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Abnormal symmetric chelipeds in an specimen of snapping shrimp Synalpheus fritzmuelleri Coutiere, 1909

Published online by Cambridge University Press:  05 March 2024

Isabela Ribeiro Rocha Moraes Open the ORCID record for Isabela Ribeiro Rocha Moraes [Opens in a new window] ,
Larissa Zacari ,
Rafael de Carvalho Santos ,
Gabriel Fellipe Barros Rodrigues  and
Antonio Leão Castilho
Isabela Ribeiro Rocha Moraes*
Affiliation:
Departamento de Biodiversidade e Bioestatística, Instituto de Biociências, Universidade Estadual Paulista (UNESP), R. Prof. Dr Antônio Celso Wagner Zanin, 250, Distrito de Rubião Junior, 18618-000 Botucatu, SP, Brazil
Larissa Zacari
Affiliation:
Departamento de Biodiversidade e Bioestatística, Instituto de Biociências, Universidade Estadual Paulista (UNESP), R. Prof. Dr Antônio Celso Wagner Zanin, 250, Distrito de Rubião Junior, 18618-000 Botucatu, SP, Brazil
Rafael de Carvalho Santos
Affiliation:
Laboratório de Estudos e Conservação de Sistemas Aquáticos (LECSA). Universidade Federal do Sul da Bahia, Centro de Formação em Ciências Agroflorestais, Ilhéus-BA, Brazil
Gabriel Fellipe Barros Rodrigues
Affiliation:
Departamento de Biodiversidade e Bioestatística, Instituto de Biociências, Universidade Estadual Paulista (UNESP), R. Prof. Dr Antônio Celso Wagner Zanin, 250, Distrito de Rubião Junior, 18618-000 Botucatu, SP, Brazil
Antonio Leão Castilho
Affiliation:
Departamento de Biodiversidade e Bioestatística, Instituto de Biociências, Universidade Estadual Paulista (UNESP), R. Prof. Dr Antônio Celso Wagner Zanin, 250, Distrito de Rubião Junior, 18618-000 Botucatu, SP, Brazil
*
Corresponding author: Isabela Ribeiro Rocha Moraes; Email: isabela.moraes@unesp.br
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Abstract

Morphological symmetry abnormalities in cheliped appendages of alpheid shrimps are extremely rare and poorly recorded in the literature. A symmetric minor cheliped were, for example, observed in queen females belonging to Synalpheus eusocial species. Symmetric major chelipeds were now described in Synalpheus fritzmuelleri individuals living in shallow Brazilian waters. These individuals were found in symbiotic association with the bryozoan Schizoporella sp. (biogenic substrate) adhering to the pilings of Ubatuba Bay docks, São Paulo State. Only one of 20 sampled S. fritzmuelleri individuals presented anomalous symmetric chelipeds. Based on carapace length, size, and morphological features, the analyzed specimens seemed to be juvenile; thus, the hypothesis of anomalous condition can be directly linked to genetic inhibition of the mechanism accounting for major cheliped development in this ontogeny phase. Studies like the present one often provide remarkable information on animal morphology and can be used as reference in evolutionary assessments to be conducted in the future.

Keywords

Alpheidaemajor chelipedmorphologysnapping clawsymmetry
Type
Research Article
Information
Journal of the Marine Biological Association of the United Kingdom , Volume 104 , 2024 , e21
Copyright
Copyright © The Author(s), 2024. Published by Cambridge University Press on behalf of Marine Biological Association of the United Kingdom

Introduction

Family Alpheidae Rafinesque, 1815 is one of the richest taxonomic groups among caridean shrimp accounting for more than 700 species, which are distributed in approximately 50 genera and exhibit high morphological diversity (Bauer, Reference Bauer2023); these species also stand out for their geographic and ecological distribution, worldwide (Anker et al., Reference Anker, Ahyong, Noël and Palmer2006; Anker, Reference Anker2020, Reference Anker2022; Chow et al., Reference Chow, De Grave, Anker, Poon, Ma, Chu, Chan and Tsang2021). Alpheus Fabricius, 1978 and Synalpheus Spence Bate, 1888 are the most species-rich genera based on specific morphological and behavioral features (Bauer, Reference Bauer2023).

The most distinctive morphological feature in both Alpheus and Synalpheus is heterochely in the first pair of chelipeds: one cheliped is modified into an enlarged ‘snapping claw’ where as the other one has the typical morphology of a cutting or gripping appendage (Bauer, Reference Bauer2023). The typical snapping claw movement turned into one of the most representative sounds of biological noises in shallow marine waters. The snapping-claw mechanics is explained by a remarkably fast movement of the dactylus, which introduces a plunger structure into the propodus'cavity (Versluis et al., Reference Versluis, Schmitz, Heydt and Lohse2000; Patek and Longo, Reference Patek and Longo2018). This interaction produces a straightforward water jet stream that produces the characteristic ‘pistol’ sound which, in its turn, remains one of the popular names attributed to these species (Au and Banks, Reference Au and Banks1998; Schmitz, Reference Schmitz and Wiese2001; Kim et al., Reference Kim, Hahn, Choi and Kim2010).

Studies in the literature address the use of the ‘pistol’ or ‘snapping’ strategy, for different purposes, by the investigated species throughout their life (Knowlton and Moulton, Reference Knowlton and Moulton1963; Knowlton and Keller, Reference Knowlton and Keller1982; Hughes, Reference Hughes1996; Lee et al., Reference Lee, Choi, Shin and Song2021). However, it is mostly defined as signals emitted in conspecific communication and interspecific interactions, such as in agonistic behaviours, since they can stun their pray with the snapping sound, and many of them behave aggressively in the process to protect their cryptic crevices (Bohnenstiehl et al., Reference Bohnenstiehl, Lillis and Eggleston2016).

In members of the genus Synalpheus the snapping behaviour gains a unique significance because some species exhibit eusocial colony organization within sponges (Duffy et al., Reference Duffy, Morrison and Ríos2000). Communication and colony defence are significant examples of snapping behaviour in these populations (Duffy et al., Reference Duffy, Morrison and Macdonald2002). Synalpheus can be divided into two informal groups, namely: gambarelloides (mandatory symbionts of sponges) and non-gambarelloides (free-living or facultative symbionts found in biogenic substrates, without eusocial condition, as the S. fritzmuelleri) (Ríos and Duffy, Reference Ríos and Duffy2007; Anker and De Grave, Reference Anker and De Grave2008). All records available in the literature about cheliped morphology and Synalpheus snapping behaviour are associated with specimens belonging to the eusocial gambarelloides group (Duffy, Reference Duffy1996; Duffy et al., Reference Duffy, Morrison and Macdonald2002; Tóth and Duffy, Reference Tóth and Duffy2008).

Heterochely variation in eusocial populations of Synalpheus species has been described in the literature (Duffy and Macdonald, Reference Duffy and Macdonald1999). This variation is mainly observed in the colony's reproductive ‘queens’, who spend more energy in reproductive activities and often present both minor chelipeds, whereas the colony's ‘helper’ shrimps present the major snapping cheliped developed for both host and colony defense purposes (Chace, Reference Chace1972; Duffy and Macdonald, Reference Duffy and Macdonald1999). On the other hand, according to studies available in the literature, lack of heterochely in non-eusocial species appears to be quite rare (Pearse and Govind, Reference Pearse and Govind1987; Anker et al., Reference Anker, Ahyong, Noël and Palmer2006).

There are, at least, three studies about specimens with two major chelipeds available in the literature, mainly in Alpheus species (Darby, Reference Darby1939; McClure, Reference McClure1996; Soledade et al., Reference Soledade, Oliveira and Almeida2017). Moreover, interpretations about the mechanism inducing symmetry in natural conditions remain poorly explored. With respect to Synalpheus, there is only a brief description of one misidentified specimen available in the literature, and it does not provide any discussion about it (Hickman and Zimmerman, Reference Hickman and Zimmerman2000).

The Synalpheus fritzmuelleri Coutière, 1909 is one of the most abundant non-gambarelloides species belonging to genus Synalpheus and it is widely distributed in the Atlantic Ocean (Anker et al., Reference Anker, Tavares and Mendonça2016). It is often found in Brazilian waters and in association with several invertebrates, such as sponges and corals, besides found free-living in consolidated substrates (Almeida et al., Reference Almeida, Terossi, Buranelli, Castilho, Costa, Zara and Mantelatto2018). Despite its ubiquitous nature, little is explored about this species' biology and behaviour, although it is often found as ‘pair-bond’ in different types of living or non-living substrates (Almeida et al., Reference Almeida, Santos, Soledade, Santos and Pérez2015).

The aims of the present study were to register – for the first time – a S. fritzmuelleri specimen presenting symmetric major chelipeds, as well as to address the consequences of this abnormality for the investigated species' natural life and behavior.

Materials and methods

Sampling procedures were conducted between October 2022 and May 2023, at Cais do Porto [docks] region, Itaguá Bay, Ubatuba City, São Paulo State, Brazil (23°27′05″ S; 45°02′48″ W).

Specimens were sampled in symbiosis with bryozoan biogenic substrate Schizoporella sp., which adhered to the pilings of the docks, at maximum depth of 4 m. All sampling procedures were performed through free-diving activities always carried out at day time.

Bryozoan fragments were carefully sampled with the aid of a small diving knife and stored in plastic bags. All biogenic substrates were carefully examined to investigate the incidence of caridean shrimp within their pores. All symbiotic species were identified in a laboratory environment; S. fritzmuelleri specimens were isolated, photographed, and measured to enable morphological comparisons between those presenting normal features and the ones carrying abnormalities.

The following measurements were taken from all specimens in good condition (with all chelipeds intact): Carapace Length (CL); Major Cheliped Length (MaCL), Major Cheliped Width (MaCW); Minor Cheliped Length (MiCL); and Minor Cheliped Width (MiCW).

All measurements were taken with a stereomicroscope (Zeiss Stemi SV6, fitted with Zeiss Stemi 2000-C image capture system) equipped with a camera and with AxioVisio software (version 4.8). Pictures of both major structures and body plan were taken using a stand and semiprofessional Nikon Coolpix P100 camera at 26x optical zoom.

The abnormal specimen was deposited in the Crustacean Collection of the Biology Department (CCDB) of FFCLRP, University of São Paulo, Ribeirão Preto City, Brazil (CCDB/FFCLRP/USP – Authorization n. 071/2012/SECEX/CGEN): CCDB 7556.

Results

In total, 34 caridean shrimps were recorded in association with the biogenic substrate; 20 of them belonged to species S. fritzmuelleri. Thirteen specimens of the target species presented both chelipeds intact for measurement purposes, whereas one presented symmetry of the major claw.

Regular specimens ranged from 1.30 to 6.02 mm CL, whereas major cheliped size ranged from 2.65 to 8.87 mm, in length, and from 0.98 to 4 mm, in width. Minor cheliped ranged from 1.06 to 3.42 mm, in length, and from 0.38 to 1.14 mm, in width (mean values are described in Table 1). Anomalous species' major cheliped was 4.18 mm long and 1.71 mm wide, whereas their minor cheliped was 3.39 mm long and 1.28 mm wide.

Table 1. Morphological approaches by specimens of Synalpheus firtzmuelleri Coutière, 1909 associated with bryozoarian substrates at Ubatuba Bay, SP, Brazil

MaCL, major cheliped length; MaCW, major cheliped width; MiCL, minor cheliped length; MiCW, minor cheliped width.

Regular conditions indicate specimens with heterochely and abnormality condition indicates the specimen with symmetric chelipeds.

All measures are indicated in millimetres (mm).

All morphological features observed for the investigated specimen were classified as normal for regular Synalpheus individuals, except for lack of heterochely. Details about the investigated species' overall morphology, and comparison between regular and symmetric S. frizmuelleri morphology are shown in Figure 1 (panoramic image) and Figure 2 (cheliped details).

Figure 1. Overall view of the entire body of Synalpheus fritzmuelleri Coutière, 1909 specimen with regular conditions and with symmetric chelipeds. (A) dorsal view of the specimen with abnormality in symmetric chelipeds; (B) dorsal view of the specimen with regular asymmetric chelipeds; The white arrow points to differences in minor asymmetric cheliped and anomalous structure (C) Lateral view of the specimen with symmetric chelipeds; (D) Ventral view of the specimen with symmetric chelipeds. Scale bar: 1 cm.

Figure 2. Image detail showing Synalpheus fritzmuelleri specimen, with emphasis on the symmetric cheliped. (A) lateral view; (B) dorsal view. Scale bar: 1 mm.

Discussion

The present study provides for the first time a record of an abnormality in the symmetry of both major chelipeds in S. fritzmuelleri. Abnormalities and uncommon structures' growth, mainly after ecdysis processes in crustaceans, are not rare. They have been reported in several groups, namely: extra claws, in crayfishes (Nakatani et al., Reference Nakatani, Okada and Yamaguchi1997); multiple morphological deformations, in Penaeoidea shrimps (Betancourt-Lozano et al., Reference Betancourt-Lozano, Baird, Sangha and González-Farias2006; Béguer et al., Reference Béguer, Pasquaud, Noël, Girardin and Boët2008), as well as growing deformation in the cheliped of some Brachyura crabs (Ramírez-Rodríguez and Félix-Pico, Reference Ramírez-Rodríguez and Félix-Pico2010). Most study results and reports available in the literature focused on isolated cases, like the one reported in the present study, according with, only one or just a small number of specimens in the investigated populations presented physical anomalies.

It is common to find situations requiring cheliped autotomy or amputation in snapping shrimps, either from in a fight or escape from predators. Whenever autotomy takes place in the major snapping claw, the pincer (or minor claw) undergoes significant transformation into a new major cheliped (Young et al., Reference Young, Pearse and Govind1994; Pereira et al., Reference Pereira, Tracey, Cooney, Korey and Hughes2014). The transformation of the minor cheliped into snapping claw happens exactly one moult cycle after the loss of the original appendix (Read and Govind, Reference Read and Govind1997). Studies available in the literature advocate that this process takes place because the minor cheliped is likely to be the suppressed major structure, and that when the major cheliped is missing, a specific gene is activated to turn the minor claw into a major claw (Stephens and Mellon, Reference Stephens and Mellon1979).

The two-major-chelipeds condition in specimens belonging to family Alpheidae is extremely rare, and this condition seems enables neutral or impossible the reversal control to an asymmetric morphology. Soledade et al. (Reference Soledade, Oliveira and Almeida2017) observed symmetry in Alpheus specimens and suggested at least three hypotheses capable of explaining the observation of this condition in the investigated animals: (1) symmetry was developed at the juvenile stage due to genetic inhibition of the mechanism accounting for developing asymmetric chelipeds; (2) symmetry was generated at the adult stage, after a single case of major cheliped autotomy and the minor cheliped's non-transformation into a snapping claw; and, finally, (3) after the adult specimen was autotomized and lost the major cheliped, it was sampled during the ‘asymmetry reversal process’, that is the process responsible to maintain the heterochely when some of the chelipeds are lost or are being formed.

Based on the CL size of the herein investigated S. fritzmuelleri specimen, one can say that it was likely a juvenile. Its major cheliped was also smaller than the mean size observed for other specimens in the same population, whereas the minor cheliped was considered bigger than that of other individuals due to symmetry, as shown in Figure 1. The first hypothesis suggested by Soledade et al. (Reference Soledade, Oliveira and Almeida2017) appears to be herein corroborated, since the symmetry observed for the investigated Synalpheus specimen can result from the genetic inhibition of snapping claws' development.

It is important registering cases like this, since they present a rare condition in Synalpheus species; moreover, discussions about these anomalies can drive evolutionary assessment to be conducted in the future.

Acknowledgements

We are grateful to all our laboratory colleagues and co-workers, for the help provided during sampling and analysis processes. We would also like to thank ‘Instituto Chico Mendes de Conservação da Biodiversidade’ (ICMBio) and ‘Instituto Brasileiro do Meio Ambiente e dos Recursos Naturais Renováveis’ (IBAMA), for allowing sample collection. The authors thanks the contributions made by the two reviewers that improved the quality and scientific contribution of this manuscript.

Authors' contributions

Isabela Ribeiro Rocha Moraes: Sampling, main text writing, bibliography observation, photograph taking and edition. Larissa Zacari: First abnormality observation, measurements, bibliography observation, formal manuscript revision. Rafael de Carvalho Santos: Main text revision, English grammar correction, bibliography observation. Gabriel Felipe Rodrigues: Sampling, main text revision, English grammar correction, bibliography observation. Antonio Leão Castilho: Samples' coordination, text writing, photograph taking and full text revision. He also secured the funding that made the current study possible.

Financial support

This project was funded by ‘Conselho Nacional de Desenvolvimento Científico e Tecnológico’ (CNPQ Grant PQ 311034/2018-7), ‘Coordenação de Aperfeiçoamento de Nível Superior – CAPES’, Brazil (CAPES PRINT 88881.310767/2018- 01, CAPES PROEX 23038.000802/2018-25).

Competing interest

None.

Ethical standards

Besides working with invertebrates, all ethical standards were applied, with licenses and procedures conducted in the best way possible for this work.

Data availability

The data that support the findings of this study are available from the corresponding author, IRRM, upon reasonable request. The abnormal specimen was deposited in the Crustacean Collection of the Biology Department (CCDB) of FFCLRP, University of São Paulo, available for consultation by number: CCDB 7556

References

Almeida, AO, Santos, PS, Soledade, GO, Santos, JP and Pérez, CD (2015) New invertebrate host records (Porifera and Cnidaria) for some caridean shrimps in estuaries of north-eastern Brazil. Marine Biodiversity Records 8, 16.CrossRefGoogle Scholar
Almeida, AO, Terossi, M, Buranelli, RC, Castilho, AL, Costa, RC, Zara, FJ and Mantelatto, FL (2018) Checklist of decapods (Crustacea) from the coast of São Paulo State (Brazil) supported by integrative molecular and morphological data: II. Infraorder Caridea: family Alpheidae. Zootaxa 4450, 331358.CrossRefGoogle Scholar
Anker, A (2020) A remarkable burrow-dwelling alpheid shrimp, new genus and new species, from tropical eastern Pacific (Malacostraca: Decapoda: Caridea). Zootaxa 4731, 7588.CrossRefGoogle ScholarPubMed
Anker, A (2022) Crosnierocaris athanasoides gen. et sp. nov., a new deep-water alpheid shrimp from the Mozambique channel (Malacostraca: Decapoda: Caridea). Zootaxa 5105, 269280.CrossRefGoogle Scholar
Anker, A, Ahyong, ST, Noël, PY and Palmer, AR (2006) Morphological phylogeny of alpheid shrimps: parallel preadaptation and the origin of a key morphological innovation, the snapping claw. Evolution 60, 25072528.CrossRefGoogle ScholarPubMed
Anker, A and De Grave, S (2008) Zuzalpheus Ríos and Duffy, 2007: a junior synonym of Synalpheus Bate, 1888 (Crustacea, Decapoda, Alpheidae). Journal of Crustacean Biology 28, 735740.CrossRefGoogle Scholar
Anker, A, Tavares, M and Mendonça, JB (2016) Alpheid shrimps (Decapoda: Caridea) of the Trindade & Martin Vaz Archipelago, off Brazil, with new records, description of a new species of Synalpheus and remarks on zoogeographical patterns in the oceanic islands of the tropical southern Atlantic. Zootaxa 4138, 158.CrossRefGoogle ScholarPubMed
Au, WWL and Banks, K (1998) The acoustics of the snapping shrimp Synalpheus parneomeris in Kaneohe Bay. The Journal of the Acoustical Society of America 103, 4147.CrossRefGoogle Scholar
Bauer, RT (2023) Shrimps: Their Diversity, Intriguing Adaptations and Varied Lifestyles. Lafayette, LA, USA: University of Louisiana.CrossRefGoogle Scholar
Béguer, M, Pasquaud, S, Noël, P, Girardin, M and Boët, P (2008) First description of heavy skeletal deformations in Palaemon shrimp populations of European estuaries: the case of the Gironde (France). Hydrobiologia 607, 225229.CrossRefGoogle Scholar
Betancourt-Lozano, M, Baird, DJ, Sangha, RS and González-Farias, F (2006) Induction of morphological deformities and moulting alterations in Litopenaeus vannamei (Boone) juveniles exposed to the triazole-derivative fungicide tilt. Archives of Environmental Contamination and Toxicology 51, 6978.CrossRefGoogle Scholar
Bohnenstiehl, DR, Lillis, A and Eggleston, DB (2016) The curious acoustic behavior of estuarine snapping shrimp: temporal patterns of snapping shrimp sound in sub-tidal oyster reef habitat. PLoS ONE 11, 121.CrossRefGoogle ScholarPubMed
Chace, FA (1972) The shrimps of the Smithsonian-Bredin Caribbean expeditions with a summary of the West Indian shallow-water species (Crustacea: Decapoda: Natantia). Smithsonian Contributions to Zoology 98, 1179.Google Scholar
Chow, LH, De Grave, S, Anker, A, Poon, KKY, Ma, KY, Chu, KH, Chan, TY and Tsang, LM (2021) Distinct suites of pre-and post-adaptations indicate independent evolutionary pathways of snapping claws in the shrimp family Alpheidae (Decapoda: Caridea). Evolution 75, 28982910.CrossRefGoogle ScholarPubMed
Darby, H (1939) Symmetry in normally asymmetrical Crustacea. Papers from the Tortugas Laboratory of the Carnegie Institution of Washington 32, 6164.Google Scholar
Duffy, JE (1996) Eusociality in a coral-reef shrimp. Nature 381, 512514.CrossRefGoogle Scholar
Duffy, JE and Macdonald, KS (1999) Colony structure of the social snapping shrimp Synalpheus filidigitus in Belize. Journal of Crustacean Biology 19, 283292.CrossRefGoogle Scholar
Duffy, JE, Morrison, CL and Macdonald, KS (2002) Colony defense and behavioral differentiation in the eusocial shrimp Synalpheus regalis. Behavioral Ecology and Sociobiology 51, 488495.CrossRefGoogle Scholar
Duffy, JE, Morrison, CL and Ríos, R (2000) Multiple origins of eusociality among sponge-dwelling shrimps (Synalpheus). Evolution 54, 503516.Google ScholarPubMed
Hickman, CPJ and Zimmerman, T (2000) A Field Guide to Crustaceans of Galapagos, Lexing-ton, Ed. Virginia: Sugar Spring Press.Google Scholar
Hughes, M (1996) The function of concurrent signals: visual and chemical communication in snapping shrimp. Animal Behaviour 52, 247257.CrossRefGoogle Scholar
Kim, BN, Hahn, J, Choi, BK and Kim, BC (2010) Snapping shrimp sound measured under laboratory conditions. Japanese Journal of Applied Physics 49, 15.Google Scholar
Knowlton, N and Keller, BD (1982) Symmetric fights as a measure of escalation potential in a symbiotic, territorial snapping shrimp. Behavioral Ecology and Sociobiology 10, 289292.CrossRefGoogle Scholar
Knowlton, RE and Moulton, JM (1963) Sound production in the snapping shrimps Alpheus (Crangon) and Synalpheus. Biological Bulletin 125, 311331.CrossRefGoogle Scholar
Lee, DH, Choi, JW, Shin, S and Song, HC (2021) Temporal variability in acoustic behavior of snapping shrimp in the East China Sea and its correlation with ocean environments. Frontiers in Marine Science 8, 779283. doi: 10.3389/fmars.2021.779283CrossRefGoogle Scholar
McClure, MR (1996) Symmetry in large claws of snapping shrimp in nature (Decapoda, Alpheidae). Crustaceana 69, 920921.CrossRefGoogle Scholar
Nakatani, I, Okada, Y and Yamaguchi, T (1997) An extra claw on the first and n the third cheliped of the crayfish, Procambarus clarkii (Decapoda, cambaridae). Crustaceana 70, 788798.Google Scholar
Patek, SN and Longo, SJ (2018) Evolutionary biomechanics: the pathway to power in snapping shrimp. Current Biology 28, 103126.CrossRefGoogle ScholarPubMed
Pearse, J and Govind, CK (1987) Spontaneous generation of bilateral symmetry in the paired claws and closer muscles of adult snapping shrimps. Development (Cambridge, England) 100, 5763.CrossRefGoogle Scholar
Pereira, A, Tracey, E, Cooney, PC, Korey, CA and Hughes, M (2014) Post-autotomy claw regrowth and functional recovery in the snapping shrimp Alpheus angulosus. Marine and Freshwater Behaviour and Physiology 47, 147159.CrossRefGoogle Scholar
Ramírez-Rodríguez, M and Félix-Pico, E (2010) Abnormalities in chelipeds of the crab cancer johngarthi off the southwest coast of the peninsula of Baja California, Mexico. Crustaceana 83, 15391541.CrossRefGoogle Scholar
Read, AT and Govind, CK (1997) Claw transformation and regeneration in adult snapping shrimp: test of the inhibition hypothesis for maintaining bilateral asymmetry. Biological Bulletin 193, 401409.CrossRefGoogle ScholarPubMed
Ríos, R and Duffy, E (2007) A review of the sponge-dwelling snapping shrimp from Carrie Bow Cay, Belize, with description of Zuzalpheus, new genus, and six new species (Crustacea: Decapoda: Alpheidae). Zootaxa 1602, 189.CrossRefGoogle Scholar
Schmitz, B (2001) Sound production in Crustacea with special reference to the Alpheidae. In Wiese, K (ed.), The Crustacean Nervous System. Hamburg, Germany: Springer, pp. 536547.Google Scholar
Soledade, GO, Oliveira, MV and Almeida, AO (2017) A specimen of the snapping shrimp Alpheus pontederiae de Rochebrune, 1883 with symmetric chelipeds. Spixiana 40, 181184.Google Scholar
Stephens, PJ and Mellon, DF (1979) Morphology and synaptic physiology of the main closer muscle in regenerating claws of Alpheus. Journal of Comparative Physiology A 134, 1727.CrossRefGoogle Scholar
Tóth, E and Duffy, JE (2008) Influence of sociality on allometric growth and morphological differentiation in sponge-dwelling alpheid shrimp. Biological Journal of the Linnean Society 94, 527540.CrossRefGoogle Scholar
Versluis, M, Schmitz, B, Heydt, AVD and Lohse, D (2000) How snapping shrimp snap: through cavitating bubbles. Science (New York, N.Y.) 289, 21142117.CrossRefGoogle ScholarPubMed
Young, RE, Pearse, J and Govind, CK (1994) Establishment and maintenance of claw bilateral asymmetry in snapping shrimps. The Journal of Experimental Zoology 269, 319326.CrossRefGoogle Scholar
Figure 0

Table 1. Morphological approaches by specimens of Synalpheus firtzmuelleri Coutière, 1909 associated with bryozoarian substrates at Ubatuba Bay, SP, Brazil

Figure 1

Figure 1. Overall view of the entire body of Synalpheus fritzmuelleri Coutière, 1909 specimen with regular conditions and with symmetric chelipeds. (A) dorsal view of the specimen with abnormality in symmetric chelipeds; (B) dorsal view of the specimen with regular asymmetric chelipeds; The white arrow points to differences in minor asymmetric cheliped and anomalous structure (C) Lateral view of the specimen with symmetric chelipeds; (D) Ventral view of the specimen with symmetric chelipeds. Scale bar: 1 cm.

Figure 2

Figure 2. Image detail showing Synalpheus fritzmuelleri specimen, with emphasis on the symmetric cheliped. (A) lateral view; (B) dorsal view. Scale bar: 1 mm.