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Southernmost occurrence of Gobiosoma hemigymnum (Eigenmann & Eigenmann, 1888) on salt marshes of the Bahia Blanca estuary, Argentina: an unusual finding

Published online by Cambridge University Press:  20 April 2023

Lucas M. Molina*
Affiliation:
Universidad Nacional de Río Negro, Área de Metodología de la Investigación, Viedma, Argentina CIT Rio Negro (UNRN-CONICET), Viedma, Argentina
M. Cecilia González Dubox
Affiliation:
CIT Rio Negro (UNRN-CONICET), Viedma, Argentina
Andrea Lopez Cazorla
Affiliation:
Instituto Argentino de Oceanografía (IADO-CONICET), Bahia Blanca, Argentina
*
Corresponding author: Lucas M. Molina; E-mail: [email protected]
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Abstract

Salt marshes do not present favourable conditions for cryptic fish species to inhabit these areas, mainly due to dryness and high temperatures at low tides, and scarce places to hide. Despite the harsh environmental conditions, we report, for the first time, the occurrence of two specimens of the half-naked goby Gobiosoma hemigymnum at high marsh, between oysters and Spartina alteniflora stems. In this paper we report evidence of a possible positive effect of autogenic ecosystem engineer and invasive species, the Pacific oyster (Magallana gigas), over the gobid, Gobiosoma hemigymnum, found 600 km away from its southernmost normal range.

Type
Marine Record
Copyright
Copyright © The Author(s), 2023. Published by Cambridge University Press on behalf of Marine Biological Association of the United Kingdom

Introduction

The distribution of species is highly influenced by both abiotic (ocean warming, Burrows et al., Reference Burrows, Schoeman, Buckley, Moore, Poloczanska, Brander and Richardson2011; Chen et al., Reference Chen, Hill, Ohlemuller, Roy and Thomas2011; Poloczanska et al., Reference Poloczanska, Brown, Sydeman, Kiessling, Schoeman, Moore and Richardson2013; Büscher et al., Reference Büscher, Form and Riebesell2017) and biotic factors (i.e. facilitation as a positive interaction among organisms, Michalet & Pugnaire, Reference Michalet and Pugnaire2016).

Marshes are environments exposed to terrestrial and aquatic conditions (both marine and freshwater) that present marked gradients of physical stress (e.g. anoxia, salinity) that have important effects on the structuring and, in particular, on the community's zonation patterns (Traut, Reference Traut2005; Lortie & Callaway, Reference Lortie and Callaway2006). Additionally, these environments suffer the effects of globalization, such as maritime transport and aquaculture, favouring the transport of marine species outside their native geographic ranges (Carlton & Geller, Reference Carlton and Geller1993; Cohen & Carlton, Reference Cohen and Carlton1998; Mack et al., Reference Mack, Simberloff, Mark Lonsdale, Evans, Clout and Bazzaz2000).

Gobiids are mostly from tropical and subtropical areas, being predominantly found in marine and brackish environments, but some species are catadromous; they prefer shallow coastal waters and live around coral reefs in all the world's seas (Acha, Reference Acha1994). Most are cryptic bottom-dwelling carnivores of small benthic invertebrates; others are planktivores (Nelson, Reference Nelson2006). Some species have symbiotic relationships with invertebrates (e.g. shrimps) and others are known to remove ecto-parasites from other fishes (Vázquez & Bas, Reference Vázquez and Bas2019). Gobiidae, one of the largest family of marine fishes, according to Nelson et al. (Reference Nelson, Grande and Wilson2016) is among the most species-rich of marine fish families, and is often the most abundant fish family in freshwater habitats on oceanic islands. The family shows some particular morphology, i.e. pelvic fins are usually fused into an adhesive disc, and most species are below 10 cm in total length (Figueroa, Reference Figueroa2019). They are common inhabitants on the coast of Uruguay and Buenos Aires, but are difficult to observe due to their cryptic habits, with the southernmost distribution limit of Gobiosoma hemigymnum being Mar del Plata (38°00′S 57°33′W), Argentina (Van Tassell et al., Reference Van Tassell, Joyeux, Macieira and Tornabene2015; Figueroa, Reference Figueroa2019). Another gobiid species (Ophiogobius jenynsi) has been reported from Argentina, and it was found at the Beagle Channel, Ushuaia (Menni et al., Reference Menni, Ringuelet and Aramburu1984).

Usually, salt marshes do not present favourable conditions for cryptic species such as gobiid fishes to inhabit these areas, mainly due to dryness and high temperatures at low tides (Piccolo & Perillo, Reference Piccolo and Perillo1990), and scarce places to hide. However, the presence of an invasive species of Pacific oyster, Magallana gigas could have a positive effect over fish species. Invasive species could usually be considered as ecosystem engineers (Fei et al., Reference Fei, Phillips and Shouse2014). Howard et al. (Reference Howard, Francis, Côté and Therriault2019) described: ‘Ecosystem engineering may be autogenic, where the invasive species itself creates habitat, or allogenic, where the habitat is transformed by the invasive organism through its activities’. Magallana gigas was first reported by Dos Santos & Fiori (Reference Dos Santos and Fiori2010) when they found a few oysters on port docks at the Bahía Blanca estuary. Twelve years later the Bahía Blanca population of M. gigas is very abundant with apparently large impacts on ecosystem structure and functionality (Molina, pers. obs.).

The aim of this paper is to report the occurrence of Gobiosoma hemigymnum more southerly than the so far (Van Tassell et al., Reference Van Tassell, Joyeux, Macieira and Tornabene2015; Figueroa, Reference Figueroa2019) documented distribution range of the species, associated to an uncommon habitat, salt marshes. We propose the hypothesis that the finding of Gobiosoma hemigymnum might be a consequence of a positive effect of autogenic ecosystem engineer and invasive species Magallana gigas.

Materials and methods

Study area

The Bahía Blanca Estuary is a wide coastal wetland complex in temperate South America, comprising a total surface of 2300 km2 which includes about 410 km2 of marshes and more than 1150 km2 of mudflats (Perillo et al., Reference Perillo, Piccolo, Parodi and Freije2001; Isacch et al., Reference Isacch, Costa, Rodríguez-Gallego, Conde, Escapa, Gagliardini and Iribarne2006). Mean tidal range varies from 2 m at the mouth to 3.8 m at the middle and upper reaches, and salinity typically increases from the mouth to the head, where the restricted circulation and the high evaporation may produce concentrations higher than 38 (Piccolo & Perillo, Reference Piccolo and Perillo1990). Located in the northern limit of the Patagonian desert, vegetation in the intertidal zone is scarce and, unlike the better known counterparts of Eastern North America, Spartina alterniflora marshes only occur in discontinuous patches at the mouth of the estuary. Under the seasonally hypersaline conditions in the inner estuary, vegetation is virtually absent in the intertidal zone except for the circular mounds of Sarcocornia perennis, colonizing the upper marshes (Perillo & Iribarne, Reference Perillo and Iribarne2003).

Within the study area, major transformations relate to the presence of the largest deep-water harbour system in Argentina, that comprises Ingeniero White Port and a series of subsidiary harbours related to a petrochemical industrial park, and a naval base (Perillo & Sequeira, Reference Perillo and Sequeira1989). The specific site where Gobiosoma hemigymnum was found corresponds to a S. alterniflora marsh of about 30 ha located 15 km south-east of Ingeniero White Port, and just 4 km north-west of the Puerto Belgrano Naval Base (Figure 1). Substrate is composed of a mixture of sand and mud, with extensive bare flats occupying most of the intertidal fringe, and high densities of Magallana gigas could be found covering the sediment surface, forming reefs (Molina, pers. obs.). Vegetation is restricted to the upper intertidal zone, with plant densities varying from 100 to more than 300 ramets m2, according to a strong seasonal pattern, and as happens also with tidal flats, lots of oyster are growing between plants, with a high bio-geomorphological impact (Molina, pers. obs.).

Figure 1. The map shows the geographic distribution range of Gobiosoma hemigymnum (blue line), with the location of the southern limit of distribution before this study (yellow dot), and the new southernmost documented record (light green dot). The Bahía Blanca estuary is shown in detail, with the main harbours, as well as the area covered by Spartina alterniflora marshes and mudflats.

Field sampling and data analysis

Sampling was made from 29 October to 5 November 2022, during low tide at afternoon. Two specimens of an unidentified fish were found in caves formed between oysters and Spartina stems (Figure 2A), which retained water, picking them up by hand, in isolated events. The specimens were kept in sampling bags with seawater for at least 2 h in order to allow fishes to be in a relaxed condition before being fixed in 10% formalin. Water temperature and salinity were also measured.

Figure 2. Plate showing record site and morphological characteristic of Gobiosoma hemigymnum. (A) Detail of the place where one of the specimens was collected, showing individuals of Magallana gigas and stems of Spartina alterniflora; (B) drawing showing standard length is ~5 times body height (from Figueroa, Reference Figueroa2019). (C) fixed specimen; (D) showing first dorsal fin with VI spines and second dorsal fin with XII rays; (E) detail of the mature female gonads occupying almost the entire fish cavity; (F) pelvic fins fused into an adhesive disc; (G) scaled specimen.

The specimens were photographed in the lab, with a Canon 7D Dsrl camera, with a 32 mm objective, considering several taxonomic features (following Van Tassell et al., Reference Van Tassell, Joyeux, Macieira and Tornabene2015 and Figueroa, Reference Figueroa2019). The morphological characteristics were described and specimens measured to the nearest 0.05 mm with a digital calliper. Meristic data were taken, gonads and livers were extracted and weighed on a SF-400C Venezia digital scale (± 0.01 mg), and the stomachs as well. Subsequently, the gonadosomatic IGS and hepatosomatic IHS indices were calculated according to Ferré et al. (Reference Ferré, Medesani, García, Grodzielski and Rodríguez2012): IGS (%) = (PG/PSP) × 100 and IHS = (PH/PSP) × 100, where PG is the wet weight of the gonad, PH the wet weight of the liver and PSP the wet weight of the specimen. Gonads were macroscopically staged according to the gonad development classification for gobies based on a five-point scale of maturity (Miller, Reference Miller1961). The specimens were stored in the fish collection of the Universidad Nacional de Río Negro under the catalogue number 44.

Results and discussion

Measurements and counts are given in Table 1. Standard length is ~5 times the body height (Figure 2B, C), dorsal fin with 6–8 spines and 11–12 rays (Figure 2C, D). These features, following Van Tassell et al. (Reference Van Tassell, Joyeux, Macieira and Tornabene2015) and Figueroa (Reference Figueroa2019), allowed to identify the two specimens as Gobiosoma hemigymnum. Anatomical dissection determined that the specimens were two females. The gonads occupied most of the whole abdominal cavity in one of the observed specimens, while in the other individual the gonads were smaller in size (Figure 2E). The two female specimens were sexually mature, according to the gonad development classification for gobiids based on a five-stage scale of maturity (Miller, Reference Miller1961). The high values of IGS and the low values of IHS indices for each specimen indicated that the two females were in breeding season (following Fouda et al., Reference Fouda, Hanna and Fouda1993).

Table 1. Meristic and environmental data, and the results of morphological indices

Within its normal distribution range this family is a numerically dominant component of larval, juvenile and adult fish assemblages in tropical and subtropical estuaries (Barletta-Bergan et al., Reference Barletta-Bergan, Barletta and Saint-Paul2002; Sanvicente-Añorve et al., Reference Sanvicente-Añorve, Salgado-Ugarte, Castillo-Rivera, Browman and Skiftesvik2003; Joyeux et al., Reference Joyeux, Campanha Filho and Jesus2004; Bonecker et al., Reference Bonecker, Nagae, Bletller, Velho and Lansac-To^ha2007; Coser et al., Reference Coser, Pereira and Joyeux2007; Shervette et al., Reference Shervette, Aguirre, Blacio, Cevallos, Gonzalez, Pozo and Gelwick2007; Ooi & Chong, Reference Ooi and Chong2011). The salt marshes fish assemblages of Bahía Blanca estuary were extensively studied by Lopez Cazorla (Reference Lopez Cazorla1987), Valiñas (Reference Valiñas2010), Valiñas et al. (Reference Valiñas, Molina, Addino, Montemayor, Acha and Iribarne2012) and Molina et al. (Reference Molina, Valiñas, Pratolongo, Elias and Perillo2017), as were the macrobenthic communities of vegetated and non-vegetated sediments (Molina et al., Reference Molina, Valiñas, Pratolongo, Elias and Perillo2009, Reference Molina, Valiñas, Pratolongo, Elias and Perillo2017; Molina, Reference Molina2013). The occurrence of G. hemigymnum has not been recorded in Bahía Blanca estuary before and all these observations and studies were made before the oyster M. gigas became an invader, with the consequential physical and biological alteration of the shore (Molina, pers. obs). Gobiosoma hemigymnum has been documented to occur, based on recent collections, in the south-western Atlantic from Rio de Janeiro, Brazil (23 S), to Mar del Plata, Argentina (38 S) (Van Tassell et al., Reference Van Tassell, Joyeux, Macieira and Tornabene2015; Figueroa, Reference Figueroa2019). The half-naked goby is associated to the Ficopomatus enigmaticus reefs, an invasive species and ecosystem engineer (Schwindt et al., Reference Schwindt, De Francesco and Iribarne2004), in Mar Chiquita lagoon (Cervigon & Bastida, Reference Cervigon and Bastida1971) and inhabits the encrusting community in both the harbour and the mesolittoral zone of Cabo Corrientes, near Mar del Plata (Vázquez & Bas, Reference Vázquez and Bas2019), both sites in the Buenos Aires province, Argentina. Accordingly, we hypothesize that the modifications introduced by Magallana gigas, in term of spatial complexity, created new habitats, suitable to G. hemigymnum.

There are several reasons to think that G. hemigymnum has become a frequent inhabitant of this environment, in relation to the presence of M. gigas. A general pattern of increased diversity and/or abundance with increased habitat complexity (Hosack et al., Reference Hosack, Dumbauld, Ruesink and Armstrong2006), with some exceptions were found (Castel et al., Reference Castel, Labourg, Escaravage, Auby and Garcia1989). Some authors support the idea that fishes are more abundant in vegetated adjacent habitats to oyster reefs (Holsman et al., Reference Holsman, McDonald and Armstrong2006; Kelly & Volpe, Reference Kelly and Volpe2007; Kelly et al., Reference Kelly, Proctor and Volpe2008) despite benthic organisms’ diversity being higher in M. gigas reefs (Hosack et al., Reference Hosack, Dumbauld, Ruesink and Armstrong2006), generating contradictory evidence. Leonard & Croft (Reference Leonard and Croft2006) propose that the presence of S. alterniflora reduces wave-related disturbance, and it could explain the occurrence of G. hemigymnum between S. alterniflora stems.

Conclusions

The introduction of Magallana gigas, that competes with existing forms of habitat structure, such as Spartina, may affect the availability of important habitat refugia and foraging resources for estuarine fishes (Hosack et al., Reference Hosack, Dumbauld, Ruesink and Armstrong2006) increasing complexity (Castel et al., Reference Castel, Labourg, Escaravage, Auby and Garcia1989), and in this case of a positive way, generating a new habitat type for the gobid G. hemigymnum, with potential prey items and refuge (Grabowski et al., Reference Grabowski, Hughes, Kimbro and Dolan2005). Further studies are needed to understand the impacts and modifications that communities and their habitats are undergoing, thus being able to predict new dynamics and improve management tools, especially taking into account that many species that inhabit these habitats can be negatively affected.

Acknowledgements

We thank the authorities of the Puerto Belgrano Club for allowing us to use the facilities for surveys.

Author contributions

LMM collected the specimens. The specimens were photographed by LMM and dissected by MCGD. ALC made the taxonomic identification. LMM wrote the manuscript with support from MCGD and ALC. All authors discussed the results and contributed to the final manuscript.

Financial support

LMM is supported by UNRN and CONICET, but this research was carried out with LMM personal financing.

Conflict of interest

The authors declare no conflict of interest.

References

Acha, EM (1994) Development and occurrence of larvae of the goby, Gobiosoma parri (Ginsburg) (Gobiidae), in the estuary of the Río de la Plata, Argentina. Scientia Marina 58, 337343.Google Scholar
Barletta-Bergan, A, Barletta, M and Saint-Paul, U (2002) Structure and seasonal dynamics of larval fish in the Caeté River Estuary in North Brazil. Estuarine. Coastal and Shelf Science 54, 193206.CrossRefGoogle Scholar
Bonecker, CC, Nagae, MY, Bletller, MCM, Velho, LFM and Lansac-To^ha, FA (2007) Zooplankton biomass in tropical reservoirs in southern Brazil. Hydrobiologia 579, 115123.Google Scholar
Burrows, MT, Schoeman, DS, Buckley, LB, Moore, P, Poloczanska, ES, Brander, KM and Richardson, AJ (2011) The pace of shifting climate in marine and terrestrial ecosystems. Science (New York, N.Y.) 334, 652655.Google ScholarPubMed
Büscher, JV, Form, AU and Riebesell, U (2017) Interactive effects of ocean acidification and warming on growth, fitness and survival of the cold-water coral Lophelia pertusa under different food availabilities. Frontiers in Marine Science 4, 101.Google Scholar
Carlton, JT and Geller, JB (1993) Ecological roulette: the global transport of nonindigenous marine organisms. Science (New York, N.Y.) 261, 7882.Google Scholar
Castel, J, Labourg, PJ, Escaravage, V, Auby, I and Garcia, ME (1989) Influence of seagrass beds and oyster parks on the abundance and biomass patterns of meio-and macrobenthos in tidal flats. Estuarine, Coastal and Shelf Science 28, 7185.Google Scholar
Cervigon, F and Bastida, RO (1971) Contribución al conocimiento de la fauna ictiológica de la provincia de Buenos Aires (Argentina). Anales de la Sociedad Científica Argentina 197, 20.Google Scholar
Chen, IC, Hill, JK, Ohlemuller, R, Roy, DB and Thomas, CD (2011) Rapid range shifts of species associated with high levels of climate warming. Science (New York, N.Y.) 333, 10241026.CrossRefGoogle ScholarPubMed
Cohen, AN and Carlton, JT (1998) Accelerating invasion rate in a highly invaded estuary. Science (New York, N.Y.) 279, 555558.Google Scholar
Coser, LM, Pereira, BB and Joyeux, JC (2007) Descrição da comunidade ictioplanctônica e sua distribuição espacial no estuário dos rios Piraquê-Açu e Piraquê-Mirim, Aracruz, ES, Brasil. Interciencia 32, 233241.Google Scholar
Dos Santos, EP and Fiori, SM (2010) Primer registro sobre la presencia de Crassostrea gigas (Thunberg, 1793) (Bivalvia: Ostreidae) en el estuario de Bahía Blanca (Argentina). Comunicaciones de la Sociedad Malacologica del Uruguay 9, 245252.Google Scholar
Fei, S, Phillips, J and Shouse, M (2014) Biogeomorphic impacts of invasive species. Annual Review of Ecology, Evolution, and Systematics 45, 6987.Google Scholar
Ferré, LE, Medesani, DA, García, CF, Grodzielski, M and Rodríguez, EM (2012) Vitellogenin levels in hemolymph, ovary and hepatopancreas of the freshwater crayfish Cherax quadricarinatus (Decapoda: Parastacidae) during the reproductive cycle. Revista de Biología Tropical 60, 253261.Google ScholarPubMed
Figueroa, DE (2019) Clave de peces marinos del Atlántico Sudoccidental, entre los 33 S y 56 S. Publicación del INIDEP. Mar del Plata.Google Scholar
Fouda, MM, Hanna, MY and Fouda, FM (1993) Reproductive biology of a Red Sea goby, Silhouettea aegyptia, and a Mediterranean goby, Pomatoschistus marmoratus, in Lake Timsah, Suez Canal. Journal of Fish Biology 43, 139151.Google Scholar
Grabowski, JH, Hughes, AR, Kimbro, DL and Dolan, MA (2005) How habitat setting influences restored oyster reef communities. Ecology 86, 19261935.Google Scholar
Holsman, KK, McDonald, PS and Armstrong, DA (2006) Intertidal migration and habitat use by subadult Dungeness crab Cancer magister in a NE Pacific estuary. Marine Ecology Progress Series 308, 183195.Google Scholar
Hosack, GR, Dumbauld, BR, Ruesink, JL and Armstrong, DA (2006) Habitat associations of estuarine species: comparisons of intertidal mudflat, seagrass (Zostera marina), and oyster (Crassostrea gigas) habitats. Estuaries and Coasts 29, 11501160.CrossRefGoogle Scholar
Howard, BR, Francis, FT, Côté, IM and Therriault, TW (2019) Habitat alteration by invasive European green crab (Carcinus maenas) causes eelgrass loss in British Columbia, Canada. Biological Invasions 21, 36073618.CrossRefGoogle Scholar
Isacch, JP, Costa, CSB, Rodríguez-Gallego, L, Conde, D, Escapa, M, Gagliardini, DA and Iribarne, OO (2006) Distribution of saltmarsh plant communities associated with environmental factors along a latitudinal gradient on the south-west Atlantic coast. Journal of Biogeography 33, 888900.CrossRefGoogle Scholar
Joyeux, JC, Campanha Filho, EA and Jesus, HCD (2004) Trace metal contamination in estuarine fishes from Vitória Bay, ES, Brazil. Brazilian Archives of Biology and Technology 47, 765774.Google Scholar
Kelly, JR, Proctor, E and Volpe, JP (2008) Intertidal community structure differs significantly between substrates dominated by native eelgrass (Zostera marina L.) and adjacent to the introduced oyster Crassostrea gigas. Hydrobiologia 596, 5766.CrossRefGoogle Scholar
Kelly, JR and Volpe, JP (2007) Native eelgrass (Zostera marina L.) survival and growth adjacent to non-native oysters (Crassostrea gigas Thunberg) in the Strait of Georgia, British Columbia. Botanica Marina 50, 143150.Google Scholar
Leonard, LA and Croft, AL (2006) The effect of standing biomass on flow velocity and turbulence in Spartina alterniflora canopies. Estuarine, Coastal and Shelf Science 69, 325336.Google Scholar
Lopez Cazorla, AC (1987) Contribución al conocimiento de la ictofauna marina del área de Bahía Blanca (Doctoral dissertation). Universidad Nacional de La Plata.Google Scholar
Lortie, CJ and Callaway, RM (2006) Re-analysis of meta-analysis: support for the stress-gradient hypothesis. Journal of Ecology 94, 716.Google Scholar
Mack, RN, Simberloff, D, Mark Lonsdale, W, Evans, H, Clout, M and Bazzaz, FA (2000) Biotic invasions: causes, epidemiology, global consequences, and control. Ecological Applications 10, 689710.CrossRefGoogle Scholar
Menni, RC, Ringuelet, RA and Aramburu, RH (1984) Peces marinos de la Argentina y Uruguay. Catálogo crítico ilustrado. Claves para la determinación de familias, géneros y especies. Nombres vulgares. Glosario. Glosario. Ed. Hemisferio Sur SA, Buenos Aires, Argentina.Google Scholar
Michalet, R and Pugnaire, FI (2016) Facilitation in communities. Functional Ecology 30, 39.CrossRefGoogle Scholar
Miller, PJ (1961) Age, growth, and reproduction of the rock goby, Gobius paganellus L., in the Isle of Man. Journal of the Marine Biological Association of the United Kingdom 41, 737769.Google Scholar
Molina, LM (2013) El rol de la biota en los procesos de estabilización-desestabilización de sedimentos estuariales. PhD thesis. Universidad nacional del sur. Argentina, 289 pp.Google Scholar
Molina, LM, Valiñas, MS, Pratolongo, PD, Elias, R and Perillo, GME (2009) First record of the sea anemone Diadumene lineata (Verrill 1871) associated to Spartina alterniflora roots and stems, in marshes at the Bahia Blanca estuary, Argentina. Biological Invasions 11, 409416.Google Scholar
Molina, LM, Valiñas, MS, Pratolongo, PD, Elias, R and Perillo, GM (2017) Effect of “Whitemouth Croaker” (Micropogonias furnieri, Pisces) on the stability of the sediment of salt marshes – an issue to be resolved. Estuaries and Coasts 40, 17951807.CrossRefGoogle Scholar
Nelson, JR (2006) Fishes of the World. New York, NY: Wiley.Google Scholar
Nelson, JS, Grande, TC and Wilson, MVH (2016) Fishes of the World. 5th Edition. Hoboken, NJ: Wiley.Google Scholar
Ooi, AL and Chong, VC (2011) Larval fish assemblages in a tropical mangrove estuary and adjacent coastal waters: offshore–inshore flux of marine and estuarine species. Continental Shelf Research 31, 15991610.Google Scholar
Perillo, GM and Iribarne, OO (2003) New mechanisms studied for creek formation in tidal flats: from crabs to tidal channels. Eos, Transactions American Geophysical Union 84, 15.Google Scholar
Perillo, GME, Piccolo, MC, Parodi, E and Freije, RH (2001) The Bahía Blanca estuary, Argentina. In Coastal Marine Ecosystems of Latin America. Berlin: Springer, pp. 205217.CrossRefGoogle Scholar
Perillo, GM and Sequeira, ME (1989) Geomorphologic and sediment transport characteristics of the middle reach of the Bahía Blanca estuary (Argentina). Journal of Geophysical Research: Oceans 94, 1435114362.CrossRefGoogle Scholar
Piccolo, MC and Perillo, GM (1990) Physical characteristics of the Bahía Blanca estuary (Argentina). Estuarine, Coastal and Shelf Science 31, 303317.CrossRefGoogle Scholar
Poloczanska, ES, Brown, CJ, Sydeman, WJ, Kiessling, W, Schoeman, DS, Moore, PJ and Richardson, AJ (2013) Global imprint of climate change on marine life. Nature Climate Change 3, 919925.CrossRefGoogle Scholar
Sanvicente-Añorve, L, Salgado-Ugarte, IH, Castillo-Rivera, M, Browman, HI and Skiftesvik, AB (2003) The use of kernel density estimators to analyze length-frequency distributions of fish larvae. The big fish bang: Proceeding of the 26th annual larval fish conference. Bergen: Institute of Marine Research, pp. 419–430.Google Scholar
Schwindt, E, De Francesco, CG and Iribarne, OO (2004) Individual and reef growth of the invasive reef-building polychaete Ficopomatus enigmaticus in a south-western Atlantic coastal lagoon. Journal of the Marine Biological Association of the United Kingdom 84, 987993.CrossRefGoogle Scholar
Shervette, VR, Aguirre, WE, Blacio, E, Cevallos, R, Gonzalez, M, Pozo, F and Gelwick, F (2007) Fish communities of a disturbed mangrove wetland and an adjacent tidal river in Palmar, Ecuador. Estuarine, Coastal and Shelf Science 72, 115128.Google Scholar
Traut, BH (2005) The role of coastal ecotones: a case study of the salt marsh. Journal of Ecology 93, 279290.CrossRefGoogle Scholar
Troost, K (2010) Causes and effects of a highly successful marine invasion: case-study of the introduced Pacific oyster Crassostrea gigas in continental NW European estuaries. Journal of Sea Research 64, 145165.Google Scholar
Valiñas, M (2010) Uso de marismas por organismos submareales, y sus efectos en la estructura de comunidades intermareales y transferencia de nutrientes a la trama trófica estuarial. PhD thesis. Universidad Nacional de Mar del PlataGoogle Scholar
Valiñas, MS, Molina, LM, Addino, M, Montemayor, DI, Acha, EM and Iribarne, OO (2012) Biotic and environmental factors affect Southwest Atlantic saltmarsh use by juvenile fishes. Journal of Sea Research 68, 4956.Google Scholar
Van Tassell, JL, Joyeux, JC, Macieira, RM and Tornabene, LM (2015) Status of Gobiosoma (Teleostei: Gobiidae) from Brazil: description of a new species, redescription of G. hemigymnum, molecular phylogeny of the genus, and key to Atlantic species. Zootaxa 4007, 451480.CrossRefGoogle ScholarPubMed
Vázquez, MG and Bas, CC (2019) Population distribution and group structure of the invasive shrimp Palaemon macrodactylus (Caridea: Palaemonidae) living in a fouling community. Marine Biology Research 15, 282289.Google Scholar
Figure 0

Figure 1. The map shows the geographic distribution range of Gobiosoma hemigymnum (blue line), with the location of the southern limit of distribution before this study (yellow dot), and the new southernmost documented record (light green dot). The Bahía Blanca estuary is shown in detail, with the main harbours, as well as the area covered by Spartina alterniflora marshes and mudflats.

Figure 1

Figure 2. Plate showing record site and morphological characteristic of Gobiosoma hemigymnum. (A) Detail of the place where one of the specimens was collected, showing individuals of Magallana gigas and stems of Spartina alterniflora; (B) drawing showing standard length is ~5 times body height (from Figueroa, 2019). (C) fixed specimen; (D) showing first dorsal fin with VI spines and second dorsal fin with XII rays; (E) detail of the mature female gonads occupying almost the entire fish cavity; (F) pelvic fins fused into an adhesive disc; (G) scaled specimen.

Figure 2

Table 1. Meristic and environmental data, and the results of morphological indices