych, D. S., Elliott, L., Kiemle, S. N., & Gretz, M. R. (2007). Pleurotaenium trabecula, a desmid of wetland biofilms: The extracellular matrix and adhesion mechanisms. Journal of Phycology, 43, 10221038. https://doi.org/10.1111/j.1529-8817.2007.00389.x CrossRefGoogle Scholar
Domozych, D. S., Sørensen, I., Popper, Z. A., Ochs, J., Andreas, A., Fangel, J. U., Pielach, A., Sacks, C., Brechka, H., Ruisi-Besares, P., Willats, W. G. T., & Rose, J. K. C. (2014). Pectin metabolism and assembly in the cell wall of the charophyte green alga Penium margaritaceum . Plant Physiology, 165, 105118. https://doi.org/10.1104/pp.114.236257 CrossRefGoogle ScholarPubMed
Du, J., Kirui, A., Huang, S., Wang, L., Barnes, W. J., Kiemle, S. N., Zheng, Y., Rui, Y., Ruan, M., Qi, S., Kim, S. H., Wang, T., Cosgrove, D. J., Anderson, C. T., & Xiao, C. (2020). Mutations in the pectin methyltransferase QUASIMODO2 influence cellulose biosynthesis and wall integrity in Arabidopsis. The Plant Cell, 32, 35763597. https://doi.org/10.1105/tpc.20.00252 CrossRefGoogle ScholarPubMed
Epstein, L., & Nicholson, R. (2016). Adhesion and adhesives of fungi and oomycetes. In A. M. Smith (Ed.), Biological adhesives (pp. 2555). Springer. https://doi.org/10.1007/978-3-319-46082-6_2 CrossRefGoogle Scholar
Francis, K. E., Lam, S. Y., & Copenhaver, G. P. (2006). Separation of Arabidopsis pollen tetrads is regulated by QUARTET1, a pectin methylesterase gene. Plant Physiology, 142, 10041013. https://doi.org/10.1104/pp.106.085274 CrossRefGoogle ScholarPubMed
Galletti, R., Johnson, K. L., Scofield, S., San-Bento, R., Watt, A. M., Murray, J. A. H., & Ingram, G. C. (2015). DEFECTIVE KERNEL 1 promotes and maintains plant epidermal differentiation. Development, 142, 19781983. https://doi.org/10.1242/dev.122325 CrossRefGoogle ScholarPubMed
García, A. J., Ducheyne, P., & Boettiger, D. (1997). Quantification of cell adhesion using a spinning disc device and application to surface-reactive materials. Biomaterials, 18, 10911098. https://doi.org/10.1016/S0142-9612(97)00042-2 CrossRefGoogle ScholarPubMed
Garcia, A. J., & Gallant, N. D. (2003). Stick and grip. Cell Biochemistry and Biophysics, 39, 6173. https://doi.org/10.1385/CBB:39:1:61 CrossRefGoogle ScholarPubMed
Gorshkova, T., Brutch, N., Chabbert, B., Deyholos, M., Hayashi, T., Lev-Yadun, S., Mellerowicz, E. J., Morvan, C., Neutelings, G., & Pilate, G. (2012). Plant fiber formation: State of the art, recent and expected progress, and open questions. Critical Reviews in Plant Sciences, 31, 201228. https://doi.org/10.1080/07352689.2011.616096 CrossRefGoogle Scholar
Grones, P., Raggi, S., & Robert, S. (2019). FORCE-ing the shape. Current Opinion in Plant Biology, 52, 16. https://doi.org/10.1016/j.pbi.2019.05.008 CrossRefGoogle ScholarPubMed
Guillaume-Gentil, O., Potthoff, E., Ossola, D., Franz, C. M., Zambelli, T., & Vorholt, J. A. (2014). Force-controlled manipulation of single cells: From AFM to FluidFM. Trends in Biotechnology, 32, 381388. https://doi.org/10.1016/j.tibtech.2014.04.008 CrossRefGoogle ScholarPubMed
Haas, K. T., Wightman, R., Meyerowitz, E. M., & Peaucelle, A. (2020). Pectin homogalacturonan nanofilament expansion drives morphogenesis in plant epidermal cells. Science, 367, 10031007. https://doi.org/10.1126/science.aaz5103 CrossRefGoogle ScholarPubMed
Haas, K. T., Wightman, R., Peaucelle, A., & Höfte, H. (2021). The role of pectin phase separation in plant cell wall assembly and growth. The Cell Surface, 7, 100054. https://doi.org/10.1016/j.tcsw.2021.100054 CrossRefGoogle Scholar
Haase, K., Al-Rekabi, Z., & Pelling, A. E. (2014). Chapter 5—Mechanical cues direct focal adhesion dynamics. In A. J. Engler & S. Kumar (Eds.), Progress in molecular biology and translational science (Vol. 126, pp. 103134). Academic Press. https://doi.org/10.1016/B978-0-12-394624-9.00005-1 Google Scholar
Halbleib, J. M., & Nelson, W. J. (2006). Cadherins in development: Cell adhesion, sorting, and tissue morphogenesis. Genes & Development, 20, 31993214. https://doi.org/10.1101/gad.1486806 CrossRefGoogle ScholarPubMed
Hall-Stoodley, L., Costerton, J. W., & Stoodley, P. (2004). Bacterial biofilms: From the natural environment to infectious diseases. Nature Reviews Microbiology, 2, 95108. https://doi.org/10.1038/nrmicro821 CrossRefGoogle ScholarPubMed
Hamant, O., & Saunders, T. E. (2020). Shaping organs: Shared structural principles across kingdoms. Annual Review of Cell and Developmental Biology, 36, 385410. https://doi.org/10.1146/annurev-cellbio-012820-103850 CrossRefGoogle ScholarPubMed
Hannezo, E., & Heisenberg, C.-P. (2019). Mechanochemical feedback loops in development and disease. Cell, 178, 1225. https://doi.org/10.1016/j.cell.2019.05.052 CrossRefGoogle ScholarPubMed
Harris, A. R., Peter, L., Bellis, J., Baum, B., Kabla, A. J., & Charras, G. T. (2012). Characterizing the mechanics of cultured cell monolayers. Proceedings of the National Academy of Sciences of the United States of America, 109, 1644916454. https://doi.org/10.1073/pnas.1213301109 CrossRefGoogle ScholarPubMed
Harris, T. J. C., & Tepass, U. (2010). Adherens junctions: From molecules to morphogenesis. Nature Reviews Molecular Cell Biology, 11, 502514. https://doi.org/10.1038/nrm2927 CrossRefGoogle ScholarPubMed
Hartsock, A., & Nelson, W. J. (2008). Adherens and tight junctions: Structure, function and connections to the actin cytoskeleton. Biochimica et Biophysica Acta (BBA)—Biomembranes, 1778, 660669. https://doi.org/10.1016/j.bbamem.2007.07.012 CrossRefGoogle ScholarPubMed
Hocq, L., Pelloux, J., & Lefebvre, V. (2017). Connecting homogalacturonan-type pectin remodeling to acid growth. Trends in Plant Science, 22, 2029. https://doi.org/10.1016/j.tplants.2016.10.009 CrossRefGoogle ScholarPubMed
Huxham, I. M., Jarvis, M. C., Shakespeare, L., Dover, C. J., Johnson, D., Knox, J. P., & Seymour, G. B. (1999). Electron-energy-loss spectroscopic imaging of calcium and nitrogen in the cell walls of apple fruits. Planta, 208, 438443. https://doi.org/10.1007/s004250050580 CrossRefGoogle Scholar
Ikegaya, H., Hayashi, T., Kaku, T., Iwata, K., Sonobe, S., & Shimmen, T. (2008). Presence of xyloglucan-like polysaccharide in spirogyra and possible involvement in cell–cell attachment. Phycological Research, 56, 216222. https://doi.org/10.1111/j.1440-1835.2008.00503.x CrossRefGoogle Scholar
Iwamoto, D. V., & Calderwood, D. A. (2015). Regulation of integrin-mediated adhesions. Current Opinion in Cell Biology, 36, 4147. https://doi.org/10.1016/j.ceb.2015.06.009 CrossRefGoogle ScholarPubMed
Jarvis, M. C. (1998). Intercellular separation forces generated by intracellular pressure. Plant, Cell & Environment, 21, 13071310. https://doi.org/10.1046/j.1365-3040.1998.00363.x CrossRefGoogle Scholar
Jarvis, M. C., & Apperley, D. C. (1995). Chain conformation in concentrated pectic gels: Evidence from 13C NMR. Carbohydrate Research, 275, 131145. https://doi.org/10.1016/0008-6215(95)00033-P CrossRefGoogle Scholar
Jarvis, M. C., Briggs, S. P. H., & Knox, J. P. (2003). Intercellular adhesion and cell separation in plants. Plant, Cell & Environment, 26, 977989. https://doi.org/10.1046/j.1365-3040.2003.01034.x CrossRefGoogle Scholar
Jauh, G. Y., Eckard, K. J., Nothnagel, E. A., & Lord, E. M. (1997). Adhesion of lily pollen tubes on an artificial matrix. Sexual Plant Reproduction, 10, 173180. https://doi.org/10.1007/s004970050085 CrossRefGoogle Scholar
Jones, E. B. G. (1994). Fungal adhesion. Mycological Research, 98, 961981. https://doi.org/10.1016/S0953-7562(09)80421-8 CrossRefGoogle Scholar
Kawakatsu, Y., Sawai, Y., Kurotani, K., Shiratake, K., & Notaguchi, M. (2020). An in vitro grafting method to quantify mechanical forces of adhering tissues. Plant Biotechnology, 37, 451458. https://doi.org/10.5511/plantbiotechnology.20.0925a CrossRefGoogle Scholar
Klebe, R. J. (1974). Isolation of a collagen-dependent cell attachment factor. Nature, 250, 248251. https://doi.org/10.1038/250248a0 CrossRefGoogle ScholarPubMed
Knox, J. P. (1992). Cell adhesion, cell separation and plant morphogenesis. The Plant Journal, 2, 137141. https://doi.org/10.1111/j.1365-313X.1992 00137.x CrossRefGoogle Scholar
Kooten, T. G. v., Schakenraad, J. M., Mei, H. C. V. d., & Busscher, H. J. (1992). Development and use of a parallel-plate flow chamber for studying cellular adhesion to solid surfaces. Journal of Biomedical Materials Research, 26, 725738. https://doi.org/10.1002/jbm.820260604 CrossRefGoogle ScholarPubMed
Kostakioti, M., Hadjifrangiskou, M., & Hultgren, S. J. (2013). Bacterial biofilms: Development, dispersal, and therapeutic strategies in the dawn of the postantibiotic era. Cold Spring Harbor Perspectives in Medicine, 3, a010306. https://doi.org/10.1101/cshperspect.a010306 CrossRefGoogle ScholarPubMed
Kuo, J.-C. (2014). Focal adhesions function as a mechanosensor. Progress in Molecular Biology and Translational Science, 126, 5573. https://doi.org/10.1016/B978-0-12-394624-9.00003-8 CrossRefGoogle ScholarPubMed
Lashbrook, C. C., & Cai, S. (2008). Cell wall remodeling in Arabidopsis stamen abscission zones. Plant Signaling & Behavior, 3, 733736. https://doi.org/10.4161/psb.3.9.6489 CrossRefGoogle ScholarPubMed
Lathe, R. S., McFarlane, H. E., Khan, G. A., Ebert, B., Ramírez-Rodríguez, E. A., Noord, N., Bhalerao, R., & Persson, S. (2021). A DUF1068 protein acts as a pectin biosynthesis scaffold and maintains Golgi morphology and cell adhesion in Arabidopsis. BioRxiv: 2021.05.03.442108. https://doi.org/10.1101/2021.05.03.442108 CrossRefGoogle Scholar
Le, J., El-Assal, S. E.-D., Basu, D., Saad, M. E., & Szymanski, D. B. (2003). Requirements for Arabidopsis ATARP2 and ATARP3 during epidermal development. Current Biology, 13, 13411347. https://doi.org/10.1016/s0960-9822(03)00493-7 CrossRefGoogle ScholarPubMed
Leboeuf, E., Thoiron, S., & Lahaye, M. (2004). Physico-chemical characteristics of cell walls from Arabidopsis thaliana microcalli showing different adhesion strengths. Journal of Experimental Botany, 55, 20872097. https://doi.org/10.1093/jxb/erh225 CrossRefGoogle ScholarPubMed
Lebret, K., Thabard, M., & Hellio, C. (2009). Chapter 4—Algae as marine fouling organisms: Adhesion damage and prevention. In C. Hellio & D. Yebra (Eds.), Advances in marine antifouling coatings and technologies (pp. 80112). Woodhead. https://doi.org/10.1533/9781845696313.1.80 CrossRefGoogle Scholar
Leckband, D. E., & de Rooij, J. (2014). Cadherin adhesion and mechanotransduction. Annual Review of Cell and Developmental Biology, 30, 291315. https://doi.org/10.1146/annurev-cellbio-100913-013212 CrossRefGoogle ScholarPubMed
Lenne, P.-F., Rupprecht, J.-F., & Viasnoff, V. (2021). Cell junction mechanics beyond the bounds of adhesion and tension. Developmental Cell, 56, 202212. https://doi.org/10.1016/j.devcel.2020.12.018 CrossRefGoogle ScholarPubMed
Letham, D. S. (1960). The separation of plant cells with ethylenediaminetetraacetic acid. Experimental Cell Research, 21, 353360. https://doi.org/10.1016/0014-4827(60)90267-6 CrossRefGoogle ScholarPubMed
Li, X., & Chapple, C. (2010). Understanding lignification: Challenges beyond monolignol biosynthesis. Plant Physiology, 154, 449452. https://doi.org/10.1104/pp.110.162842 CrossRefGoogle ScholarPubMed
Liedekerke, P. V., Ghysels, P., Tijskens, E., Samaey, G., Roose, D., & Ramon, H. (2011). Mechanisms of soft cellular tissue bruising. A particle based simulation approach. Soft Matter, 7, 35803591. https://doi.org/10.1039/C0SM01261K CrossRefGoogle Scholar
Lindsay, D. W., Yeoman, M. M., & Brown, R. (1974). An analysis of the development of the graft union in Lycopersicon esculentum . Annals of Botany, 38, 639646. https://doi.org/10.1093/oxfordjournals.aob.a084849 CrossRefGoogle Scholar
Liners, F., Letesson, J. J., Didembourg, C., & Van Cutsem, P. (1989). Monoclonal antibodies against pectin: Recognition of a conformation induced by calcium. Plant Physiology, 91, 14191424. https://doi.org/10.1104/pp.91.4.1419 CrossRefGoogle ScholarPubMed
Lionetti, V., Cervone, F., & De Lorenzo, G. (2015). A lower content of de-methylesterified homogalacturonan improves enzymatic cell separation and isolation of mesophyll protoplasts in Arabidopsis. Phytochemistry, 112, 188194. https://doi.org/10.1016/j.phytochem.2014.07.025 CrossRefGoogle ScholarPubMed
Lodish, H., Berk, A., Kaiser, C. A., Kaiser, C., Krieger, M., Scott, M. P., Bretscher, A., Ploegh, H., & Matsudaira, P. (2008). Molecular cell biology. Macmillan.Google Scholar
Lu, H., Koo, L. Y., Wang, W. M., Lauffenburger, D. A., Griffith, L. G., & Jensen, K. F. (2004). Microfluidic shear devices for quantitative analysis of cell adhesion. Analytical Chemistry, 76, 52575264. https://doi.org/10.1021/ac049837t CrossRefGoogle ScholarPubMed
Maître, J.-L., & Heisenberg, C.-P. (2011). The role of adhesion energy in controlling cell–cell contacts. Current Opinion in Cell Biology, 23, 508514. https://doi.org/10.1016/j.ceb.2011.07.004 CrossRefGoogle ScholarPubMed
Manning, M. L., Foty, R. A., Steinberg, M. S., & Schoetz, E.-M. (2010). Coaction of intercellular adhesion and cortical tension specifies tissue surface tension. Proceedings of the National Academy of Sciences, 107, 1251712522 CrossRefGoogle ScholarPubMed
Mao, L., Begum, D., Chuang, H. W., Budiman, M. A., Szymkowiak, E. J., Irish, E. E., & Wing, R. A. (2000). JOINTLESS is a MADS-box gene controlling tomato flower abscission zone development. Nature, 406, 910913. https://doi.org/10.1038/35022611 CrossRefGoogle ScholarPubMed
Marsollier, A.-C., & Ingram, G. (2018). Getting physical: Invasive growth events during plant development. Current Opinion in Plant Biology, 46, 817. https://doi.org/10.1016/j.pbi.2018.06.002 CrossRefGoogle ScholarPubMed
Mathur, J., Mathur, N., Kernebeck, B., & Hülskamp, M. (2003a). Mutations in actin-related proteins 2 and 3 affect cell shape development in Arabidopsis. The Plant Cell, 15, 16321645. https://doi.org/10.1105/tpc.011676 CrossRefGoogle Scholar
Mathur, J., Mathur, N., Kirik, V., Kernebeck, B., Srinivas, B. P., & Hülskamp, M. (2003b). Arabidopsis CROOKED encodes for the smallest subunit of the ARP2/3 complex and controls cell shape by region specific fine F-actin formation. Development, 130, 31373146. https://doi.org/10.1242/dev.00549 CrossRefGoogle Scholar
McCartney, L., & Knox, J. P. (2002). Regulation of pectic polysaccharide domains in relation to cell development and cell properties in the pea testa. Journal of Experimental Botany, 53, 707713. https://doi.org/10.1093/jexbot/53.369.707 CrossRefGoogle ScholarPubMed
Meir, S., Philosoph-Hadas, S., Sundaresan, S., Selvaraj, K. S. V., Burd, S., Ophir, R., Kochanek, B., Reid, M. S., Jiang, C.-Z., & Lers, A. (2010). Microarray analysis of the abscission-related transcriptome in the tomato flower abscission zone in response to auxin depletion. Plant Physiology, 154, 19291956. https://doi.org/10.1104/pp.110.160697 CrossRefGoogle ScholarPubMed
Meister, A., Gabi, M., Behr, P., Studer, P., Vörös, J., Niedermann, P., Bitterli, J., Polesel-Maris, J., Liley, M., Heinzelmann, H., & Zambelli, T. (2009). FluidFM: Combining atomic force microscopy and nanofluidics in a universal liquid delivery system for single cell applications and beyond. Nano Letters, 9, 25012507. https://doi.org/10.1021/ nl901384x CrossRefGoogle Scholar
Melnyk, C. W., Gabel, A., Hardcastle, T. J., Robinson, S., Miyashima, S., Grosse, I., & Meyerowitz, E. M. (2018). Transcriptome dynamics at Arabidopsis graft junctions reveal an intertissue recognition mechanism that activates vascular regeneration. Proceedings of the National Academy of Sciences, 115, E2447E2456 CrossRefGoogle ScholarPubMed
Moore, R. (1984). Graft formation in Solanum pennellii (Solanaceae). Plant Cell Reports, 3, 172175. https://doi.org/10.1007/BF00270192 CrossRefGoogle Scholar
Mouille, G., Ralet, M.-C., Cavelier, C., Eland, C., Effroy, D., Hématy, K., McCartney, L., Truong, H. N., Gaudon, V., Thibault, J.-F., Marchant, A., & Höfte, H. (2007). Homogalacturonan synthesis in Arabidopsis thaliana requires a Golgi-localized protein with a putative methyltransferase domain. The Plant Journal, 50, 605614. https://doi.org/10.1111/j.1365-313X.2007.03086.x CrossRefGoogle ScholarPubMed
Nagy, L. G., Kovács, G. M., & Krizsán, K. (2018). Complex multicellularity in fungi: Evolutionary convergence, single origin, or both? Biological Reviews, 93, 17781794. https://doi.org/10.1111/brv.12418 CrossRefGoogle ScholarPubMed
Ng, A., Greenshields, R. N., & Waldron, K. W. (1997). Oxidative cross-linking of corn bran hemicellulose: Formation of ferulic acid dehydrodimers. Carbohydrate Research, 303, 459462. https://doi.org/10.1016/S0008-6215(97)00193-6 CrossRefGoogle Scholar
Ng, A., Parker, M. L., Parr, A. J., Saunders, P. K., Smith, A. C., & Waldron, K. W. (2000). Physicochemical characteristics of onion (Allium cepa L.) tissues. Journal of Agricultural and Food Chemistry, 48, 56125617. https://doi.org/10.1021/jf991206q CrossRefGoogle ScholarPubMed
Notaguchi, M., Kurotani, K., Sato, Y., Tabata, R., Kawakatsu, Y., Okayasu, K., Sawai, Y., Okada, R., Asahina, M., Ichihashi, Y., Shirasu, K., Suzuki, T., Niwa, M., & Higashiyama, T. (2020). Cell–cell adhesion in plant grafting is facilitated by β-1,4-glucanases. Science, 369, 698702. https://doi.org/10.1126/science.abc3710 CrossRefGoogle ScholarPubMed
O’Neill, M. A., Eberhard, S., Albersheim, P., & Darvill, A. G. (2001). Requirement of borate cross-linking of cell wall rhamnogalacturonan II for Arabidopsis growth. Science, 294, 846849. https://doi.org/10.1126/science.1062319 CrossRefGoogle ScholarPubMed
Ogawa, M., Kay, P., Wilson, S., & Swain, S. M. (2009). ARABIDOPSIS DEHISCENCE ZONE POLYGALACTURONASE1 (ADPG1), ADPG2, and QUARTET2 are polygalacturonases required for cell separation during reproductive development in Arabidopsis. The Plant Cell, 21, 216233. https://doi.org/10.1105/tpc.108.063768 CrossRefGoogle Scholar
Olsson, V., & Butenko, M. A. (2018). Abscission in plants. Current Biology, 28, R338R339. https://doi.org/10.1016/j.cub.2018.02.069 CrossRefGoogle ScholarPubMed
Ordaz-Ortiz, J. J., Marcus, S. E., & Paul Knox, J. (2009). Cell wall microstructure analysis implicates hemicellulose polysaccharides in cell adhesion in tomato fruit pericarp parenchyma. Molecular Plant, 2, 910921. https://doi.org/10.1093/mp/ssp049 CrossRefGoogle ScholarPubMed
Packham, D. E. (2017). Theories of fundamental adhesion. In L. F. M. da Silva, A. Öchsner, & R. D. Adams (Eds.), Handbook of adhesion technology (pp. 131). Springer. https://doi.org/10.1007/978-3-319-42087-5_2-2 Google Scholar
Parker, M. L., & Waldron, K. W. (1995). Texture of Chinese water chestnut: Involvement of cell wall phenolics. Journal of the Science of Food and Agriculture, 68, 337346. https://doi.org/10.1002/jsfa.2740680313 CrossRefGoogle Scholar
Pasternak, T., Paponov, I. A., & Kondratenko, S. (2021). Optimizing protocols for Arabidopsis shoot and root protoplast cultivation. Plants, 10, 375. https://doi.org/10.3390/plants10020375 CrossRefGoogle ScholarPubMed
Peaucelle, A., Braybrook, S. A., Le Guillou, L., Bron, E., Kuhlemeier, C., & Höfte, H. (2011). Pectin-induced changes in cell wall mechanics underlie organ initiation in Arabidopsis. Current Biology, 21, 17201726. https://doi.org/10.1016/j.cub.2011.08.057 CrossRefGoogle ScholarPubMed
Pinheiro, D., & Bellaïche, Y. (2018). Mechanical force-driven adherens junction remodeling and epithelial dynamics. Developmental Cell, 47, 319. https://doi.org/10.1016/j.devcel.2018.09.014 CrossRefGoogle ScholarPubMed
Qiu, J.-L., Jilk, R., Marks, M. D., & Szymanski, D. B. (2002). The Arabidopsis SPIKE1 gene is required for normal cell shape control and tissue development. The Plant Cell, 14, 101118. https://doi.org/10.1105/tpc.010346 CrossRefGoogle ScholarPubMed
Raven, J. A., & Giordano, M. (2014). Algae. Current Biology, 24, R590R595. https://doi.org/10.1016/j.cub.2014.05.039 CrossRefGoogle ScholarPubMed
Razatos, A., Ong, Y.-L., Sharma, M. M., & Georgiou, G. (1998). Molecular determinants of bacterial adhesion monitored by atomic force microscopy. Proceedings of the National Academy of Sciences, 95, 1105911064 CrossRefGoogle ScholarPubMed
Rhee, S. Y., Osborne, E., Poindexter, P. D., & Somerville, C. R. (2003). Microspore separation in the quartet 3 mutants of Arabidopsis is impaired by a defect in a developmentally regulated polygalacturonase required for pollen mother cell wall degradation. Plant Physiology, 133, 11701180. https://doi.org/10.1104/pp.103.028266 CrossRefGoogle Scholar
Roberts, K., Alberts, B., Johnson, A., Lewis, J., Raff, M., & Walter, P. (2002). Molecular biology of the cell. Garland Science.Google Scholar
Robinson, S., & Durand-Smet, P. (2020). Combining tensile testing and microscopy to address a diverse range of questions. Journal of Microscopy, 278, 145153. https://doi.org/10.1111/jmi.12863 CrossRefGoogle ScholarPubMed
Robinson, S., Huflejt, M., de Reuille, P., Braybrook, S. A., Schorderet, M., Reinhardt, D., & Kuhlemeier, C. (2017). An automated confocal micro-extensometer enables in vivo quantification of mechanical properties with cellular resolution. The Plant Cell, 29, 29592973. https://doi.org/10.1105/tpc.17.00753 CrossRefGoogle ScholarPubMed
Robinson, S., & Kuhlemeier, C. (2018). Global compression reorients cortical microtubules in Arabidopsis hypocotyl epidermis and promotes growth. Current Biology, 28, 17941802.e2. https://doi.org/10.1016/j.cub.2018.04.028 CrossRefGoogle ScholarPubMed
Roland, J. C. (1978). Cell wall differentiation and stages involved with intercellular gas space opening. Journal of Cell Science, 32, 325336. https://doi.org/10.1242/jcs.32.1.325 CrossRefGoogle ScholarPubMed
Rosen, G. D., & Dube, D. S. (2006). ADHESION, CELL–MATRIX | focal contacts and signaling. In G. J. Laurent & S. D. Shapiro (Eds.), Encyclopedia of respiratory medicine (pp. 4147). Academic Press. https://doi.org/10.1016/B0-12-370879-6/00013-2 CrossRefGoogle Scholar
Rui, Y., Chen, Y., Yi, H., Purzycki, T., Puri, V. M., & Anderson, C. T. (2019). Synergistic pectin degradation and guard cell pressurization underlie stomatal pore formation. Plant Physiology, 180, 6677. https://doi.org/10.1104/pp.19.00135 CrossRefGoogle ScholarPubMed
Sackmann, E., & Smith, A.-S. (2014). Physics of cell adhesion: Some lessons from cell-mimetic systems. Soft Matter, 10, 16441659. https://doi.org/10.1039/C3SM51910D CrossRefGoogle ScholarPubMed
Saedler, R., Zimmermann, I., Mutondo, M., & Hülskamp, M. (2004). The Arabidopsis KLUNKER gene controls cell shape changes and encodes the AtSRA1 homolog. Plant Molecular Biology, 56, 775782. https://doi.org/10.1007/s11103-004-4951-z CrossRefGoogle ScholarPubMed
Shafayet Zamil, M., Yi, H., & Puri, V. M. (2017). A multiscale FEA framework for bridging cell-wall to tissue-scale mechanical properties: The contributions of middle lamella interface and cell shape. Journal of Materials Science, 52, 79477968. https://doi.org/10.1007/s10853-017-0999-4 CrossRefGoogle Scholar
Sheng, X., Ting, Y. P., & Pehkonen, S. O. (2007). Force measurements of bacterial adhesion on metals using a cell probe atomic force microscope. Journal of Colloid and Interface Science, 310, 661669. https://doi.org/10.1016/j.jcis.2007.01.084 CrossRefGoogle ScholarPubMed
Shi, C.-L., Stenvik, G.-E., Vie, A. K., Bones, A. M., Pautot, V., Proveniers, M., Aalen, R. B., & Butenko, M. A. (2011). Arabidopsis class I KNOTTED-like homeobox proteins act downstream in the IDA-HAE/HSL2 floral abscission signaling pathway. The Plant Cell, 23, 25532567. https://doi.org/10.1105/tpc.111.084608 CrossRefGoogle Scholar
Stenvik, G.-E., Tandstad, N. M., Guo, Y., Shi, C.-L., Kristiansen, W., Holmgren, A., Clark, S. E., Aalen, R. B., & Butenko, M. A. (2008). The EPIP peptide of INFLORESCENCE DEFICIENT IN ABSCISSION is sufficient to induce abscission in Arabidopsis through the receptor-like kinases HAESA and HAESA-LIKE2. The Plant Cell, 20, 18051817. https://doi.org/10.1105/tpc.108.059139 CrossRefGoogle ScholarPubMed
Stoeckle, D., Thellmann, M., & Vermeer, J. E. (2018). Breakout—Lateral root emergence in Arabidopsis thaliana . Current Opinion in Plant Biology, 41, 6772. https://doi.org/10.1016/j.pbi.2017.09.005 CrossRefGoogle ScholarPubMed
Sung, K. L., Sung, L. A., Crimmins, M., Burakoff, S. J., & Chien, S. (1986). Determination of junction avidity of cytolytic T cell and target cell. Science, 234, 14051408. https://doi.org/10.1126/science.3491426 CrossRefGoogle ScholarPubMed
Temple, H., Phyo, P., Yang, W., Lyczakowski, J. J., Echevarría-Poza, A., Yakunin, I., Parra-Rojas, J. P., Terrett, O. M., Saez-Aguayo, S., Dupree, R., Orellana, A., Hong, M., & Dupree, P. (2021). Discovery of putative Golgi S-adenosyl methionine transporters reveals the importance of plant cell wall polysaccharide methylation. BioRxiv: 2021.07.06.451061. https://doi.org/10.1101/2021.07.06.451061 CrossRefGoogle Scholar
Thomas, W. A., Boscher, C., Chu, Y.-S., Cuvelier, D., Martinez-Rico, C., Seddiki, R., Heysch, J., Ladoux, B., Thiery, J. P., Mege, R.-M., & Dufour, S. (2013). α-Catenin and vinculin cooperate to promote high E-cadherin-based adhesion strength. Journal of Biological Chemistry, 288, 49574969. https://doi.org/10.1074/jbc.M112.403774 CrossRefGoogle ScholarPubMed
Tran, D., Galletti, R., Neumann, E. D., Dubois, A., Sharif-Naeini, R., Geitmann, A., Frachisse, J.-M., Hamant, O., & Ingram, G. C. (2017). A mechanosensitive Ca2+ channel activity is dependent on the developmental regulator DEK1. Nature Communications, 8, 1009. https://doi.org/10.1038/s41467-017-00878-w CrossRefGoogle ScholarPubMed
Trinh, D.-C., Alonso-Serra, J., Asaoka, M., Colin, L., Cortes, M., Malivert, A., Takatani, S., Zhao, F., Traas, J., Trehin, C., & Hamant, O. (2021). How mechanical forces shape plant organs. Current Biology, 31, R143R159. https://doi.org/10.1016/j.cub.2020.12.001 CrossRefGoogle ScholarPubMed
Tuson, H. H., & Weibel, D. B. (2013). Bacteria–surface interactions. Soft Matter, 9, 43684380. https://doi.org/10.1039/C3SM27705D CrossRefGoogle ScholarPubMed
Uesugi, K., Akiyama, Y., Hoshino, T., Akiyama, Y., Yamato, M., Okano, T., & Morishima, K. (2013). Measuring adhesion force of a cell sheet by the ninety-degree peel test using a multi hook type fixture. Journal of Biomechanical Science and Engineering, 8, 129138. https://doi.org/10.1299/jbse.8.129 CrossRefGoogle Scholar
Ungai-Salánki, R., Peter, B., Gerecsei, T., Orgovan, N., Horvath, R., & Szabó, B. (2019). A practical review on the measurement tools for cellular adhesion force. Advances in Colloid and Interface Science, 269, 309333. https://doi.org/10.1016/j.cis.2019.05.005 CrossRefGoogle Scholar
Veldhuis, J. H., Ehsandar, A., Maître, J.-L., Hiiragi, T., Cox, S., & Brodland, G. W. (2017). Inferring cellular forces from image stacks. Philosophical Transactions of the Royal Society B: Biological Sciences, 372, 20160261. https://doi.org/10.1098/rstb.2016.0261 CrossRefGoogle ScholarPubMed
Verger, S., Chabout, S., Gineau, E., & Mouille, G. (2016). Cell adhesion in plants is under the control of putative O-fucosyltransferases. Development, 143, 25362540. https://doi.org/10.1242/dev.132308 Google ScholarPubMed
Verger, S., Long, Y., Boudaoud, A., & Hamant, O. (2018). A tension-adhesion feedback loop in plant epidermis. eLife, 7, e34460. https://doi.org/10.7554/eLife.34460 CrossRefGoogle ScholarPubMed
Wang, X., Wilson, L., & Cosgrove, D. J. (2020). Pectin methylesterase selectively softens the onion epidermal wall yet reduces acid-induced creep. Journal of Experimental Botany, 71, 26292640. https://doi.org/10.1093/jxb/eraa059 CrossRefGoogle ScholarPubMed
Willats, W. G., Orfila, C., Limberg, G., Buchholt, H. C., van Alebeek, G. J., Voragen, A. G., Marcus, S. E., Christensen, T. M., Mikkelsen, J. D., Murray, B. S., & Knox, J. P. (2001). Modulation of the degree and pattern of methyl-esterification of pectic homogalacturonan in plant cell walls. Implications for pectin methyl esterase action, matrix properties, and cell adhesion. Journal of Biological Chemistry, 276, 1940419413. https://doi.org/10.1074/jbc.M011242200 CrossRefGoogle ScholarPubMed
Winklbauer, R. (2015). Cell adhesion strength from cortical tension—An integration of concepts. Journal of Cell Science, 128, 36873693. https://doi.org/10.1242/jcs.174623 CrossRefGoogle Scholar
Yang, H., Benatti, M. R., Karve, R. A., Fox, A., Meilan, R., Carpita, N. C., & McCann, M. C. (2020). Rhamnogalacturonan-I is a determinant of cell–cell adhesion in poplar wood. Plant Biotechnology Journal, 18, 10271040. https://doi.org/10.1111/pbi.13271 CrossRefGoogle ScholarPubMed
Yap, A. S., Duszyc, K., & Viasnoff, V. (2018). Mechanosensing and mechanotransduction at cell–cell junctions. Cold Spring Harbor Perspectives in Biology, 10, a028761. https://doi.org/10.1101/cshperspect.a028761 CrossRefGoogle ScholarPubMed
Zamil, M. S., & Geitmann, A. (2017). The middle lamella—More than a glue. Physical Biology, 14, 015004. https://doi.org/10.1088/1478-3975/aa5ba5 CrossRefGoogle ScholarPubMed
Zamil, M. S., Yi, H., & Puri, V. M. (2014). Mechanical characterization of outer epidermal middle lamella of onion under tensile loading. American Journal of Botany, 101, 778787. https://doi.org/10.3732/ajb.1300416 CrossRefGoogle ScholarPubMed
Zamir, E., & Geiger, B. (2013). Focal adhesions and related integrin contacts. In W. J. Lennarz & M. D. Lane (Eds.), Encyclopedia of biological chemistry (2nd ed., pp. 318323). Academic Press. https://doi.org/10.1016/B978-0-12-378630-2.00473-4 CrossRefGoogle Scholar
Zhang, J., Henriksson, G., & Johansson, G. (2000). Polygalacturonase is the key component in enzymatic retting of flax. Journal of Biotechnology, 81, 8589. https://doi.org/10.1016/S0168-1656(00)00286-8 CrossRefGoogle ScholarPubMed
Zhang, T., Tang, H., Vavylonis, D., & Cosgrove, D. J. (2019). Disentangling loosening from softening: Insights into primary cell wall structure. The Plant Journal, 100, 11011117. https://doi.org/10.1111/ tpj.14519 CrossRefGoogle ScholarPubMed
Zhang, T., Zheng, Y., & Cosgrove, D. J. (2016). Spatial organization of cellulose microfibrils and matrix polysaccharides in primary plant cell walls as imaged by multichannel atomic force microscopy. The Plant Journal, 85, 179192. https://doi.org/10.1111/tpj.13102 CrossRefGoogle ScholarPubMed
Zinkl, G. M., Zwiebel, B. I., Grier, D. G., & Preuss, D. (1999). Pollen-stigma adhesion in Arabidopsis: A species-specific interaction mediated by lipophilic molecules in the pollen exine. Development, 126, 54315440. https://doi.org/10.1242/dev.126.23.5431 CrossRefGoogle ScholarPubMed
Figure 0

Fig. 1. Mechanics of cell adhesion. (a) Force, stress and strain. When a force (orange arrow) is applied on an object, it generates a mechanical stress and a strain (deformation). The stress corresponds to the ratio of the force F applied to the cross-sectional area A of the object on which the force is applied. The strain is the ratio of the elongation ΔL of the object to the original length L0 of the object. (b) De-adhesion strength and work. When a doublet of cells is stretched apart, the cells are deformed (strain) and the stress in the sample increases until the stress is high enough to break the links between the cells. The maximal amount of stress applied before the cells detached from each other corresponds to the de-adhesion strength (blue dashed line). The area under the stress–strain curve is measured as the de-adhesion work (blue hatched area). After separation, the cell shape can be changed due to their plasticity. (c) Adhesion energy can in principle be deduced from the work of de-adhesion by considering stress dissipation.

Figure 1

Fig. 2. Adhesion in plant and animal cells. The top drawings represent cell doublets, and the bottom drawings are close-up representations of the edge of the cell–cell interface. In both plant (left) and animal (right) cells, the cell shape is governed by an equilibrium between the internal hydrostatic pressure and the cortical tension. The plant cell adhesion is mediated by a cell wall mostly composed of cellulose and matrix polysaccharides. At the interface, the middle lamella is enriched in pectins and believed to play an important role in adhesion. The animal cell adhesion is mediated via proteins located at the plasma membrane. Cell-adhesion molecules are linked to the actin cytoskeleton which contributes to the cortical tension.

Figure 2

Fig. 3. Cell-adhesion quantification methods. (a) Plate and wash assay. After placing the cells in contact with the substrate for a period, the medium is replaced, removing the nonadherent cells. (b) Centrifugal assay. A 96-well plate is coated with a substrate. A cell suspension is added and allowed to adhere to the substrate. Then the wells are sealed, and the plate is spun at a specific speed and duration. (c) Hydrodynamic flow assays. (c1) The radial flow chamber. An outward radial flow. Different intensities of shear stress are applied on the cells depending on their position in the chamber according to a gradient inversely proportional to the radial position. (c2) The spinning disc assay uses a rotating flow to apply a hydrodynamic shear force on the sample. The cells are in contact with a substrate on a plate, which is rotating in a chamber containing liquid. The applied forces vary linearly with radial distance. (c3) The parallel plate. The cells are in a rectangular chamber, and a constant flow is maintained during one experiment. (d) Microfluidic chamber. The cells are in micrometre-range channels where a laminar flow is running. The smaller the channel is, the higher is the shear stress applied on the sample. (e) Cell shape-based imaging technique. The cell shape depends on an equilibrium between the internal hydrostatic pressure and the cortical tension. The strength of cell–cell adhesion can be deduced from the area of contact and the angle at the junction of cells. (f) Single-cell force spectroscopy. A cell is attached to the cantilever of an atomic force microscope then put in contact with a substrate. The cantilever first approaches and pushes the cell on the substrate. Then the cell is pulled from the surface. The adhesion force between the cell and the substrate will bend the cantilever until the cell detaches. A laser is reflected by the cantilever to a photodetector. This will draw a force curve giving information on the force of adhesion between the cell and the substrate. (g) Fluidic probe force microscopy. The same principle as the single-cell force spectroscopy, but the cantilever contains a microchannel that can suck the cell like a micropipette. (h) Step pressure assay. Two motorised micropipettes are connected to a microfluidic pump. First, the two cells are in contact to allow the adhesion. One micropipette keeps the cell in position with a high constant suction, whereas the other one pulls its cell away with a lower suction. If the adhesion is stronger than the measuring pipette suction, the cell will slip out the micropipette. The suction in this pipette is then increased until it is strong enough to separate the cells. (i) Extensometer used for tensile test. The tissue sample is held at each end and stretched with a specific force. The stretching and the tearing are monitored with microscopic observation. For additional information on the methods presented, including the quantitative/mathematical framework used to derive adhesion mechanics values, see Alam et al. (2019), Garcia and Gallant (2003) and Ungai-Salánki et al. (2019).

Author comment: Characterising the mechanics of cell–cell adhesion in plants — R0/PR1

Comments

To the Editor,

Please find attached our manuscript entitled “Characterizing the mechanics of cell-cell adhesion in plants” for Quantitative Plant Biology within the “call for paper: Plant biomechanics”.

Adhesion is essential for keeping single-celled and multicellular organisms alive and developing. Despite being a fundamental feature, we still know very little about how it works in plants. Here, we argue that the lack of methods for quantitatively measuring cell-cell adhesion in plants is currently the main bottleneck for the field. Yet, adhesion mechanics in animal, fungi, yeast, algae and bacteria has been vastly studied thanks to the use of quantitative methods. Furthermore, the data generated have contributed to a large number of theoretical studies on the mechanisms of cell adhesion in these organisms. Here, we both intend to review the existing knowledge on cell adhesion mechanics in general and how it is quantitatively measured. A large focus is placed on presenting information on the tools and methods available for measuring the adhesion force at the single cell and the tissue level. We then hypothesize and propose possible future development of precise quantitative methods for measuring cell adhesion in plants. We believe this review is among the first steps in the development of such quantitative approaches for plants and that such developments will open the door for major breakthroughs in the field and have a broad impact on our understanding of plant biomechanics.

Because the focus is on the development of biophysical quantitative methods, in our view, the collected material in this manuscript will be of interest to the readership of Quantitative Plant Biology. The knowledge reviewed has a high potential to serve as a reference in several scientific communities including development, biophysics and plant and animal biology in general, and the novel ideas proposed could fuel the development of new quantitative methods for plants biophysical characterization. Due to the far-reaching implications and the interdisciplinary nature of this review, we hope that you and the reviewers will consider this work for publication in this journal.

Best regards,

Stéphane Verger

Review: Characterising the mechanics of cell–cell adhesion in plants — R0/PR2

Conflict of interest statement

Reviwer declares none.

Comments

Comments to Author: This well written manuscript outlines the challenges to understand both the molecular mechanisms and the mechanics of cell adhesion in plants. Although principally focused on plants cells the review does consider what is known in other systems most notably animal cells and outlines a range of methodological approaches. The challenges of the study of cell adhesion for an organism with walled cells is well presented. The manuscript is thoughtful, authoritative and up-to-date and is well prepared and well-illustrated.

The manuscript is excellent in setting the scene for approaches – which may or may not be practicable for plant cells. The idea of preparing plant cell doublets for analyses is a good approach to think about - but of course may be less achievable in practice. The article is good in that it recognizes that cell to cell adhesion strength between plant cells may be greater than that of the cell wall – and thus any intervention to pull cells apart may lead to cell rupture rather than a controlled loss of cell adhesion.

The schematic representation of plant cells being rounded (as for animal cells) in Figure 2 – is perhaps not ideal and more defined shapes would indicate the importance of the cell wall in imposing cell geometries.

The authors could indicate understanding cell adhesion across plant organs is potentially even more challenging in that middle lamellae can have different origins – depending on, for example, their occurrence in transverse or in longitudinal walls in an elongating organ. The former being direct unexpanded regions deposited at cytokinesis and the latter arising from the often considerable extension of an original middle lamella/cell adhesion plane to be the interface between several cells due to directional cell elongation. Therefore it is possible, for example, that some treatments may release files of cells with transverse adhesions intact.

The authors are correct to highlight the lack of precise knowledge of how pectin functions in cell adhesion and they could also indicate that there is evidence in some cases that xyloglucan may be involved (Ikegaya et al. (2008) Presence of xyloglucan-like polysaccharide in Spirogyra and possible involvement in cell–cell attachment. Phycological Research 56, 216-222; Ordaz-Ortiz et al. (2009) Cell wall microstructure analysis implicates hemicellulose polysaccharides in cell adhesion in tomato fruit pericarp parenchyma. Molecular Plant 2, 910-921). There is also the issue of where the cell adhesion load is in relation to the complex polysaccharide networks across the two primary cell walls and middle lamellae that are between two adjacent cell membranes. What and where are the weakest links across such a cell interface and how are the molecules that have a primary function in cell adhesion linked into cell wall structures?

In summary, this is an excellent overview of the topic that should provide a keen stimulus for future research in this important area.

Review: Characterising the mechanics of cell–cell adhesion in plants — R0/PR3

Conflict of interest statement

Reviewer declares none.

Comments

Comments to Author: In this review article, the authors present the state of current knowledge of cell-cell adhesion in plants, as well as in animals and other species, introduce the mechanical concepts required to understand cell-cell adhesion, summarize a range of methods that have been used to measure cell-substrate or cell-cell adhesion in (mostly non-plant) biological systems, and discuss whether these methods could be used to measure cell-cell adhesion in plants and open new avenues of research. Cell-cell adhesion in plants is a fascinating and important topic that touches on many aspects of plant growth and development, and even on biotechnological aspects (for example, Yang et al. 2020, cited here, has implications for biofuel processing of poplar), but is poorly understood. Thus, this review article is timely and interesting, but could benefit from some revisions as suggested below.

Major Comments:

For a submission to Quantitative Plant Biology, I was struck by how non-quantitative the review is. Although it does a good job of presenting mechanics concepts in Figure 1, almost no numerical measurements or predictions of cell-cell adhesion forces in plants are reported, nor are they placed in a quantitative/mathematical framework that might allow for useful interpretation of experimental data, although finite element modeling is mentioned in passing. For example, in Line (L) 412, the authors posit that cell-cell adhesion is likely much stronger in plants than in animals; how much stronger, even to an order of magnitude?

Figure 1: Please standardize the font and font sizes throughout the figure (I suggest using 12 pt Arial for the panel letters and 10 or 8 pt Arial for all other text); panel A could be made larger to fill some of the white space and make it more readable. Since this review is mostly about plant cell adhesion, it might be helpful to depict more realistic cartoons of plant cells, making them rectangles or long hexagons rather than ovals.

Figure 2: Very few plant cell types are rounded like this, and cellular geometry likely influences cell adhesion mechanics, so I would suggest depicting both plant and animal cells more realistically here – as they stand now, the models remind me of the tendency in physics to approximate objects as spheres. Additionally, plant cells (and animal cells) are rarely present as doublets – I know that is for simplicity’s sake here, but maybe other surrounding cells could be shown in gray? These surrounding cells would influence cortical tension as shown. Junctions in the form of plasmodesmata are often present between plant cells, but are not shown here (or mentioned anywhere in the review) – I think they should be considered. I would also argue that we DO know something about cell wall organization (or at least composition) at the extremity of the cell-cell connection in plant cells, since researchers have detected particular structures/epitopes at tricellular junctions in various plant tissues (see, for example, work by Willats).

The section on animal cell-cell adhesion should be revised to more precisely define the molecular and cellular mechanics involved in cell adhesion. This section could also be connected to a new panel in Figure 3 that shows at least one example of these molecular players in a mechanical context.

The summary paragraph from L218-238 is repetitive and could be shortened – for example, the reintroduction of organ abscission or intrusive growth seems unnecessary. If you want to highlight these phenomena, why not show them in a figure, along with other examples of cell separation in plants such as pollen tetrad separation, pollen tube growth, and lateral root formation?

Section beginning L274: I am not sure cell shape-based adhesion energy estimation would apply to plant cells, given that they have semi-rigid walls that resist deformation; this caveat should be explicitly stated, rather than obliquely hinted at in the final sentence. This is covered later in the manuscript (L441), but these two ideas should be closely connected. In fact, it may aid the organization of the review to present each different method for measuring cell adhesion, then discuss how it could be applied to studying plants, rather than lumping all of the methods and all of the discussions together, separating each method from the discussion of how it could be applied (or not) in plants.

Cell-substrate adhesion has been studied in algae, such as Penium, that have wall composition similar to that of emrbyophytes (true plants); the authors could cite examples from Domozych and others of studies of Penium adhesion to substrates that is pectin-dependent.

Commas are often misused (mostly overused) in the manuscript. For example, in L30, the first two commas could be removed from the sentence starting “The precise fine-tuning”. In general, I would suggest reading the sentence out loud and adding commas only where one would naturally pause while speaking the sentence.

Minor Comments:

Many of the internal citations include first initials; these can likely be removed.

L24: Replace “But” with “However,”

L28: replace “rather” with “also”

L32: should be “fiber cell”

L34: “lateral” doesn’t need to be capitalized

L35: should be “space”

L36: should be “and how adhesion resists and adapts to”

L43: remove “the”

L50: From this sentence and the description in Figure 1, it is not clear how stress is independent of the dimensions of the sample – isn’t it defined as force over cross-sectional area? Please clarify – do you mean that the applied force and the strain are dimension-independent?

L85: I believe this citation should be “Bou Daher & Braybrook, 2015”, since Bou Daher is the first author’s surname

L118: remove comma

L128: I don’t think it is true that most monocots have small amounts of pectins in their cell walls, although grasses do. Grasses are a subset of monocots, so this sentence should be revised.

L157: should be “maintaining”

L159: would it be worthwhile to name these mutants, for instance in a table?

L166: remove “and it is”

L184: “and mediate”

L188: remove “a”; including a space between 5 and pN would aid readability

L192-196: please indicate the range of cadherin-cadherin adhesion tension and cell-cell binding energy to give the reader a quantitative sense of these values

L198: remove second “the”

L203: remove “the”

L207: revise “largely studied” to “studied in detail” or “intensively studied”

L215: the surface of what?

L216: revise to “This creates strong anchorage between an organism and its substrate or host cells”

L241: revise “rather focus” to “focused”

L243: remove “rather”

L254: should be “96-well”

L260: missing space between Fig. and 3C

L286: should be “96 well plate”

L302: write out “single cell force spectroscopy”

L303: could this be called a “suction pump” instead of a negative pressure pump?

L320: should be “use”

L329: why not consistently call this suction rather than negative pressure? Using both terms seems over-complicated

334: no need for the acronym SCFS since it is not very common and is only used three times in the main text

345: suggest replacing “denature” with “disrupt”; could use “adhesion properties” rather than “properties of adhesion”

L364: remove first comma

L366: “such a tissue”

L368: remove “the”

L370: “quantification of cell adhesion mechanics”

L374: “consists of”; remove comma

L375: replace “shaking by a vortex” with “vortexing”

L392: replace “Lilly stylar” with “lily (Lilium sp.) styles”

L402: they used a laser beam, not an ion beam, for that experiment

L420: “hydrodynamic”

L432: remove “plants”

L458: “micromanipulation”

L473: remove first comma

L477 “cell adhesion-defective”

L484: replace “inform of” to “provide information regarding”

L489: “treatments”

L506: replace “vastly” with “extensively”

L507: remove “The precious”

Recommendation: Characterising the mechanics of cell–cell adhesion in plants — R0/PR4

Comments

Comments to Author: Both reviewers praised the quality of your manuscript. Reviewer 1 suggested a few changes and additions.They are mere suggestions, which you can decide to follow or not. Reviewer 2 asked for more revisions, although still minor, especially regarding the figures and the presentation of methods for measuring cell adhesion. These points should be addressed in your revised manuscript.

Decision: Characterising the mechanics of cell–cell adhesion in plants — R0/PR5

Comments

No accompanying comment.