Hostname: page-component-cd9895bd7-p9bg8 Total loading time: 0 Render date: 2024-12-28T19:05:59.344Z Has data issue: false hasContentIssue false

Behavioural strategy of the ectosymbiotic crab (Sestrostoma sp.) during ecdysis of the crab and its upogebiid shrimp host

Published online by Cambridge University Press:  16 July 2020

Yuto Shiozaki
Affiliation:
Graduate School of Kuroshio Science, Kochi University, 2–5–1 Akebono, Kochi, Kochi780-8520, Japan
Gyo Itani*
Affiliation:
Graduate School of Kuroshio Science, Kochi University, 2–5–1 Akebono, Kochi, Kochi780-8520, Japan
*
Author for correspondence: Gyo Itani, E-mail: [email protected]
Rights & Permissions [Opens in a new window]

Abstract

Moulting is essential for crustacean growth, but is one of the causes of mortality, because a crustacean cannot move during and just after its ecdysis. In the cases of ectosymbiotic crabs, escape from the host's hostile response may also be a problem during its own ecdysis. In this study, Sestrostoma sp. (Varunidae), an ectosymbiotic crab which clings to the ventral abdomen of upogebiid shrimps with legs that can walk, was studied to clarify how the crab moults and maintains association with the host. Five cases of crab ecdysis were observed, where the crab moulted with its legs clinging to the host abdomen, without detaching from the host body. Time required for moulting was 14–21 min. Shedding of the old exoskeleton (active phase) took only 40–59 s. Sestrostoma sp. detached from the host abdomen and waited in the burrow tube during shrimp ecdysis. The crab then reattached at the same location on the host when shrimp moulting was complete. Our results suggest that Sestrostoma sp. are able to maintain a symbiotic relationship with the same shrimp host after its own ecdysis as well after ecdysis of its host.

Type
Research Article
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 (http://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
Copyright © Marine Biological Association of the United Kingdom 2020

Introduction

Moulting is an essential behaviour for growth in individuals which are covered with their exoskeleton, such as crustaceans. Body expansion occurs by water absorption during moulting (Philippen et al., Reference Phlippen, Webster, Chung and Dircksen2000). Moulting is composed of two phases: a passive, followed by an active phase (Philippen et al., Reference Phlippen, Webster, Chung and Dircksen2000). In the passive phase, the thoraco–abdominal membrane is ruptured by body expansion. The old exoskeleton is shed in the active phase. During ecdysis, especially in the active phase, crustaceans cannot move (Waddy et al., Reference Waddy, Aiken, de Kleijn and Factor1995). In the case of Homarus americanus, the lobster loses mobility during the active phase for 10–20 min (Waddy et al., Reference Waddy, Aiken, de Kleijn and Factor1995). After moulting, the soft body gradually becomes harder. In the blue swimming crab, Portunus pelagicus, the time required for carapace hardening is between 9 and 17 h (Azra et al., Reference Azra, Chen, Hsu, Ikhwanuddin and Abol–Munafi2019).

Ecdysis is one of the causes of crab mortality because of failure to complete, predation or cannibalism (Ryer et al., Reference Ryer, van Montfrans and Moody1997; Bleakley, Reference Bleakley, Wellborn and Thiel2018; Azra et al., Reference Azra, Chen, Hsu, Ikhwanuddin and Abol–Munafi2019; de la Cruz–Huervana et al., Reference de la Cruz–Huervana, Quinitio and Corre2019). Crabs cannot move and defend themselves against, or flee from predators, during and after moulting. In general, crabs moult in a safe space such as in burrows or in seagrass beds, which provide a refuge from predation or cannibalism (Ryer et al., Reference Ryer, van Montfrans and Orth1990; Laidre, Reference Laidre, Wellborn and Thiel2018; Ortega et al., Reference Ortega, Ibeiro, Rodrigues, Rodrigues and Dumont2019). In the case of endosymbiotic crabs, the host may provide a safe space for the crab to moult. For example, the pea crab (Arcotheres sp.), an endoparasite of the sessile bivalve, Barbatia virescens, moults inside the host shell (Watanabe & Henmi, Reference Watanabe and Henmi2009). In the case of ectosymbiotic crabs, the crab usually benefits from the host, obtaining nutrients and protection against predators, but the crab may face the severe risk of dropping off the host's body during the crab's own ecdysis. Ectosymbiotic crabs may therefore have evolved to prevent detachment during their own ecdysis. To the best of our knowledge, however, there has been no research on moulting behaviour of ectosymbiotic crustaceans from this perspective.

The shrimps of the genus Upogebia construct typically Y- or U-shape burrows in muddy sediment (Dworschak, Reference Dworschak1983; Griffis & Suchanek, Reference Griffis and Suchanek1991; Nickell & Atkinson, Reference Nickell and Atkinson1995). The shrimps create water currents with their rhythmically stroking pleopods so that oxygen-rich seawater and organic substances such as phytoplankton or detritus flow into the burrows (Dworschak, Reference Dworschak1987; Dworschak et al., Reference Dworschak, Felder, Tudge, Schram and von Vaupel Klein2012). They feed mainly on suspended matter using the dense setae on the first and second pereiopods (Dworschak, Reference Dworschak1987; Nickell & Atkinson, Reference Nickell and Atkinson1995). It is known that various symbionts inhabit upogebiid burrows or bodies (MacGinitie, Reference MacGinitie1930, Reference MacGinitie1935; Ross, Reference Ross, Vernberg and Vernberg1983). Symbionts of upogebiid shrimps can be divided into ectosymbionts and burrow co-habitants (burrow symbionts) (Itani, Reference Itani and Tamaki2004). In the western Pacific, it is known that ectosymbionts include bopyrid isopods, crabs and bivalves (Kato & Itani, Reference Kato and Itani1995; Itani, Reference Itani2001, Reference Itani and Tamaki2004) and burrow symbionts are shrimps, crabs, copepods, phoronids, bivalves, polychaetes and gobies (Miya, Reference Miya1997; Anker et al., Reference Anker, Jeng and Chan2001; Itani, Reference Itani2001; Sato et al., Reference Sato, Uchida, Itani and Yamashita2001; Kinoshita, Reference Kinoshita2002; Itoh & Nishida, Reference Itoh and Nishida2007; Nara et al., Reference Nara, Akiyama and Itani2008; Kinoshita et al., Reference Kinoshita, Itani and Uchino2010; Henmi & Itani, Reference Henmi and Itani2014a; Inui et al., Reference Inui, Koyama and Akamatsu2018).

The varunid crab Sestrostoma sp. is an ectosymbiotic crab associated with upogebiid shrimps, clinging on to the host abdomen with legs that can walk. This species is the only known decapod crustacean symbiotic with another decapod and has a parasitic life cycle because it has been confirmed to feed on host tissue (Itani, Reference Itani2001). Sestrostoma sp. can walk freely and grasp the host again after the crab has become detached from the host; hence, there is no decrease in locomotion ability (Itani, Reference Itani2001). The crab genus Sestrostoma includes both burrow symbionts and an ectosymbiont. A congeneric crab (S. toriumii) is a co-habitant in the upogebiid shrimp burrows, where the crab is often expelled from the burrow by the shrimp (Itani, Reference Itani2001; Henmi & Itani, Reference Henmi and Itani2014b). This crab has developed a ‘pass-under’ (ventral evasion) behaviour to escape the hostile response of the host species (Henmi et al., Reference Henmi, Okada and Itani2017). Thus, in the case of the ectosymbiotic Sestrostoma sp., clinging is an adaptive mechanism to avoid host harassment (Itani, Reference Itani2001).

As described, Sestrostoma sp. should behave appropriately to maintain symbiosis with the host during its own ecdysis. We have three hypotheses about the ecdysis of Sestrostoma sp.; (1) Sestrostoma sp. moults with its body clinging to the host abdomen; (2) Sestrostoma sp. detaches from the host and moults in the burrow; or (3) Sestrostoma sp. leaves from the host burrow and moults outside. However, the third hypothesis is improbable because moulting outside will endanger the crab who usually lives inside the burrow. Because of limitations in observation methods, we recorded the moulting behaviour of Sestrostoma sp. in an artificial burrow, precluding the possibility of hypothesis (3).

Host ecdysis is also a potential crisis for the ectosymbionts, who can be cast off with the exuviae (Itani et al., Reference Itani, Kato and Shirayama2002). Some symbiotic species have developed adaptive strategies to survive host ecdysis. Examples include the behavioural adaptation of the bivalve Peregrinamor ohshimai (Itani et al., Reference Itani, Kato and Shirayama2002) or life cycle adaptation by the cycliophora Symbion pandra (Funch & Christensen, Reference Funch and Kristensen1995). In this study, we recorded the behaviour of Sestrostoma sp. during host ecdysis and compared it with behaviour of other ectosymbionts. We will use the term ‘symbiotic’ literally, in the sense of ‘living together’ in this paper, after Ross (Reference Ross, Vernberg and Vernberg1983).

Materials and methods

Specimens were collected from the tidal flats in Uranouchi Inlet, Kochi, Japan (33°26′00.1″N 133°26′21.6″E). Sestrostoma sp. are symbiotic with Upogebia sakaii and U. yokoyai, both dominant burrowing species on the tidal flats. Specimens were collected using a yabbie pump (Poseidon) and sieved through a 1 mm meshed sieve. A shrimp was collected together with its symbiotic crab in one collection (one pumping), and was used as the host for subsequent observation in the aquarium. Generally, the burrow of the upogebiid shrimp has spaces for filter-feeding or changing direction, called a turning chamber (Dworschak, Reference Dworschak1987; Kinoshita et al., Reference Kinoshita, Itani and Uchino2010). In the laboratory, PVC pipes with an inner diameter of 13 mm were used as the burrow model, encased with a larger pipe (20 mm diameter) as a turning chamber(s) following Itani et al. (Reference Itani, Kato and Shirayama2002). To observe the shrimp and crab behaviour, the pipe was cut longitudinally, and fixed on a transparent acrylic plate with an adhesive. Sand was glued inside the pipe so that Sestrostoma sp. could walk freely. The glued pipes were exposed to running water for 24 h before using.

The burrow model was leaned against the glass surface in an aquarium (60 cm width × 30 cm depth × 35 cm height). Seawater was circulated and filtered, and aeration was added. After putting a host shrimp with its Sestrostoma sp., both edges of the burrow model were covered with a small net so that only seawater could enter and exit. Water temperature was kept around 25°C with salinity 25–30 psu. Dried fish food was added every 3 days into the burrow using a syringe for feeding. Before the experiment, carapace length of host shrimp (CL) and carapace width of Sestrostoma sp. (CW) were measured with callipers (Mitutoyo) to the nearest 0.01 mm as an index of body size. Observations were performed from July to October in 2018 and January to February in 2020. We recorded animal behaviour with a video camera (Canon iVIS HF R21) until the shrimp or the crab moulted. Observation lasted 20.7 ± 8.3 days (mean ± SD) (N = 15).

Results

Ecdysis of the symbiont

Sestrostoma sp. usually clung ventrally to the first abdominal segment of the host (Figure 1) for the whole observation period, except in the cases where the host moulted or died. Five ecdyses of Sestrostoma sp. were recorded. In every case, the crab moulted with its legs clinging onto the ventral edges of the first abdominal segment of the host. The sequence of moulting behaviour in the crab was as follows (Figure 2, Supplementary video S1): (1) the thoraco–abdominal membrane was ruptured (passive phase); (2) the exuvia was pushed up diagonally forward and new body extended behind (active phase); (3) after having shed the exoskeleton, the crab still clung to the exuvium, which was still clinging to the ventral abdomen; (4) the crab moved onto the host shrimp abdomen, and clung there, after detaching its exuvium. The time required for moulting was 835–1285 s. Durations of the passive (T p) and the active phase (T a) were 794–1237 s and 40–59 s, respectively (N = 5; Table 1). The active phase was 3.7–6.5% of the total moulting time. After moulting, the exuvia remained attached to the host abdomen for 169–1080 s (T e).

Fig. 1. Sestrostoma sp. clinging to ventral abdomen of Upogebia sakaii.

Fig. 2. Moulting behaviour of Sestrostoma sp. (No. 4 in Table 1). White arrows indicate Sestrostoma sp. (1) The thoraco-abdominal membrane of the crab was ruptured; (2) start of crab moulting (active phase); (3) end of crab moulting; (4) the crab on the exuvium; (5) the crab reattached to the same location on the host after dropping the exuvium.

Table 1. Morphological and behavioural summaries of observed ecdyses of Sestrostoma sp.

CL, carapace length of the host shrimp; CW, carapace width of Sestrostoma sp.; T p, duration of passive phase; T a, duration of active phase; T e, duration of time the exuvium remained attached to the host abdomen after ecdysis.

The symbiont at ecdysis of the host

Six ecdyses of the host shrimps were recorded. In every case, the ecdysis of the host shrimps and crabs did not coincide. The moulting of the shrimps (T m) took 252–392 s (N = 6; Table 2). After moulting, the shrimps wriggled intensely for 445–1394 s (T w). When the host began moulting, Sestrostoma sp. left the host body and stayed nearby (Figure 3, Supplementary Video S2) with one exception where the crab walked from the exuvia to the newly emerged host body, but soon detached upon host wriggling. When the shrimps were quiet and moulting was complete, Sestrostoma sp. returned to the ventral abdominal position on the host (Figure 3, Supplementary Video S2).

Fig. 3. Moulting behaviour of upogebiid shrimp (No. 3 in Table 2). White arrows indicate Sestrostoma sp. (1) At the start of shrimp moulting; (2) Sestrostoma sp. detached from the shrimp body; (3) at the end of shrimp moulting; (4) Sestrostoma sp. reattached to the same location on the host.

Table 2. Morphological and behavioural summaries of observed ecdysis of upogebiid shrimp with Sestrostoma sp.

CL, carapace length of the host shrimp; CW, carapace width of Sestrostoma sp.; T m, duration of shrimp moulting; T w, duration of shrimp wriggling after ecdysis.

Discussion

Sestrostoma sp. moults with its body clinging onto the ventral abdominal segment of the host. During moulting, it is crucial for the symbiotic crab not to be detected by the host, because the host shrimp always cleans the burrow and often expels symbiotic animals (Itani, Reference Itani2001; Henmi & Itani, Reference Henmi and Itani2014b; Henmi et al., Reference Henmi, Okada and Itani2017). The abdomen of the host may be the safest space for the crab, because the host chelipeds and the cleaning legs (fifth legs) do not touch the ventral side of the first abdominal segment (Itani, Reference Itani2001). It is reasonable to suggest that moulting while clinging to the host abdomen is an adaptive behaviour for Sestrosotoma sp., rather than moulting in the burrow after detaching from the host body.

The moulting process of Sestrostoma sp. is almost the same as in other crabs (Phlippen et al., Reference Phlippen, Webster, Chung and Dircksen2000). The time required for moulting (passive and active phase) in adult crabs is known only for Carcinus maenas, Chionoecetes opilio, Macrocheira kaempferi and Paralithodes camtschaticus. In such species, crabs took a longer time to moult than Sestrostoma sp. (14–21 min): 45–90 min in C. maenas, 2–9 h in C. opilio, about 103 min in M. kaempferi and 11–32 min in P. camtschaticus (Watson, Reference Watson1971; Phlippen et al., Reference Phlippen, Webster, Chung and Dircksen2000; Stevens, Reference Stevens, Paul, Dawe, Elner, Jamieson, Kruse, Otto, Sainte–Marie, Shirley and Woodby2002; Okamoto, Reference Okamoto2008). Rapid moulting, especially in the active phase where the crab sheds its old exoskeleton, is suitable for Sestrostoma sp., because the crab would otherwise be dropped off if the host moved suddenly at that time. In the case of C. maenas, it took 45–50 min in the passive phase, following 5–15 min in the active phase. The active phase was 9–25% of the total moult duration (Phlippen et al., Reference Phlippen, Webster, Chung and Dircksen2000). Time required for the active phase of Sestrostoma sp. was 41–59 s (3.7–6.5%), which was much lower than that for C. maenas. However, it is not clear whether the length of the active phase of Sestrostoma sp. is short as a result of adaptive evolution of symbiosis with the shrimp. Comparing ecdysis in many crabs from a variety of phylogenetic origins is needed. What is unclear is the mechanism and function by which the exuvium of Sestrostoma sp. remains attached to the host abdomen after moulting.

Behaviour and strategy of the symbiont in dealing with host ecdyses has been reviewed in Itani et al. (Reference Itani, Kato and Shirayama2002). Among others, two bivalves show different strategies. Pseudopythina macrophthalmensis is a symbiotic galeommatoid bivalve associated with macrophthalmid crabs. Because this bivalve has a high locomotion ability, it is considered that P. macrophthalmensis can crawl from the exuvia and reattach to the host crab after host ecdysis (Kosuge & Itani, Reference Kosuge and Itani1994). Another galeommatoid bivalve, Peregrinamor ohshimai, which attaches to the ventral aspect of the cephalothorax of upogebiid shrimps, crawled onto the new body of the host during host ecdysis, without becoming detached. Artificially detached P. ohshimai are never able to reattach to the host because of the low locomotion ability of the bivalve, whose shell shape is specialized for symbiotic life (Itani et al., Reference Itani, Kato and Shirayama2002). Sestrostoma sp. has a high locomotion ability and can frequently solicit another host (Itani, Reference Itani2001). In ectosymbiotic animals with a high locomotion ability, host ecdysis is not a problem for their continued association. In this study, once detached from the host, the crab simply reattached to the same host individual. Because of the artificial burrow used in this study, it was not possible to determine whether the crab would change shrimp hosts during host ecdysis under natural circumstances.

This study describes the moulting behaviour of Sestrostoma sp. which clings to a ventral abdominal somite of the upogebiid mud shrimp. The crab moults with its legs clinging to the shrimp abdomen, hereby protected from potential hostile behaviour from the host. What is unsolved is the mechanism by which the exuvium remains attached to the abdomen. Many other crabs are ectosymbiotic with other invertebrates, cymothoid isopods attach to fish bodies, and caprellid amphipods are an epibiont associated with algae, all of which lose their host if they are detached during ecdyses. The moulting behaviour of symbiotic and parasitic crustaceans would be an interesting avenue for further research into the symbiotic life cycle of crustaceans.

Supplementary material

The supplementary material for this article can be found at https://doi.org/10.1017/S0025315420000594.

Acknowledgements

We wish to thank the members of the Laboratory of Marine Symbiotic Biology, Kochi University, for assisting with field sampling and observations in the laboratory. We are also grateful to Dr Y. Henmi (Kyoto University), whose feedback substantially improved the manuscript. We acknowledge Editage (http://www.editage.jp) for English language editing.

Financial support

This work was partly supported by JSPS KAKENHI grant number 16K07233 and the Asahi Glass Foundation to GI.

References

Anker, A, Jeng, MS and Chan, TY (2001) Two unusual species of alpheidae (Decapoda: Caridea) associated with upogebiid mudshrimps in the mudflats of Taiwan and Vietnam. Journal of Crustacean Biology 21, 10491061.Google Scholar
Azra, MN, Chen, JC, Hsu, TH, Ikhwanuddin, M and Abol–Munafi, AB (2019) Growth, molting duration and carapace hardness of blue swimming crab, Portunus pelagicus, instars at different water temperatures. Aquaculture Reports 15, 100226.CrossRefGoogle Scholar
Bleakley, B (2018) Cannibalism in crustaceans. In Wellborn, GA and Thiel, M (eds), The Natural History of the Crustacea. Life Histories, Vol. 5. Oxford: Oxford University Press, pp. 347373.Google Scholar
de la Cruz–Huervana, JJY, Quinitio, ET and Corre, VL (2019) Induction of moulting in hatchery-reared mangrove crab Scylla serrata juveniles through temperature manipulation or autotomy. Aquaculture Research 50, 30003008.Google Scholar
Dworschak, PC (1983) The biology of Upogeba pussila (Petagna) (Decapoda, Thalassinidea). I. The burrows. Marine Ecology 4, 1943.Google Scholar
Dworschak, PC (1987) Feeding behaviour of Upogebia pusilla and Callianassa tyrrhena (Crustacea, Decapoda, Thalassinidea). Investigación Pesquera 51(Suppl. 1), 421429.Google Scholar
Dworschak, PC, Felder, DL and Tudge, CC (2012) Infraorders Axiidea de Saint Laurent, 1979 and Gebiidea de Saint Laurent, 1979 (formerly known collectively as Thalassinidea). In Schram, FR and von Vaupel Klein, JC (eds) Treatise on Zoology – Anatomy, Taxonomy, Biology – The Crustacea, Vol. 9 Part B. Leiden: Brill, pp. 3108.Google Scholar
Funch, P and Kristensen, RM (1995) Cycliophora is a new phylum with affinities to Entoprocta and Ectoprocta. Nature 378, 711714.Google Scholar
Griffis, RB and Suchanek, TH (1991) A model of burrow architecture and trophic modes in thalassinidean shrimp (Decapoda: Thalassinidea). Marine Ecology Progress Series 79, 171183.CrossRefGoogle Scholar
Henmi, Y and Itani, G (2014 a) Burrow utilization in the goby Eutaeniichthys gilli associated with the mud shrimp Upogebia yokoyai. Zoological Science 31, 523528.CrossRefGoogle ScholarPubMed
Henmi, Y and Itani, G (2014 b) Laboratory quantification of burrow utilization by the symbiotic varunid crab Sestrostoma toriumii. Plankton and Benthos Research 9, 203206.CrossRefGoogle Scholar
Henmi, Y, Okada, Y and Itani, G (2017) Field and laboratory quantification of alternative use of host burrows by the varunid crab Sestrostoma toriumii (Takeda, 1974) (Brachyura: Varunidae). Journal of Crustacean Biology 35, 18.Google Scholar
Inui, R, Koyama, A and Akamatsu, Y (2018) Abiotic and biotic factors influence the habitat use of four species of Gymnogobius (Gobiidae) in riverine estuaries in the Seto Inland Sea. Ichthyological Research 65, 111.Google Scholar
Itani, G (2001) Two types of symbioses between grapsid crabs and a host thalassinidean shrimp. Publications of the Seto Marine Biological Laboratory 39, 129137.CrossRefGoogle Scholar
Itani, G (2004) Host specialization in symbiotic animals associated with thalassinidean shrimps in Japan. In Tamaki, A. (ed.), Proceedings of the Symposium on “Ecology of Large Bioturbators in Tidal Flats and Shallow Sublittoral Sediments –From Individual Behavior to Their Role as Ecosystem Engineers”. Nagasaki: Nagasaki University, pp. 3343.Google Scholar
Itani, G, Kato, M and Shirayama, Y (2002) Behaviour of the shrimp ectosymbionts, Peregrinamor ohshimai (Mollusca: Bivalvia) and Phyllodurus sp. (Crustacea: Isopoda) through host ecdyses. Journal of the Marine Biological Association of the United Kingdom 82, 6978.Google Scholar
Itoh, H and Nishida, S (2007) Life history of the copepod Hemicyclops gomsoensis (Poecilostomatoida, Clausidiidae) associated with decapod burrows in the Tama-River estuary, central Japan. Plankton Benthos Research 2, 134146.CrossRefGoogle Scholar
Kato, M and Itani, G (1995) Commensalism of a bivalve, Peregrinamor ohshimai, with a thalassinidean burrowing shrimp Upogebia major. Journal of the Marine Biological Association of the United Kingdom 75, 941947.Google Scholar
Kinoshita, K (2002) Burrow structure of the mud shrimp Upogebia major (Decapoda: Thalassinidea: Upogebiidae). Journal of Crustacean Biology 22, 474480.Google Scholar
Kinoshita, K, Itani, G and Uchino, T (2010) Burrow morphology and associated animals of the mud shrimp Upogebia yokoyai (Crustacea: Thalassinidea: Upogebiidae). Journal of the Marine Biological Association of the United Kingdom 90, 947952.CrossRefGoogle Scholar
Kosuge, T and Itani, G (1994) A record of the crab associated bivalve, Pseudopythina mocrophthulmensis from Iriomote Island, Okinawa. Japan. Venus 53, 241244.Google Scholar
Laidre, ME (2018) Evolutionary ecology of burrow construction and social life. In Wellborn, GA and Thiel, M (eds), The Natural History of the Crustacea. Life Histories, Vol. 5. Oxford: Oxford University Press, pp. 279301.Google Scholar
MacGinitie, GE (1930) The natural history of the mud shrimp Upogebia pugettensis (Dana). Annals and Magazine of Natural History (series 10) 6, 3644.Google Scholar
MacGinitie, GE (1935) Ecological aspects of a California marine estuary. American Midland Naturalist 6, 629765.CrossRefGoogle Scholar
Miya, Y (1997) Stenalpheops anacanthus, new genus, new species (Crustacea, Decapoda, Alpheidae) from the Seto Inland Sea and the Sea of Ariake, South Japan. Bulletin of Faculty of Liberal Arts, Nagasaki University 38, 145161.Google Scholar
Nara, M, Akiyama, H and Itani, G (2008) Macrosymbiotic association of the myid bivalve Cryptomya with thalassinidean shrimps: examples from modern and Pleistocene tidal flats of Japan. Palaeogeography, Palaeoclimatology, Palaeoecology 261, 100104.CrossRefGoogle Scholar
Nickell, LA and Atkinson, RJA (1995) Functional morphology of burrows and trophic modes of three thalassinidean shrimp species, and a new approach to the classification of thalassinidean burrow morphology. Marine Ecology Progress Series 128, 181197.CrossRefGoogle Scholar
Okamoto, K (2008) Molting behavior of the giant spider crab, Macrocheirα kaempferi in captivity. Bulletin of Shizuoka Prefectural Research Institute of Fishery 43, 6770. (In Japanese with English abstract).Google Scholar
Ortega, I, Ibeiro, CF, Rodrigues, LS, Rodrigues, MA and Dumont, LFC (2019) Habitat use in different life and moulting stages of Callinectes sapidus (Decapoda, Portunidae) in South Brazilian estuarine and marine environments. Journal of the Marine Biological Association of the United Kingdom 100, 7991.CrossRefGoogle Scholar
Phlippen, MK, Webster, SG, Chung, JS and Dircksen, H (2000) Ecdysis of decapod crustaceans is associated with a dramatic release of crustacean cardioactive peptide into the haemolymph. Journal of Experimental Biology 203, 521536.Google ScholarPubMed
Ross, DM (1983) Symbiotic relations. In Vernberg, FJ and Vernberg, WB (eds), The Biology of Crustacea, Vol. 7. New York, NY: Academic Press, pp. 163212.Google Scholar
Ryer, CH, van Montfrans, J and Orth, RJ (1990) Utilization of a seagrass meadow and tidal marsh creek by blue crabs Callinectes sapidus. II. Spatial and temporal patterns of molting. Bullitin of Marine Science 46, 95104.Google Scholar
Ryer, CH, van Montfrans, J and Moody, KE (1997) Cannibalism, refugia and the molting blue crab. Marine Ecology Progress Series 147, 7785.CrossRefGoogle Scholar
Sato, M, Uchida, H, Itani, G and Yamashita, H (2001) Taxonomy and life history of the scale worm Hesperonoe hwanghaiensis (Polychaeta: Polynoidae), newly recorded in Japan, with special reference to commensalism to a burrowing shrimp, Upogebia major. Zoological Science 18, 981991.Google Scholar
Stevens, BG (2002) Molting of red king crab (Paralithodes camtschaticus) observed by time–lapse video in the laboratory. In Paul, AJ, Dawe, EG, Elner, R, Jamieson, GS, Kruse, GH, Otto, RS, Sainte–Marie, B, Shirley, TC and Woodby, D (eds), Crabs in Cold Water Regions: Biology, Management, and Economics. Fairbanks, AK: University of Alaska, pp. 2938.Google Scholar
Waddy, SL, Aiken, DE and de Kleijn, DPV (1995) Control of growth and reproduction. In Factor, JR (ed.), Biology of the Lobster. San Diego, CA: Academic Press, pp. 217226.CrossRefGoogle Scholar
Watanabe, T and Henmi, Y (2009) Morphological development of the commensal peacrab (Arcotheres sp.) in the laboratory reared specimens. Journal of Crustacean Biology 29, 217223.CrossRefGoogle Scholar
Watson, J (1971) Ecdysis of the snow crab, Chionoecetes opilio. Canadian Journal of Zoology 49, 10251027.Google Scholar
Figure 0

Fig. 1. Sestrostoma sp. clinging to ventral abdomen of Upogebia sakaii.

Figure 1

Fig. 2. Moulting behaviour of Sestrostoma sp. (No. 4 in Table 1). White arrows indicate Sestrostoma sp. (1) The thoraco-abdominal membrane of the crab was ruptured; (2) start of crab moulting (active phase); (3) end of crab moulting; (4) the crab on the exuvium; (5) the crab reattached to the same location on the host after dropping the exuvium.

Figure 2

Table 1. Morphological and behavioural summaries of observed ecdyses of Sestrostoma sp.

Figure 3

Fig. 3. Moulting behaviour of upogebiid shrimp (No. 3 in Table 2). White arrows indicate Sestrostoma sp. (1) At the start of shrimp moulting; (2) Sestrostoma sp. detached from the shrimp body; (3) at the end of shrimp moulting; (4) Sestrostoma sp. reattached to the same location on the host.

Figure 4

Table 2. Morphological and behavioural summaries of observed ecdysis of upogebiid shrimp with Sestrostoma sp.

Shiozaki and Itani supplementary material

Shiozaki and Itani supplementary material 1

Download Shiozaki and Itani supplementary material(Video)
Video 9 MB

Shiozaki and Itani supplementary material

Shiozaki and Itani supplementary material 2

Download Shiozaki and Itani supplementary material(Video)
Video 10.2 MB