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Pollen movement of the endemic Agave cupreata by bats and birds in western Mexico

Published online by Cambridge University Press:  04 April 2024

Rosario Arreola-Gómez
Affiliation:
Instituto de Investigaciones sobre los Recursos Naturales, Universidad Michoacana de San Nicolás de Hidalgo, Morelia, Michoacán, México
Eduardo Mendoza*
Affiliation:
Instituto de Investigaciones sobre los Recursos Naturales, Universidad Michoacana de San Nicolás de Hidalgo, Morelia, Michoacán, México
*
Corresponding author: Eduardo Mendoza; Email: [email protected]
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Abstract

We quantified the amount of pollen carried by bats and birds visiting the flowers of cultivated and wild individuals of the endemic Agave cupreata in western Mexico and estimated the distance to which pollen was moved using diurnal/nocturnal inflorescence exclusions and fluorescent powders. There were no differences in the amount of pollen transported by bats and birds near cultivated and wild agaves, but overall, bats transported greater loads than birds. Nocturnal pollen movement was more frequent, and the maximum distance recorded was 630 m (diurnal and nocturnal), with no transfer between cultivated and wild plants. Bats seem to provide a greater pollination service than birds in our focal anthropized landscape. It is necessary to incorporate management practices into mezcal production that ensure enough food for the wide array of animal species using this resource, which in turn will help to maintain the pollination service.

Type
Short Communication
Copyright
© The Author(s), 2024. Published by Cambridge University Press

Introduction

Most flowering plants depend on animal vectors for reproduction (IPBES, 2016). Even self-pollinated species benefit from animal visitation due to its favourable effect on genetic interchange (Potts et al. Reference Potts, Biesmeijer, Kremen, Neumann, Schweiger and Kunin2010). The amount of pollen transported and the distance to which it is deposited are critical factors affecting the reproductive success of plants due to their role in connecting plant populations, reducing endogamy, and, therefore, inbreeding depression (Allison, Reference Allison1990, García Cruzatty et al. Reference García Cruzatty, Rivero, Vásconez, Peñarrieta and Droppelmann2017, Young et al. Reference Young, Boyle and Brown1996). Pollen movement becomes a particularly relevant process in anthropized landscapes where the sizes of plant populations decrease, and isolation increases due to habitat fragmentation (Breed et al. Reference Breed, Ottewell, Gardner, Marklund, Dormontt and Lowe2015). The degree to which pollen movement is affected in anthropized landscapes is most likely related to animal vector characteristics, such as body size, mobility, behaviour, and susceptibility to habitat perturbation (Breed et al. Reference Breed, Ottewell, Gardner, Marklund, Dormontt and Lowe2015, Laforge et al. Reference Laforge, Archaux, Coulon, Sirami, Froidevaux, Gouix, Ladet, Martin, Barré, Roemer, Claireau, Kerbiriou and Barbaro2021). However, limited information on the characteristics of pollen movement by animals greatly hinders broadening the understanding of anthropic habitat perturbation’s impacts on plant pollination and population connectivity (Nora et al. Reference Nora, Albaladejo, González-Martínez, Robledo-Arnuncio and Aparicio2011).

Mexico is a diversification centre of plants in the genus Agave (locally known as ‘magueyes’ or ‘agaves’). Of a worldwide total of 210 species, as many as 159 (75%) occur in Mexico, and 126 (61%) are endemic (García-Mendoza et al. Reference García-Mendoza, Franco Martínez and Sandoval Gutiérrez2019). The plants in the genus Agave have special ecological, cultural, and economic relevance in Mexico (Colunga-García Marín et al. Reference Colunga-García Marín, Zizumbo-Villarreal, Martínez-Torres, Colunga-García, Larqué, Eguiarte and Zizumbo-Villarreal2007, Eguiarte et al. Reference Eguiarte, Jiménez Barrón, Aguirre-Planter, Scheinvar, Gamez, Gasca-Pineda, Castellanos-Morales, Moreno-Letelier and Souza2021, Torres-García et al. Reference Torres-García, Rendón-Sandoval, Blancas and Moreno-Calles2019). Since prehispanic times, agaves have been used as raw material to produce distilled beverages; however, growing demand for tequila and mezcal has fuelled an increase in agave harvest, which is having several negative environmental and social impacts, such as depletion of wild populations, pollution by agrochemicals, loss of natural habitats, displacement of subsistence crops, and marginalisation of small-scale agave farmers (Martínez Castro et al. Reference Martínez Castro, Martínez-Palacios, Sánchez Vargas, Lobitte, Nápoles Alvarez, Martínez Palacios, Villegas, Martínez Avalos, Golubov, Martínez-Palacios, Morales-García and Guillén Rodríguez2015, Tetreault et al. Reference Tetreault, McCulligh and Lucio2021).

Bats are the primary pollinators of agaves (Arizaga et al. Reference Arizaga, Ezcurra, Peters, de Arellano and Vega2000, Rocha et al. Reference Rocha, Valera and Eguiarte2005, Trejo-Salazar et al. Reference Trejo-Salazar, Scheinvar and Eguiarte2015). However, many bird species (e.g., orioles, hummingbirds, warblers, and woodpeckers) are also common visitors of these plants (Sutherland, Reference Sutherland1987, Slauson, Reference Slauson2000, Ornelas et al. Reference Ornelas, Ordano, Hernández, López, Mendoza and Perroni2002). Bat and bird species can differ in their capacities to move pollen and in their response to the anthropogenic modification of the landscape (Muchhala and Thomson, Reference Muchhala and Thomson2010, Laforge et al. Reference Laforge, Archaux, Coulon, Sirami, Froidevaux, Gouix, Ladet, Martin, Barré, Roemer, Claireau, Kerbiriou and Barbaro2021, Paxton et al. Reference Paxton, Smetzer, Hart, Anderson and Paxton2023). In this study, we assess whether bats outperform birds in their capacity to move the pollen of endemic Agave cupreata (locally known as ‘Maguey chino’) in an anthropized landscape in western Mexico.

Materials and methods

We conducted this study in the locality of Las Azucenas within the municipality of Madero, Michoacan in western Mexico. The municipality of Madero has an average temperature range of 12°C to 26°C, an annual precipitation of between 800 and 1,300 mm, and an altitude of between 800 and 2,900 m (INEGI, 2009). A. cupreata is a species endemic to the Balsas River basin and the Sierra Madre Sur mountains in Guerrero and Michoacán (Martínez Castro et al. Reference Martínez Castro, Martínez-Palacios, Sánchez Vargas, Lobitte, Nápoles Alvarez, Martínez Palacios, Villegas, Martínez Avalos, Golubov, Martínez-Palacios, Morales-García and Guillén Rodríguez2015). It is a semelparous plant with protandrous and multi-ovulate flowers (Illsey Granich et al. Reference Illsey Granich, Gómez Alarcón, Rivera Méndez, Morales Moreno, García Bazán, Ojeda Sotelo, Calzada Rendón and Mancilla Nava2005). This species takes between eight and nine years, approximately, to reach the size to be used to produce mezcal and, in contrast to other agave species, its capacity for vegetative reproduction is null (Illsey Granich et al. Reference Illsey Granich, Gómez Alarcón, Rivera Méndez, Morales Moreno, García Bazán, Ojeda Sotelo, Calzada Rendón and Mancilla Nava2005, Gallardo Valdez et al. Reference Gallardo Valdez, Gschaedler Mathis, Cházaro Basáñez, Rodríguez Domínguez, Tapia Campos, Villanueva Rodríguez, Salado Ponce, Villegas García, Medina Niño, Aguirre Ochoa and Vallejo Pedraza2008). This characteristic makes the reproduction of this species highly dependent on animal visitation. The A. cupreata has been used in the region to produce mezcal for about 400 years, and it is currently a source of income for an increasing number of families (Martínez Castro et al. Reference Martínez Castro, Martínez-Palacios, Sánchez Vargas, Lobitte, Nápoles Alvarez, Martínez Palacios, Villegas, Martínez Avalos, Golubov, Martínez-Palacios, Morales-García and Guillén Rodríguez2015). In our study area, wild and cultivated agaves coexist. Cultivated agaves are grown in greenhouses for about the first two years. Then, at the onset of the rainy season, they are transplanted to hill slopes, which have been cleared of their natural vegetation, where they reach maturity. Therefore, cultivated agaves are grown in areas with more open vegetation whereas wild agaves are more associated with forested areas (Fig. 1a and 1b). Cultivated agaves tend to be taller than wild agaves (the averages from a sample of eight cultivated agaves and eight wild agaves were 6.67 vs. 5.27 m). This is likely due to greater exposure to sunlight. No other morphology differences are evident between cultivated and wild agaves.

Figure 1. (a) Wild and (b) cultivated Agave cupreata plants in Madero, Michoacán, western Mexico; (c) Leptonycteris nivalis covered with pollen grains of A. cupreata; (d) Wooden platform built to reach the inflorescences of A. cupreata; (e) and (f) Nocturnal search of pollen grains of A. cupreata marked with fluorescent powder of different colours to differentiate between diurnal and nocturnal movements.

In the February–April 2017 period, we independently evaluated two aspects of the capacity of birds and bats to transport A. cupreata pollen: (a) the amount of pollen carried on the animal’s body and (b) the distance to which pollen was moved. To quantify the amount of pollen carried by birds and bats visiting A. cupreata, we conducted diurnal and nocturnal surveys near cultivated and wild agaves for 22 days (11 days each) using six mist nests (12 m × 2.5 m and 6 m × 2.5 m). These nets were set at an approximate height of three metres and were active from 19:00 to 2:00 to capture bats and from 7:00 to 12:00 and 16:00 to 19:00 to capture birds. The captured bird and bat species were identified using field guides (Howell and Webb, Reference Howell and Webb1995; Medellín et al. Reference Medellín, Arita and Sánchez1997). Regarding birds, we focused on collecting pollen samples from individuals in the Trochilinae family (hereafter hummingbirds) and the Icterus genus (hereafter orioles). For bats, we only collected pollen samples from Leptonycteris nivalis and Choeronycteris mexicana (Fig. 1c). We focused on these species because a previous study indicated them as the vertebrates that visited the flowers of A. cupreata most frequently in our study area (Arreola-Gómez, Reference Arreola-Gómez2018). To collect samples, we rubbed small cubes of Kisser glycerol gelatine on the plumage or fur of the captured birds and bats’ cephalic, dorsal, and ventral areas (Caballero-Martínez et al. Reference Caballero-Martínez, Rivas Manzano and Aguilera Gómez2009). These Kisser gelatine cubes were deposited in labelled glass jars. After taking the samples, the animals were safely released, following the corresponding protocols to avoid harming the birds and bats as we handled them (Ralph et al. Reference Ralph, Geupel, Pyle, Martin, de Sante and Milá1996, Suárez-Alvarez and López-Berrizbeitia, Reference Suárez-Alvarez and López-Berrizbeitia2020).

Once in the lab, we used a syringe to take a 0.05 mL sample from a random spot in the gelatine cube, which was later melted and placed on slides to be observed under the microscope (Model: Trino III). To count all the pollen grains, we selected a point at one end of each slide and visually moved across it horizontally. As a reference for the identification of A. cupreata pollen, we used preparations made with pollen grains of this species collected directly from their flowers. We applied an Analysis of Variance and a post hoc Tukey test to assess whether there was a contrast in the amount of moved pollen (Log10 transformed) between the type of agave (cultivated vs. wild) and among animal groups (i.e., hummingbirds, orioles, L. nivalis, and C. mexicana). We tested for the model’s residual normality; analyses were conducted using the R programme (R Core Team, 2021).

A few days after the bird and bat capture, we conducted a separate experiment to estimate the distance that the pollen was moved in which we selected two A. cupreata plants (one cultivated and the other wild) with 1,364 m between them. We marked the pollen in these plants with fluorescent powders, which have been widely used to study pollination by animals, mainly insects (Eisikowitch and Galil, Reference Eisikowitch and Galil1971, Terry et al. Reference Terry, Walter, Donaldson, Snow, Forster and Machin2005). However, its use to study pollination by bats and birds is more limited. To distinguish between pollen transported by birds or bats, at dusk, we marked the anthers of two umbels of the cultivated agave with green powder and the anthers of two umbels of the wild agave with pink powder. These umbels remained exposed throughout the entire night. At dawn, we covered these umbels with organza bags and then marked two other umbels of the same agaves with orange powder (cultivated agave) and two umbels with blue powder (wild agave). These umbels remained exposed during the day and were covered with organza bags at dusk. We built wooden platforms to allow a person to safely stand on to reach the umbels of the focal agaves. These platforms were finished well in advance of the start of the experiment to minimise any disturbance to plant visitors (Fig. 1d). We repeated both procedures for two consecutive days. After marking the umbels, we searched for fluorescent powder in the inflorescences of eight A. cupreata plants, which were distributed along a terrain strip spanning a length of two km. We conducted this search for two nights using an ultraviolet lamp (Model 7020 Hampton Bay) attached to the end of a metallic pole (Fig. 1e and 1f). Once we detected the presence of fluorescent powder, we recorded the coordinates of the agave. We calculated the distance of the movement using the software Qgis ver. 3.22 (QGIS Development Team, 2021).

Results

We completed a nocturnal sampling effort of 8,820 hours, which allowed us to capture 40 bats (17 L. nivalis and 23 C. mexicana). Moreover, we completed 10,080 hours of diurnal sampling, capturing 58 birds (21 hummingbirds and 37 orioles). Samples from most of the captured bats and birds, in both cultivated and wild agaves, had pollen (Fig. 2a). We did not detect statistical differences in the number of pollen grains from samples of cultivated agave versus wild agave (F = 0.482, df = 1/89, P = 0.4892, Table S1). However, we did find differences among the visitors (F = 24.295, df = 3/89, P < 0.001, Table S1). The Tukey test (α = 0.05) indicated that all the animal groups carried different amounts of pollen except for orioles and hummingbirds. Samples from bats had, by far, the greatest amount of pollen, particularly those of L. nivalis (Fig. 2b).

Figure 2. (a) Percentage of captured birds and bats with pollen grains from the endemic Agave cupreata in Madero, Michoacan, western Mexico; (b) Differences in the average amount of pollen of A. cupreata recorded in samples taken from the body of birds and bats. Species key: CME = Choeronycteris mexicana, ICT = Icterus spp., LNI = Leptonycteris nivalis, TRO = Trochilidae; (c) Map showing pollen movement by birds and bats in Madero, Michoacan, western Mexico. Squares indicate pollen sources and triangles, agaves in which pollen was deposited.

We recorded five events of pollen movement between agaves (Fig. 2c). Three of them were nocturnal, as indicated by the pink, fluorescent powder, and occurred within the forest. One involved the transference of pollen between two umbels of the same wild agave, which were separated by 0.5 m. The other two transferences occurred between wild agaves located at distances of 30 m and 45 m (Fig. 2c). Moreover, we recorded pollen transportation between cultivated agaves located at 630 m (Fig. 2c). This event of pollen transportation involved diurnal and nocturnal fauna, as indicated by the presence of green and orange powder. There was no documented movement between cultivated and wild agaves.

Discussion

We found evidence that bats are highly important pollen vectors for A. cupreata in our anthropized landscape. Based on the amount of pollen carried on their bodies and the frequency of pollen movement events between conspecific plants, bats seemed to outperform birds, particularly L. nivalis. There were also significant differences in the amount of pollen transported by L. nivalis and C. mexicana, which are likely related to their different foraging patterns. L. nivalis frequently touches the stamens and petals of A. cupreata flowers and, in some instances, even hangs on the umbels with its wings opened. In contrast, C. mexicana hovers while visiting different flowers in sequence, rarely touching them (Arreola-Gómez, pers. obs.).

Birds transported less pollen on their bodies than bats and seemingly moved it less frequently among agaves as well. However, most of the sampled birds had pollen on their bodies, suggesting they might play an important supporting role in securing a minimum level of pollination success in cases when plants are infrequently visited by bats. This effect can be reinforced by other vertebrates, such as the Grayish mouse opossum (Tlacuatzin canescens) and the Virginia opossum (Didelphis virginiana), which have also been recorded visiting the flowers of A. cupreata and displaying abundant pollen in their fur (Arreola-Gómez and Mendoza, Reference Arreola-Gómez and Mendoza2020). The existence of a wide number of vertebrate (and likely invertebrate) species moving pollen among A. cupreata flowers might provide populations of this plant with a certain level of resilience to the effects of habitat degradation. Furthermore, the wide array of animal species visiting the flowers of A. cupreata is indicative of this plant species’ great relevance as a local food source (Ornelas et al. Reference Ornelas, Ordano, Hernández, López, Mendoza and Perroni2002).

The distance between the wild and cultivated agaves was within the range of movement of the nectarivorous bats (Medellín et al. Reference Medellín, Rivero, Ibarra, de la Torre, Gonzalez-Terrazas, Torres-Knoop and Tschapka2018); however, we did not detect pollen transference between them. However, it is necessary to conduct subsequent studies involving a greater sampling effort to establish whether the absence of pollen movement between wild and cultivated agaves is the rule or whether our study design did not capture this type of movement. Moreover, we assumed that diurnal and nocturnal pollen transfer was conducted by the birds and bats we had previously identified as the primary visitors to A. cupreata flowers. However, a great variety of animals (including insects) visit A. cupreata flowers. The use of selective exclosures would help to gain a more accurate view of the relative importance of different groups of species as pollen vectors for A. cupreata.

Our results highlight the need to implement strategies to favour the permanence of bats in the region. For example, it is important to identify sites that are of special importance for bats, such as those that provide them shelter (e.g., caves or hollows in tree trunks), to ensure their protection. Paradoxically, the increased demand for agave plants to produce mezcal can harm the bats (and other animals) that depend on the food resources provided by A. cupreata flowers. To increase the size of the agaves and their sugar content, which results in more raw material to produce mezcal, local producers prevent their reproduction because it inevitably leads to the plants’ death (i.e., monocarpic reproduction). Moreover, because the only way to have new plants is through seed germination, theft of spikes with mature seeds has surged in our study region. This risk has also motivated people to reduce the number of flowering agaves. If these practices escalate, agave nectar can become a very limited resource for a variety of animal species, including bats, which in turn would have negative repercussions on the pollination service.

Supplementary material

The supplementary material for this article can be found at https://doi.org/10.1017/S0266467424000087.

Acknowledgements

We thank Daniel Ferreyra, Calletano Montaño, and Carlos Ontiveros for their help in conducting fieldwork and the local agave and mezcal producers for supporting this study. Franceli Macedo helped design the figures included in this paper.

Financial support

This research was supported by the Office of Scientific Research (Coordinación de la Investigación Científica, CIC, for its Spanish initials) of Universidad Michoacana de San Nicolás de Hidalgo and Mexico’s Secretariat of Public Education through the Prodep Network ‘Conservation of biodiversity in anthropized environments’ (Conservación de la Biodiversidad en Ambientes Antropizados).

Competing interests

The authors declare none.

References

Allison, T (1990) Pollen production and plant density affect pollination and seed production in Taxus canadensis . Ecology 71, 516522.CrossRefGoogle Scholar
Arizaga, S, Ezcurra, E, Peters, E, de Arellano, FR and Vega, E (2000) Pollination ecology of Agave macroacantha (Agavaceae) in a Mexican tropical desert. The role of pollinators. American Journal of Botany 87, 10111017.CrossRefGoogle Scholar
Arreola-Gómez, R (2018) Ensamble de visitantes florales de Agave cupreata en el Municipio de Madero Michoacán. Master thesis. Universidad Michoacana de San Nicolás de Hidalgo. Morelia Michoacán.Google Scholar
Arreola-Gómez, R and Mendoza, E (2020) Marsupial visitation to the inflorescences of the endemic Agave cupreata in western México. Western North American Naturalist 80, 563568.CrossRefGoogle Scholar
Breed, M, Ottewell, K, Gardner, MG, Marklund, MHK, Dormontt, EE and Lowe, AJ (2015) Mating patterns and pollinator mobility are critical traits in forest fragmentation genetics. Heredity 115, 108114.CrossRefGoogle ScholarPubMed
Caballero-Martínez, LA, Rivas Manzano, IV and Aguilera Gómez, LI (2009) Hábitos alimentarios de Anoura geoffroyi (Chiroptera: Phyllostomidae) en Ixtapan del Oro, Estado de México. Acta Zoológica Mexicana 5, 161175.Google Scholar
Colunga-García Marín, P, Zizumbo-Villarreal, D and Martínez-Torres, J (2007) Tradiciones en el aprovechamiento de los agaves mexicanos: una aportación a la protección legal y conservación de su diversidad biológica y cultural. In Colunga-García, Marín P, Larqué, Saavedra A, Eguiarte, L and Zizumbo-Villarreal, D (eds), En lo ancestral hay futuro: del tequila, los mezcales y otros agaves. Yucatán, México: Centro de Investigación Científica de Yucatán, pp. 229248.Google Scholar
Eguiarte, LE, Jiménez Barrón, OA, Aguirre-Planter, E, Scheinvar, E, Gamez, N, Gasca-Pineda, J, Castellanos-Morales, G, Moreno-Letelier, A and Souza, V (2021) Evolutionary ecology of Agave: distribution patterns, phylogeny, and coevolution (an homage to Howard S. Gentry). American Journal of Botany 108, 216235.CrossRefGoogle Scholar
Eisikowitch, D and Galil, J (1971) Effect of wind on the pollination of Pancratium maritimum L. (Amaryllidaceae) by hawkmoths (Lepidoptera: Sphingidae). The Journal of Animal Ecology 40, 673678.CrossRefGoogle Scholar
Gallardo Valdez, J, Gschaedler Mathis, AC, Cházaro Basáñez, MJ, Rodríguez Domínguez, JM, Tapia Campos, E, Villanueva Rodríguez, S, Salado Ponce, JH, Villegas García, E, Medina Niño, R, Aguirre Ochoa, M and Vallejo Pedraza, M (2008) La producción de Mezcal en el estado de Michoacán. Centro de investigación y asistencia en tecnología y diseño del estado de Jalisco A.C. Michoacán, México: Gobierno del Estado de Michoacán, p. 156.Google Scholar
García Cruzatty, L, Rivero, M, Vásconez, G, Peñarrieta, S and Droppelmann, F (2017) Eficiencia reproductiva y producción de polen en Nothofagus alpina en un huerto semillero clonal. Bosque 38, 133139.CrossRefGoogle Scholar
García-Mendoza, AJ, Franco Martínez, IS and Sandoval Gutiérrez, D (2019) Cuatro especies nuevas de Agave (Asparagaceae, Agavoideae) del sur de México. Acta Botánica Mexicana 126, e1461.Google Scholar
Howell, SN and Webb, S (1995) A Guide to the Birds of Mexico and Northern Central America. Bonn, Germany: Oxford University Press.CrossRefGoogle Scholar
Illsey Granich, C, Gómez Alarcón, T, Rivera Méndez, G, Morales Moreno, MP, García Bazán, J, Ojeda Sotelo, A, Calzada Rendón, M and Mancilla Nava, S (2005) Conservación in situ y manejo campesino de magueyes mezcaleros. Grupo de Estudios Ambientales AC. Informe final SNIB-CONABIO proyecto No. V028. México D. F.Google Scholar
INEGI (2009) Prontuario de información geográfica Municipal de los Estados Unidos Mexicanos. México: Madero Michoacán de Ocampo.Google Scholar
IPBES (2016) Summary for Policymakers of the Assessment Report of the Intergovernmental Science-Policy Platform on Biodiversity and Ecosystem Services on Pollinators, Pollination and Food Production. Bonn, Germany: Zenodo. https://doi.org/10.5281/zenodo.2616458.Google Scholar
Laforge, A, Archaux, F, Coulon, A, Sirami, C, Froidevaux, J, Gouix, N, Ladet, S, Martin, H, Barré, K, Roemer, C, Claireau, F, Kerbiriou, C and Barbaro, L (2021) Landscape composition and life-history traits influence bat movement and space use: analysis of 30 years of published telemetry data. Global Ecology and Biogeography 30, 24422454.CrossRefGoogle Scholar
Martínez Castro, LE, Martínez-Palacios, M, Sánchez Vargas, NM, Lobitte, P, Nápoles Alvarez, CR, Martínez Palacios, O, Villegas, J, Martínez Avalos, JG and Golubov, J (2015) Poblaciones silvestres de Maguey Chino (Agave cupreata) en el Estado de Michoacán Aspectos sobre el Manejo y la Conservación de Agaves Mezcaleros en Michoacán. In Martínez-Palacios, A, Morales-García, LE and Guillén Rodríguez, S (eds), Aspectos sobre el Manejo y la Conservación de Agaves Mezcaleros en Michoacán. Michoacán, México: Universidad Michoacana de San Nicolás de Hidalgo, Secretaría de Agricultura, Ganadería, Desarrollo Rural, Pesca y Alimentación, Consejo Estatal de Ciencia, Tecnología e Innovación, pp. 167175.Google Scholar
Medellín, RA, Arita, HT and Sánchez, O (1997) Identificación de los murciélagos de México: Clave de Campo. México: Consejo Nacional de Ciencia y Tecnología, Instituto de Ecología, UNAM, p. 80.Google Scholar
Medellín, RA, Rivero, M, Ibarra, A, de la Torre, JA, Gonzalez-Terrazas, TP, Torres-Knoop, L and Tschapka, M (2018) Follow me: foraging distances of Leptonycteris yerbabuenae (Chiroptera: Phyllostomidae) in Sonora determined by fluorescent powder. Journal of Mammalogy 20, 306311.CrossRefGoogle Scholar
Muchhala, N and Thomson, JD (2010) Fur versus feathers: pollen delivery by bats and hummingbirds and consequences for pollen production. The American Naturalist 175, 717726.CrossRefGoogle ScholarPubMed
Nora, S, Albaladejo, RG, González-Martínez, SC, Robledo-Arnuncio, JJ and Aparicio, A (2011) Movimiento de genes (polen y semillas) en poblaciones fragmentadas de plantas. Ecosistemas 20, 3545.Google Scholar
Ornelas, JF, Ordano, M, Hernández, A, López, JC, Mendoza, L and Perroni, Y (2002) Nectar oasis produced by Agave marmorata Roezl. (Agavaceae) lead to spatial and temporal segregation among nectarivores in the Tehuacán Valley, México. Journal of Arid Environments 52, 3751.CrossRefGoogle Scholar
Paxton, KL, Smetzer, JR, Hart, PJ, Anderson, MJ and Paxton, EH (2023) Landscape configuration alters movement behavior and space-use of a Hawaiian forest bird community. Journal of Avian Biology, 2023, e03117.Google Scholar
Potts, SG, Biesmeijer, JC, Kremen, C, Neumann, P, Schweiger, O and Kunin, WE (2010) Global pollinator declines: trends, impacts and drivers. Trends in Ecology & Evolution 25, 345353.CrossRefGoogle ScholarPubMed
QGIS Development Team (2021) QGIS Geographic Information System. Open Source Geospatial Foundation. http://qgis.org Google Scholar
R Core Team (2021) R: A Language and Environment for Statistical Computing. Vienna, Austria: R Foundation for Statistical Computing. https://www.R-project.org/ Google Scholar
Ralph, C, Geupel, GR, Pyle, P, Martin, TE, de Sante, DF and Milá, B (1996) Manual de métodos de campo para el monitoreo de aves terrestres. Gen. Tech. Rep. PSW-GTR159. Albany,CA: Pacific Southwest Research Station, Forest Service, U.S. Department of Agriculture, 46 p.CrossRefGoogle Scholar
Rocha, M, Valera, A and Eguiarte, LE (2005) Reproductive ecology of five sympatric Agave Littaea (Agavaceae) species in central Mexico. American Journal of Botany 92, 13301341.CrossRefGoogle ScholarPubMed
Slauson, LA (2000) Pollination biology of two quiropterophilous agaves in Arizona. American Journal of Botany 87, 825836.CrossRefGoogle ScholarPubMed
Suárez-Alvarez, R and López-Berrizbeitia, F (2020) Manual de manejo de murciélagos en el campo. Red Latinoamericana y del Caribe para la conservación de Murciélagos. https://www.relcomlatinoamerica.net/images/PDFs/Manual_de_manejo_de_murcielagos.pdf Google Scholar
Sutherland, SD (1987) Why hermaphroditic plants produce many more flowers than fruits: experimental tests with Agave mckelveyana . Evolution 41, 750759.CrossRefGoogle ScholarPubMed
Terry, LI, Walter, GH, Donaldson, JS, Snow, E, Forster, PI and Machin, PJ (2005) Pollination of Australian Macrozamia cycads (Zamiaceae): effectiveness and behavior of specialist vectors in a dependent mutualism. American Journal of Botany 92, 931940.CrossRefGoogle Scholar
Tetreault, D, McCulligh, C and Lucio, C (2021) Distilling agro-extractivism: Agave and tequila production in Mexico. Journal of Agrarian Change 21, 219241.CrossRefGoogle Scholar
Torres-García, I, Rendón-Sandoval, FJ, Blancas, J and Moreno-Calles, AI (2019) The genus Agave in agroforestry systems of Mexico. Botanical Sciences 97, 263290.CrossRefGoogle Scholar
Trejo-Salazar, RE, Scheinvar, E and Eguiarte, LE (2015) ¿Quién poliniza realmente los agaves? Diversidad de visitantes florales en 3 especies de Agave (Agavoideae: Asparagaceae). Revista Mexicana de Biodiversidad 86, 358369.CrossRefGoogle Scholar
Young, A, Boyle, T and Brown, T (1996) The population genetic consequences of habitat fragmentation for plants. Trends in Ecology & Evolution 11, 413418.CrossRefGoogle ScholarPubMed
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Figure 1. (a) Wild and (b) cultivated Agave cupreata plants in Madero, Michoacán, western Mexico; (c) Leptonycteris nivalis covered with pollen grains of A. cupreata; (d) Wooden platform built to reach the inflorescences of A. cupreata; (e) and (f) Nocturnal search of pollen grains of A. cupreata marked with fluorescent powder of different colours to differentiate between diurnal and nocturnal movements.

Figure 1

Figure 2. (a) Percentage of captured birds and bats with pollen grains from the endemic Agave cupreata in Madero, Michoacan, western Mexico; (b) Differences in the average amount of pollen of A. cupreata recorded in samples taken from the body of birds and bats. Species key: CME = Choeronycteris mexicana, ICT = Icterus spp., LNI = Leptonycteris nivalis, TRO = Trochilidae; (c) Map showing pollen movement by birds and bats in Madero, Michoacan, western Mexico. Squares indicate pollen sources and triangles, agaves in which pollen was deposited.

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