A paradise for Maldane sarsi antarctica: preliminary characterization of the marine soft-bottom fauna of False Bay (Livingston Island, South Shetland Islands, Antarctica)

Miguel Bascur; Andrea Prófumo; Mariona Gonzalez-Pineda; Pere Monràs-Riera; Tomás Azcárate-García; Àlex Aubach-Masip; Marina De Llobet; Guillem Molina-Vacas; Yara Tibiriçá; Elisenda Ballesté; João Gil; Conxita Avila

doi:10.1017/S0954102025000185

A paradise for Maldane sarsi antarctica: preliminary characterization of the marine soft-bottom fauna of False Bay (Livingston Island, South Shetland Islands, Antarctica)

Part of: Different Perspectives on Antarctic Science, An Homage to Prof. Andrés Barbosa

Published online by Cambridge University Press: 04 June 2025

Miguel Bascur*: Affiliation:
Department of Evolutionary Biology, Ecology, Environmental Sciences, and Biodiversity Research Institute (IRBio), Faculty of Biology, Universitat de Barcelona, Barcelona, Catalonia, Spain
Andrea Prófumo*: Affiliation:
Department of Evolutionary Biology, Ecology, Environmental Sciences, and Biodiversity Research Institute (IRBio), Faculty of Biology, Universitat de Barcelona, Barcelona, Catalonia, Spain
Mariona Gonzalez-Pineda: Affiliation:
Department of Evolutionary Biology, Ecology, Environmental Sciences, and Biodiversity Research Institute (IRBio), Faculty of Biology, Universitat de Barcelona, Barcelona, Catalonia, Spain
Pere Monràs-Riera: Affiliation:
Department of Evolutionary Biology, Ecology, Environmental Sciences, and Biodiversity Research Institute (IRBio), Faculty of Biology, Universitat de Barcelona, Barcelona, Catalonia, Spain
Tomás Azcárate-García: Affiliation:
Department of Evolutionary Biology, Ecology, Environmental Sciences, and Biodiversity Research Institute (IRBio), Faculty of Biology, Universitat de Barcelona, Barcelona, Catalonia, Spain Department of Marine Biology and Oceanography, Institute of Marine Sciences (ICM-CSIC), Barcelona, Catalonia, Spain
Àlex Aubach-Masip: Affiliation:
Department of Evolutionary Biology, Ecology, Environmental Sciences, and Biodiversity Research Institute (IRBio), Faculty of Biology, Universitat de Barcelona, Barcelona, Catalonia, Spain
Marina De Llobet: Affiliation:
Department of Evolutionary Biology, Ecology, Environmental Sciences, and Biodiversity Research Institute (IRBio), Faculty of Biology, Universitat de Barcelona, Barcelona, Catalonia, Spain School of Ocean Sciences, Bangor University, Menai Bridge, UK
Guillem Molina-Vacas: Affiliation:
Department of Evolutionary Biology, Ecology, Environmental Sciences, and Biodiversity Research Institute (IRBio), Faculty of Biology, Universitat de Barcelona, Barcelona, Catalonia, Spain
Yara Tibiriçá: Affiliation:
University of Guam, Marine Laboratory, Mangilao, GU, USA
Elisenda Ballesté: Affiliation:
Department of Genetics, Microbiology and Statistics, Faculty of Biology, Universitat de Barcelona, Barcelona, Catalonia, Spain
João Gil: Affiliation:
Centre of Marine Sciences (CCMAR), University of Algarve, Campus de Gambelas, Faro, Portugal
Conxita Avila: Affiliation:
Department of Evolutionary Biology, Ecology, Environmental Sciences, and Biodiversity Research Institute (IRBio), Faculty of Biology, Universitat de Barcelona, Barcelona, Catalonia, Spain
*: Corresponding author: Miguel Bascur and Andrea Prófumo; Emails: mbascuba7@alumnes.ub.edu; aprofumo@ub.edu
Corresponding author: Miguel Bascur and Andrea Prófumo; Emails: mbascuba7@alumnes.ub.edu; aprofumo@ub.edu

Article contents

Abstract
Introduction
Methods
Distribution and population features of Maldane sarsi antarctica
Results
Distribution and population features of Maldane sarsi antarctica
Discussion
Ecological importance of Polychaeta and population features of Maldane sarsi antarctica
Conclusions
Competing interests
Author contributions
Financial support
Footnotes
References

Rights & Permissions

Abstract

Soft-bottom areas are among the least explored ecosystems in Antarctica. To improve our understanding of these environments, we performed a preliminary assessment of the marine macrobenthic fauna in False Bay, Livingston Island, near Huntress Glacier (South Shetland Islands, Antarctica). Fourteen Van Veen grabs (0.018 m2 area) were deployed at two stations within the bay at depths of 174–210 m. The samples provided values up to 159 556 individuals m-2 within 15 major taxonomic groups. Annelida Polychaeta was predominant (~93%), followed by Ophiuroidea and Bivalvia at the external station and Bivalvia and Amphipoda at the internal site. Maldanid polychaetes, particularly Maldane sarsi antarctica, constituted 84.62–90.74% of the samples. Total biomass was 6673.25 grams of wet weight per square metre, mainly from Ascidiacea, Polychaeta, Holothuroidea and Ophiuroidea. Approximately 12% of the macrofauna inhabited the sediment (epifauna), while 88% lived into the sediments (infauna). Regarding feeding modes, specimens were detritivores (77.91–82.71%), suspension-feeders (7.59–13.37%) and, infrequently, predators (4.07–5.07%) and grazers (4.63–4.65%). According to the compilation of occurrence records in the Southern Ocean, M. sarsi antarctica has a circum-Antarctic distribution. Furthermore, the population of this species in False Bay appears to be stable and undisturbed with a normal distribution in size structure, with a higher proportion of individuals at intermediate sizes (2.85–4.26 cm). This study provides for the first time detailed descriptions of the macrofauna from the soft bottoms of False Bay, representing a preliminary effort to monitor ecological shifts in this critically important and understudied region, which is experiencing rapid environmental changes within Antarctic marine ecosystems.

Keywords

Annelida Polychaeta marine invertebrates polar assemblages sedimentary habitats Southern Ocean

Information

Type: Biological Sciences
Information: Antarctic Science , First View , pp. 1 - 14

DOI: https://doi.org/10.1017/S0954102025000185 [Opens in a new window]
Creative Commons: This is an Open Access article, distributed under the terms of the Creative Commons Attribution licence (https://creativecommons.org/licenses/by/4.0), which permits unrestricted re-use, distribution and reproduction, provided the original article is properly cited.
Copyright: © The Author(s), 2025. Published by Cambridge University Press on behalf of Antarctic Science Ltd

Introduction

Marine soft sediments are among the most widespread habitats in the world’s oceans and play a fundamental role in the functioning of marine ecosystems (Gray Reference Gray2002, Pan & Pratolongo Reference Pan, Pratolongo, Pan and Pratolongo2022). These habitats are primarily composed of fine-grained sediments such as mud, sand and gravel and host many diverse benthic communities that are crucial in processes such as energy transfer in trophic networks, nutrient and carbon cycling, contaminant removal and secondary production (Snelgrove et al. Reference Snelgrove, Blackburn, Hutchings, Alongi, Grassle and Hummel1997, Lohrer & Hancock Reference Lohrer and Hancock2004, Schratzberger & Ingels Reference Schratzberger and Ingels2018). Currently, marine soft sediments face many threats, including climate hazards and anthropogenic pressures (Brierley & Kingsford Reference Brierley and Kingsford2009, Gissi et al. Reference Gissi, Manea, Mazaris, Fraschetti, Almpanidou and Bevilacqua2021, Williamson & Guinder Reference Williamson, Guinder and Letcher2021). For instance, ocean warming and pollution can alter sediment characteristics, leading to shifts in species compositions and ecosystem services (Altafim et al. Reference Altafim, Alves, Trevizani, Figueira, Gallucci and Choueri2023, Vlaminck et al. Reference Vlaminck, Moens, Braeckman and Van Colen2023). Despite their significance, marine soft sediments are still poorly studied, particularly in polar areas, making it crucial to obtain a deeper understanding of these ecosystems given the current global climate trends.

The composition of faunal assemblages inhabiting soft-bottom ecosystems is shaped by a complex interplay of environmental factors, where depth, sediment type and organic matter content are particularly relevant (Snelgrove Reference Snelgrove1999, Vause et al. Reference Vause, Morley, Fonseca, Jażdżewska, Ashton and Barnes2019). Among the invertebrate macrofauna, the most representative phyla in these assemblages are annelid polychaetes, crustaceans, molluscs and echinoderms, although other annelids (e.g. echiurans and sipunculans) and nemerteans are also present in lower abundances (Snelgrove Reference Snelgrove1998, Ellingsen Reference Ellingsen2001). The organisms living in these assemblages are typically characterized by limited mobility, and they may inhabit either into the sediment (infauna), the sediment surface (epifauna) or both (e.g. Pearson Reference Pearson2001). Regarding feeding strategies, suspension-feeders (both active and passive), deposit-feeders (surface or subsurface) and predators usually dominate these marine sediments, although other feeding types may also be present (Snelgrove Reference Snelgrove1999, Macdonald et al. Reference Macdonald, Burd and Van Roodselaar2012). Additionally, due to their three-dimensional body structures extending above the sediment, some of these organisms may act as ecosystem engineers and provide substrates for other organisms to attach to and grow upon (Rabaut et al. Reference Rabaut, Guilini, Van Hoey, Vincx and Degraer2007, Meadows et al. Reference Meadows, Meadows and Murray2012).

In the Southern Ocean, faunal assemblages differ from those found elsewhere in the world due to several environmental characteristics, such as isolation, water temperature and continental shelf depth (Barnes & Clarke Reference Barnes and Clarke2011). Although all phyla can be found in this ocean, two types of soft-bottom assemblages can be differentiated: 1) those dominated by sessile suspension-feeding epifauna, such as sponges or ascidians, and 2) those dominated by infauna and mobile epifauna, such as polychaetes, bivalves and echinoderms (Gutt Reference Gutt2007 and references therein). Furthermore, because durophagy is absent in these environments, the main predators are species such as sea stars and nemerteans, among other vagile taxa (Dayton et al. Reference Dayton, Robilliard, Paine and Dayton1975, Aronson & Blake Reference Aronson and Blake2001, Clarke et al. Reference Clarke, Aonson, Crame, Gili and Blake2004, Ortiz et al. Reference Ortiz, Hermosillo-Nuñez, González, Rodríguez-Zaragoza, Gómez and Jordán2017).

Widely reported regional changes, such as the reduction of the annual duration of sea ice, the melting and retreat of marine-terminating glaciers and the collapse of ice shelves around Antarctica during recent decades, are significant threats to biodiversity in these zones (Gutt et al. Reference Gutt, Barratt, Domack, d'Acoz, Dimmler and Grémare2011, Ducklow et al. Reference Ducklow, Fraser, Meredith, Stammerjohn, Doney and Martinson2013, Cook et al. Reference Cook, Holland, Meredith, Murray, Luckman and Vaughan2016, Henley et al. Reference Henley, Schofield, Hendry, Schloss, Steinberg and Moffat2019, Post et al. Reference Post, Alley, Christensen, Macias-Fauria, Forbes and Gooseff2019, IPCC Reference Lee and and Romero2023). Considering that many of these Antarctic areas remain underexplored, predictions for the future of their soft-bottom marine biodiversity in the face of climate change are uncertain (e.g. Vause et al. Reference Vause, Morley, Fonseca, Jażdżewska, Ashton and Barnes2019). This is especially true in the South Shetland Islands, an archipelago close to the Polar Front, a crucial boundary where cold Antarctic waters meet warmer sub-Antarctic waters (e.g. Orsi et al. Reference Orsi, Whitworth and Nowlin1995).

Annelid polychaetes represent one of the most common and abundant taxa in marine benthic communities worldwide, particularly in sedimentary environments (Knox Reference Knox, Reish and Fauchald1977, Hutchings Reference Hutchings1998, Crespo & Pardal Reference Crespo, Pardal, Leal Filho, Azul, Brandli, Lange Salvia and Wall2020, Giangrande et al. Reference Giangrande, Gambi, Gravina, Rossi and Bramanti2020). Several studies have demonstrated their dominance in terms of species richness, abundance and biomass in soft-bottom habitats (Knox Reference Knox, Reish and Fauchald1977, Hutchings et al. Reference Hutchings, Ward, Waterhouse and Walker1993, Smith Reference Smith2000). This dominance is particularly notable in polar areas (Kendall et al. Reference Kendall, Widdicombe and Weslawski2003, Piepenburg Reference Piepenburg2005, Clarke & Crame Reference Clarke and Crame2010, Pabis et al. Reference Pabis, Sicinski and Krymarys2011), where they may reach more than half of the total benthic invertebrate biomass (Knox Reference Knox, Reish and Fauchald1977). Polychaetes play a critical role in ecosystems by creating new habitats and modifying the redox conditions of the sediment through bioturbation (Bolam & Fernandes Reference Bolam and Fernandes2002, Mermillod-Blondin Reference Mermillod-Blondin2011, Kristensen et al. Reference Kristensen, Penha-Lopes, Delefosse, Valdemarsen, Organo Quintana and Banta2012, Jumars et al. Reference Jumars, Dorgan and Lindsay2015). These processes are essential to allowing oxygenation and the transportation of surface materials to the deeper sediment layers, maintaining and even creating soft-bottom ecosystem structures.

Thus, to enhance our understanding of Antarctic marine soft-bottom assemblages in underexplored ecosystems threatened by global warming, this study aimed to provide a preliminary description of the marine fauna inhabiting False Bay in Livingston Island (South Shetland Islands). These new insights represent a valuable baseline for future studies assessing the broader ecological implications beyond the climate-induced changes in Antarctic ecosystems.

Methods

Study location

The present study was carried out during January 2023 (summer) at False Bay, Livingston Island (South Shetland Islands, Antarctica) in the framework of the CHALLENGE Antarctic campaign by our research group (Universitat de Barcelona). This cove of 6.4 km in length lies between Barnard Point and Hurd Peninsula, on the south side of Livingston Island (62°43^′S, 60°22^′W; Fig. 1). Within this bay, we selected two different stations to obtain a preliminary description of the marine benthic macrofauna: an exterior site and a more internal one (Fig. 1). These two stations were chosen based on their contrasting distance from Huntress Glacier, located in the innermost part of the bay, and according to the logistical necessities of our cruise. False Bay has some marine-terminating glaciers, with Huntress Glacier being the largest, despite having shown a gradual retreat in recent years (Cook et al. Reference Cook, Fox and Thomson2021).

Figure 1. Sampling locations in a. the West Antarctic Peninsula and the South Shetland Islands, b. Livingston Island and c. within False Bay. Sampling locations are shown as green triangles (E = external station; I = internal station).

Environmental variables

Oceanographic data, including seawater temperature (°C), salinity (PSU), chlorophyll-a (mg m^-3) and dissolved oxygen (mg l^-1), were obtained from both stations within the bay using a Sea-bird SBE 11plus CTD (conductivity-temperature-depth) device to characterize the environmental conditions from the collection sites. The 10 deepest data points from each vertical profile, and thus closest to the biological sampling location, were pooled to obtain the mean and standard deviation for each station and variable (Table I). Substrate descriptions rely on visual observations, indicating a detritic mud environment.

Table I. Sampling location and characteristics of the stations, including dredge and CTD (conductivity-temperature-depth) device sampling coordinates, depths and environmental data. Data for environmental parameters indicate means ± standard deviation.

Chl-a = chlorophyll-a; DO = dissolved oxygen.

Sample collection and classification

More than 20 Van Veen dredges (0.15 × 0.12 × 0.40 m; 0.018 m² area) were deployed from the starboard side of the vessel, with a depth range of 174–210 m. Only some of these dredges retrieved sediments: 10 from the external station and 4 from the more internal station, thus rendering a total of 14 samples. All of the dredges’ contents underwent meticulous sieving using seawater through a 1 mm mesh sieve. The organisms and sediment captured were subsequently relocated to the wet laboratory. Separation using tweezers was carefully performed to sort all of the macrofauna from the fine sediment. All of the specimens found were then categorized into broad taxonomic groups, mainly classes (although for crustaceans we used orders), and carefully preserved in pre-labelled bottles containing absolute ethanol. Later, at the laboratories of the Universitat de Barcelona, all individuals were counted, their wet weight was obtained and they were photographed using an Euromex® stereomicroscope. Finally, abundances and biomass data were standardized as individuals per square metre (ind. m^-2) and grams of wet weight (WW) per square metre (g WW m^-2), respectively. As we could not obtain sufficient replicates from the internal station and dredge samples were pooled at each site, a statistical comparison between both stations was not performed, although we provide here all of the descriptive data regarding the fauna collected.

Taxonomic identification and feeding guilds

Most specimens were preliminarily identified by the authors to the lowest possible taxonomic level using the available literature (Brueggeman Reference Brueggeman1998, Engl Reference Engl2012, Rauschert et al. Reference Rauschert, Arntz and Hempel2015, Xavier et al. Reference Xavier, Cherel, Boxshall, Brandt, Coffer and Forman2020, Drennan et al. Reference Drennan, Dahlgren, Linse and Glover2021). Then, the preliminary identifications, together with their respective photographs, were sent to specialists of the different taxonomic groups to confirm their identification (Tables II & S1). Additionally, all organisms found were classified, based on the abundance data, using relative frequency according to their feeding behaviour (grazers, suspension-feeders, predators and detritivores) or their physical habitat (infauna or epifauna), following the most relevant literature (Jumars et al. Reference Jumars, Dorgan and Lindsay2015, Barnes & Sands Reference Barnes and Sands2017, Mohd Nasir et al. Reference Mohd Nasir, Barnes and Wan Hussin2024, Souster et al. Reference Souster, Barnes, Primicerio and Jørgensen2024). The detritivore functional group also included deposit-feeder specimens. Only for specimens that could alternate between both physical habitats (epifauna and infauna) or could present different feeding types, a frequency > 1 was recorded.

Table II. Summary of abundances and biomasses for the main groups and species found in this study. Data extracted from the full Table S1.

ind. = individuals; WW = wet weight.

Distribution and population features of Maldane sarsi antarctica

Due to the clear dominance of M. sarsi antarctica Arwidsson, Reference Arwidsson1911 in the soft-bottom environment at our study sites, an in-depth analysis of some of the ecological characteristics of this species was carried out. A comprehensive search of the spatial distribution of this species across the Antarctic region was conducted to provide context for its occurrence in False Bay. A preliminary search was conducted of georeferenced occurrence records compiled from the published literature (Siciński Reference Ahn and Kang1986, Ahn & Kang Reference Ahn and Kang1991, Cantone Reference Cantone1995, Parapar et al. Reference Parapar, López, Gambi, Núñez and Ramos2011, Pabis & Siciński Reference Pabis, Sicinski and Krymarys2012) and public databases such as SCAR-MarBin (https://www.vliz.be/projects/scarmarbin/), OBIS (https://www.obis.org/), GBIF (http://www.gbif.org/) and Biodiversity.aq (https://www.biodiversity.aq/), selecting only those records that provided geographical coordinates. Occurrence records were obtained from Biodiversity.aq, given that this repository integrates data from all other relevant databases. Moreover, occurrence records were also extracted from research articles in which this polychaete species was recorded (see Data S1). The dataset was processed and visualised using QGIS v.3.40 software to generate a map representing its known distribution and also to display the sampling depths of each record in order to offer further insights into the species’ bathymetric range. However, some studies reporting the presence of this species were not included in the dataset (e.g. Garraffoni et al. Reference Garraffoni, Moura, Vasconcelos, Araújo and Passos2012), as they did not provide exact geographical coordinates or sampling depths nor specify its occurrence at a precise sampling station, despite confirming its presence in the study areas. In general, these studies do not refer to new distribution sites but rather to already-sampled locations that are represented in the compiled dataset (Data S1).

The size structure of the M. sarsi antarctica population in False Bay was also studied. To obtain a representative sample of the population, we used stratified sampling (Andrew & Mapstone Reference Andrew and Mapstone1987). The total population of 2412 individuals were divided into three strata based on body size, categorized as small, medium and large, as determined by visual observation. Once the population was stratified, the number of individuals in each stratum was counted. Each stratum was then assigned a sample size proportional to its representation in the total population using the calculation in Equation 1:

(1)

$$\begin{align}{n}_i = \frac{N_i}{N_{total}}\times {n}_{sample}\end{align}$$

where n_i is the theoretical number of individuals from the stratum, N_i is the total number of individuals in stratum i, N_total is the total number of individuals in the population and n_sample is the subsample selected from the total population. Once the sample proportion for each stratum was determined as small (26.83%), medium (56.10%) or large (17.07%), 410 individuals (~17% of the total population) were randomly selected within each stratum to measure their total length. Using a Vernier calliper, the total length (from the tip of the head to the end of the pygidium) was then measured (in cm). Using the size database, the data were sorted in increasing order to determine the minimum and maximum size so as to obtain the total rank (R = maximum - minimum). Then, the interquartile range (IQR) was calculated by subtracting the size value of the first quartile (Q1) from the data of the third quartile (Q3). Using the IQR and the number of samples, the width of each interval was calculated using the Freedman-Diaconis rule (Freedman & Diaconis Reference Freedman and Diaconis1981), shown in Equation 2:

(2)

$$\begin{align}h = 2\times IQR\times {n}^{-1/3}\end{align}$$

where h is the width of each interval and n is the number of observations. Finally, the total rank (R) was divided by the interval width (h) to establish nine different and appropriate categories for the frequency histogram in order to display the population characteristics of the species’ size.

Results

Environmental variables

The collected data from both stations in False Bay showed variations in the environmental conditions between the two sites (Table I). The internal station, situated at a shallower depth, presented slightly warmer temperatures (1.75 ± 0.01°C vs 0.82 ± 0.01°C) and higher chlorophyll-a concentrations (0.18 ± 0.01 vs 0.08 ± 0.01 mg m^-3) than the external site, located at a greater depth. Furthermore, the dissolved oxygen concentration was higher at the internal station (6.82 ± 0.01 mg l^-1) compared to the external one (5.99 ± 0.01 mg l^-1). Both stations shared similar sediment characteristics when visually evaluated, consisting of mud and gravel, indicative of a low-energy depositional environment.

Assemblage characteristics

A total of 159 556 ind. m^-2 were identified in this study, classified into 15 major taxonomic groups: Polychaeta, Bivalvia, Amphipoda, Ophiuroidea, Asteroidea, Pycnogonida, Isopoda, Holothuroidea, Ascidiacea, Priapulida, Nemertea, Cnidaria, Bryozoa, Gastropoda and Porifera (Fig. 2 & Tables II & S1). From these, total abundances were 151 778 ind. m^-2 at the external station and 7778 ind. m^-2 at the internal station, corresponding to 15 and 6 major taxonomic groups, respectively (Tables II & S1). For both stations, Polychaeta was the most abundant taxon (~93%; Fig. 3). Ophiuroidea (2.23%) and Bivalvia (1.65%) were the next more abundant taxa for the external station, while Bivalvia (2.86%) and Amphipoda (2.14%) were the next more abundant taxa for the internal one (Fig. 3).

Figure 2. Images of the most representative specimens collected during the second expedition of the CHALLENGE project in False Bay (Livingston Island): a. Phoxocephalidae (Amphipoda), b. Aphelochaeta sp. (Polychaeta), c. Natatolana sp. (Isopoda), d. Maldane sarsi antarctica (Polychaeta), e. Thyasira debilis (Bivalvia), f. Nymphon charcoti (Pycnogonida), g. Amphiura cf. joubini (Ophiuroidea) and h. Amphiura sp. (Ophiuroidea). All scale bars = 1 cm, except for e. scale bar = 2 mm.

Figure 3. Contribution to relative abundances of taxonomic groups found at the a. external and b. internal stations. The pie charts show the overall composition of assemblages, including polychaetes, with the expanded sections detailing the distribution of other taxa.

The total biomass measured was 6673.25 g WW m^-2, of which 6239.25 g WW m^-2 corresponded to the external station and 434 g WW m^-2 corresponded to the internal station (Table S1). Ascidiacea (27.59%) and Polychaeta (30.10%) had similar percentages, followed by Holothuroidea (20.62%) and Ophiuroidea (14.25%), in terms of being the main contributors to the biomass at the external station (Fig. 4). At the internal station, the biomass was instead dominated by Ascidiacea (66.84%), followed by Polychaeta (16.45%) and Pycnogonida (14.90%; Fig. 4).

Figure 4. Contribution to relative biomasses of taxonomic groups found at the a. external and b. internal stations. The pie charts show the overall composition of assemblages, with the expanded sections detailing the distribution of other taxa.

Regarding Polychaeta, both sampling stations exhibited a high relative abundance, ranging from 84.62% to 90.74% for the family Maldanidae (i.e. M. sarsi antarctica; Fig. 5 & Table II), with a biomass of 1348.02 g WW m^-2 at the external station and 56.08 g WW m^-2 at the internal station (Fig. 6 & Tables II & S1). After maldanids, Cirratulidae (3.94–9.23%), Lumbrineridae (1.65–2.31%) and Spionidae (0.87–1.54%) were the most abundant polychaete families at both stations. For polychaetes, the main difference between the stations was the total number of families, with 15 being present at the external station compared to 7 being present at the internal station (Table S1).

Figure 5. Contribution to relative abundances of different Polychaeta families found at the a. external and b. internal stations. The pie charts show the overall composition of assemblages, including Maldanidae, with the expanded sections detailing the distribution of other families.

Figure 6. Contribution to relative biomasses of different Polychaeta families found at the a. external and b. internal stations. The pie charts show the overall composition of assemblages, with the expanded sections detailing the distribution of other taxa.

The distributions of functional groups based on their feeding behaviour (grazers, suspension-feeders, predators and detritivores) were similar at both stations, with a predominant contribution of detritivores. However, the external station showed slightly higher proportions of predators (5.07%) and detritivores (82.71%) but a lower proportion of suspension-feeders (7.59%) compared to the internal station (4.07%, 77.91% and 13.37%, respectively; Fig. 7). The contributions of the infauna and the epifauna were also similar at both stations, with much higher values observed for the infauna than the epifauna (Fig. 7).

Figure 7. Relative contribution (%) of all sampled individuals according to their feeding behaviour (left) and physical habitat (right).

Distribution and population features of Maldane sarsi antarctica

A total of 186 previous records were found for M. sarsi antarctica, in a depth range from 40 to 3700 m. Our map indicates a circum-Antarctic distribution for this species in the Antarctic benthos, with a major sampling focus on the South Shetland Islands and the Bellingshausen Sea and a significant lack of records in the southern Indian Ocean (Fig. S1 & Data S1).

The size distribution of M. sarsi antarctica ranged from 0.73 to 7.78 cm, with the highest concentration of individuals in the 2.85–3.55 cm (21.95%) and 3.55–4.26 cm (20.73%) intervals (Fig. S2, Table S2 & Data S2). The distribution follows a unimodal pattern, with a greater abundance of organisms in intermediate size classes and a gradual decrease towards the extremes (Fig. S2, Table S2 & Data S2). Therefore, these results indicate that the population is dominated by individuals in intermediate developmental stages, with fewer very small or large organisms.

Discussion

This study provides a first local-scale characterization of the marine soft-bottom assemblages inhabiting False Bay (Livingston Island). Our results show that benthic assemblages were dominated by Polychaeta in terms of relative abundance and a shared dominance of Ascidiacea, Ophiuroidea and Pycnogonida in terms of relative biomass, suggesting their successful adaptation to efficiently exploit the resources of this habitat. In particular, False Bay is a paradise for the maldanid M. sarsi antarctica, which is the most abundant species by far. Considering that several physical and ecological changes have been recorded widely in Antarctica due to global change and anthropogenic causes (Cook et al. Reference Cook, Holland, Meredith, Murray, Luckman and Vaughan2016, Rogers et al. Reference Rogers, Frinault, Barnes, Bindoff, Downie and Ducklow2020), this study represents a first step towards providing a baseline for future studies addressing marine conservation policies and the effects of these changes on these particular soft-bottom marine ecosystems.

Composition of benthic assemblages

Studies on soft-bottom benthic macrofauna involving both infaunal and epifaunal sources are relatively scarce, especially for Antarctica (Table III; Jażdżeski et al. Reference Jażdżeski, Jurasz, Kittel, Presler, Presler and Siciński1986, Sáiz-Salinas et al. Reference Sáiz-Salinas, Ramos, García, Troncoso, San Martín, Sanz and Palacin1997, Arnaud et al. Reference Arnaud, López, Olaso, Ramil, Ramos-Esplá and Ramos1998, Angulo-Preckler et al. Reference Angulo-Preckler, Leiva, Avila and Taboada2017b, Reference Angulo-Preckler, Figuerola, Núñez-Pons, Moles, Martín-Martín and Rull-Lluch2018). Additional studies are required to determine the current situation and the effects of global change in polar areas, including with regard to glacier retreat. Most recent studies, however, focus mainly on assessing changes in the mega-epifauna around Antarctica through seafloor imagery and on infaunal descriptions using environmental DNA (e.g. Vause et al. Reference Vause, Morley, Fonseca, Jażdżewska, Ashton and Barnes2019, Grimes et al. Reference Grimes, Donnelly, Ka, Noor, Mahon and Halanych2023). Our results reveal that in False Bay the dominant group was Polychaeta, followed by lower abundances of Bivalvia, Amphipoda and Ophiuroidea (only at the external station). The observed dominant taxonomic groups in this study align with previous descriptions from other regions of the planet (Table III). In such reports, with some exceptions, the Annelida, Crustacea, Mollusca and, sometimes, Echinodermata (especially in Antarctica) are the most dominant groups, even though differences exist in the sedimentary environment, the depth sampled (~5–4700 m) or the collecting methods used (e.g. Agassiz trawls, Van Veen dredges, box corers, scuba diving; Table III). These study areas include the tropical deep sea (Cosson et al. Reference Cosson, Sibuet and Galeron1997, Quintanar-Retama et al. Reference Quintanar-Retama, Vázquez-Bader and Gracia2023), temperate areas (Sardá et al. Reference Sardá, Martin, Pinedo, Dueso, Cardell, Eleftheriou, Ansell and Smith1995, Martins et al. Reference Martins, Quintino and Rodrigues2013, Soto et al. Reference Soto, Quiroga, Ganga and Alarcón2017), Arctic zones (Ellingsen Reference Ellingsen2001, Ellingsen & Gray Reference Ellingsen and Gray2002) and the South Shetland Islands in Antarctica (Sáiz-Salinas et al. Reference Sáiz-Salinas, Ramos, García, Troncoso, San Martín, Sanz and Palacin1997, Arnaud et al. Reference Arnaud, López, Olaso, Ramil, Ramos-Esplá and Ramos1998, Angulo-Preckler et al. Reference Angulo-Preckler, Tuya and Avila2017a,Reference Angulo-Preckler, Leiva, Avila and Taboadab, Reference Angulo-Preckler, Figuerola, Núñez-Pons, Moles, Martín-Martín and Rull-Lluch2018; Table III). However, in contrast to our work, in these previous studies there was no such clear dominance of a single group, and the total abundances were distributed among two or more different taxonomic groups. Only one previous study carried out in Admiralty Bay (King George Island, South Shetland Islands) found similar results to those reported here in terms of dominance, with Polychaeta constituting 67.7% of the total fauna at 250 m depth, and Bivalvia reaching 86% of the total fauna at 15 m depth (Jażdżeski et al. Reference Jażdżeski, Jurasz, Kittel, Presler, Presler and Siciński1986). In our study, the substantial differences in abundances between the internal and external sites could be related to the low number of replicates obtained in the study, but it could also be related to the distinct environmental parameters reported, such as the slightly higher temperature, higher chlorophyll-a concentration and higher dissolved oxygen concentration at the internal site. The internal site, being closer to the glacier front, was probably colonized much later than the external one, and this is relevant for both the species composition and the biomass found. In addition, near-shore marine Antarctic biodiversity may also be affected by shifts in the ice sheet caused by climate change, altering essential habitats (Pritchard et al. Reference Pritchard, Ligtenberg, Fricker, Vaughan, van den Broeke and Padman2012, Noble et al. Reference Noble, Rohling, Aitken, Bostock, Chase and Gomez2020). For instance, ocean warming has accelerated the melting of glaciers and the collapse of several ice shelves (Cook et al. Reference Cook, Holland, Meredith, Murray, Luckman and Vaughan2016, Davison et al. Reference Davison, Hogg, Gourmelen, Jakob, Wuite and Nagler2023). Additionally, sea ice now forms later and melts earlier within a calendar year, contributing to the intensification of global warming (e.g. Purich & Doddridge Reference Purich and Doddridge2023). Further studies are needed to carefully consider both of these possibilities.

Table III. Main taxonomic groups, based on the total abundance, found in previous similar studies from soft-bottom habitats around the world, from low to high latitudes.

^a These values were calculated from the original data.

^b Abundance data not available.

ind. = individuals.

Biomass in False Bay, however, was not dominated by a particular taxon but showed a distribution between Ascidiacea, Polychaeta, Holothuroidea, Ophiuroidea and Pycnogonida. These data are similar to those obtained in previous Antarctic studies, where biomass was also distributed among different groups, such as Ascidiacea, Echinodermata, Porifera, Polychaeta and, occasionally, Bryozoa (Jażdżeski et al. Reference Jażdżeski, Jurasz, Kittel, Presler, Presler and Siciński1986, Sáiz-Salinas et al. Reference Sáiz-Salinas, Ramos, García, Troncoso, San Martín, Sanz and Palacin1997, Arnaud et al. Reference Arnaud, López, Olaso, Ramil, Ramos-Esplá and Ramos1998). Considering the patchiness of Antarctic marine assemblages at small spatial scales and the complexity of the environmental variations, it is usually assumed that assemblage compositions can be highly variable (Gutt Reference Gutt2007, Gutt et al. Reference Gutt, Arndt, Kraan, Dorschel, Schröder, Bracher and Piepenburg2019). According to assembly theory, both stochastic and deterministic factors shape the structure of these marine communities (Vellend Reference Vellend2016). It is well established that marine fauna possessing specialized traits to exploit specific microhabitats can successfully colonize these areas, forming assemblages based on habitat affinity (Sebens Reference Sebens, Bell, McCoy and Mushinsky1991, Convey et al. Reference Convey, Chown, Clarke, Barnes, Bokhorst and Cummings2014). Unfortunately, few studies have addressed these dynamics in Antarctica, rendering the current conclusions only preliminary. Some research suggests that, at large spatial scales, certain assemblages are primarily influenced by random processes (e.g. Valdivia et al. Reference Valdivia, Garcés-Vargas, Garrido, Gómez, Huovinen and Navarro2021), whereas studies at smaller scales indicate that environmental filtering is the dominant driver (e.g. Valdivia et al. Reference Valdivia, Garrido, Bruning, Piñones and Pardo2020). Thus, the spatial scale at which assemblage mechanisms are examined appears to be highly relevant. In this context, we propose that strong small-scale environmental filtering in False Bay has probably produced local assemblages characterized by highly convergent functional traits, such as those observed in terms of the dominance of deposit-feeders (Gutt Reference Gutt2007). This assemblage composition could be related to the unique characteristics of the available organic matter, sediment grain size or seafloor stability of this particular glacier bay (Sañé et al. Reference Sañé, Isla, Gerdes, Montiel and Gili2012, Learman et al. Reference Learman, Henson, Thrash, Temperton, Brannock and Santos2016, Vause et al. Reference Vause, Morley, Fonseca, Jażdżewska, Ashton and Barnes2019). Further studies are needed to clarify all of these relationships, and in particular why M. sarsi antarctica is ‘in paradise’ within False Bay, exhibiting the highest values for abundance and biomass of all of the taxonomic groups found there.

Benthic assemblages in False Bay are clearly dominated by deposit-feeding infauna, suggesting that sedimentation of organic matter from phytodetritus to the seabed plays a fundamental role in shaping the trophic structure of the ecosystem, providing a constant food source for these organisms (Gutt Reference Gutt2007, Angulo-Preckler et al. Reference Angulo-Preckler, Figuerola, Núñez-Pons, Moles, Martín-Martín and Rull-Lluch2018). In this context, previous studies have proposed a ‘food banks’ theory for Antarctica (Glover et al. Reference Glover, Smith, Mincks, Sumida and Thurber2008, Mincks et al. Reference Mincks, Smith, Jeffreys and Sumida2008, Smith et al. Reference Smith, DeMaster, Thomas, Srsen, Grange, Evrard and DeLeo2012). This theory suggests that, due to the cold temperatures of the Southern Ocean, organic matter reaching the seafloor from phytodetritus flux and/or resuspension can remain available year-round for consumption by detritivorous (e.g. deposit-feeder) organisms (Glover et al. Reference Glover, Smith, Mincks, Sumida and Thurber2008). In contrast, the lower abundances of filter-feeding epifauna, such as Bryozoa and Ascidiacea, may indicate a more limited connection between the water column and the benthos, potentially resulting from the stability of the seabed, where the lack of strong currents reduces the availability of suspended particles for filter-feeders (Arnaud et al. Reference Arnaud, López, Olaso, Ramil, Ramos-Esplá and Ramos1998, Gutt Reference Gutt2007, Dunlop et al. Reference Dunlop, Harendza, Plassen and Keeley2020). Another potential cause of the low amount of epifauna in False Bay could be the dominant grain size of the sediment. Because of the lack of strong currents, the type of sediment that would accumulate most in this bay is detritic mud. As reported previously, epifaunal species are more abundant in sediments with medium or large grain sizes, such as sand or gravel, than in muddy sediments (Gray Reference Gray2002, Zhulay et al. Reference Zhulay, Iken, Renaud and Bluhm2019). However, despite the predominance of detritivores in False Bay, there were also some mobile epifaunal taxa characteristic of these infaunal-dominated assemblages that could obtain their food through predation or grazing, such as Ophiuroidea, Asteroidea, Amphipoda or Isopoda, although they appeared in much lower densities. This scenario suggests that the benthic community in this area may be highly specialized, with adaptations that enable organisms such as detritivores to thrive in an environment with specific environmental characteristics and ecological niches that support their development.

Ecological importance of Polychaeta and population features of Maldane sarsi antarctica

It has been widely described that polychaetes can significantly alter sediment conditions, which in turn can modify the structure and composition of benthic communities, emphasizing their role as engineering species in sedimentary marine ecosystems (Sanders et al. Reference Sanders, Goudsmit, Mills and Hampson1962, Levin et al. Reference Levin, Blair, DeMaster, Plaia, Fornes, Martin and Thomas1997, Waldbusser et al. Reference Waldbusser, Marinelli, Whitlatch and Visscher2004, Kongsrud & Rapp Reference Kongsrud and Rapp2012). In our study, polychaetes accounted for ~93% of the total relative abundance obtained, with totals of 15 and 7 different families observed at the external and internal stations, respectively. Those results are within the values of previous studies examining soft-bottom polychaete assemblages in Antarctica, with numbers of families ranging from 13 to 27 (Parapar et al. Reference Parapar, López, Gambi, Núñez and Ramos2011, Pabis & Sobczyk Reference Pabis and Sobczyk2015, Paiva et al. Reference Paiva, Seixas and Echeverría2015, Angulo-Preckler et al. Reference Angulo-Preckler, Leiva, Avila and Taboada2017b). This contrasting composition may be associated with various factors such as depth, sediment grain size and organic matter content.

Remarkably, the family Maldanidae emerged as a key group in our study, representing 90.74% of the total abundance for the external station and 84.62% for the internal station. Maldanids are known for building tubes in soft and mixed sediments in both horizontal and vertical orientations (Day Reference Day1967, Jiménez-Cueto & Salazar-Vallejo Reference Jiménez-Cueto and Salazar-Vallejo1997, De Assis et al. Reference De Assis, Alonso and Christoffersen2007). These tube constructions allow them to inhabit a wide range of habitats, from the intertidal region to the deep sea (Paterson et al. Reference Paterson, Glover, Barrio Froján, Whitaker, Budaeva, Chimonides and Doner2009, De Assis & Christoffersen Reference De Assis and Christoffersen2011). Maldanids feed mainly on organic matter, either in surface or in subsurface deposits, contributing to sediment irrigation and the supply of fresh organic matter for other infaunal organisms (Fauchald & Jumars Reference Fauchald and Jumars1979, Rouse & Pleijel Reference Rouse and Pleijel2001, Dufour et al. Reference Dufour, White, Desrosiers and Juniper2008, Jumars et al. Reference Jumars, Dorgan and Lindsay2015). Previous studies found that one of the most abundant maldanid species in Antarctica was M. sarsi antarctica Arwidsson, Reference Arwidsson1911, with maximum densities of between 139 and 2786 ind. m^-2 (e.g. San Martín et al. Reference San Martín, Parapar, García and Redondo2000, Siciński Reference Siciński2000, Siciński et al. Reference Siciński, Jażdżewski, Broyer, Presler, Ligowski and Nonato2011, Pabis & Sobczyk Reference Pabis and Sobczyk2015, Cataldo-Mendez et al. Reference Cataldo-Mendez, Brante and Urzúa2024). This species was also the most dominant in our study, reaching up to a maximum abundance of 12 794 ind. m^-2 in False Bay. Our data showed much higher abundances of this polychaete species than in previous studies on soft bottoms around the South Shetland Islands at depths ranging from 46 to 694 m (e.g. Jażdżeski et al. Reference Jażdżeski, Jurasz, Kittel, Presler, Presler and Siciński1986, Sáiz-Salinas et al. Reference Sáiz-Salinas, Ramos, García, Troncoso, San Martín, Sanz and Palacin1997). On the contrary, although the total polychaete assemblage is richer and more abundant at the shallower and volcanic-influenced habitat of Deception Island, this particular species is completely absent (Angulo-Preckler et al. Reference Angulo-Preckler, Leiva, Avila and Taboada2017b, Reference Angulo-Preckler, Figuerola, Núñez-Pons, Moles, Martín-Martín and Rull-Lluch2018). These findings suggest that the exceptionally high densities observed in False Bay reflect a combination of favourable food availability and stable benthic conditions that support deposit-feeding species while limiting the presence of suspension feeders. Additionally, recent research indicates that the energy content of this species is lower in areas near melting glaciers compared to more distant sites (Cataldo-Mendez et al. Reference Cataldo-Mendez, Brante and Urzúa2024). These findings collectively suggest that M. sarsi antarctica is a keystone species in Antarctic soft-bottom ecosystems, and further research on the species is essential for predicting how such marine assemblages might respond to global change.

Maldane sarsi antarctica has a circum-Antarctic distribution, probably influenced by oceanographic, ecological and evolutionary factors (Fig. S1). As a sedentary polychaete adapted to cold waters, its dispersal is driven by Antarctic marine currents that facilitate genetic connectivity and larval transport (Rogers Reference Rogers2007, Thatje Reference Thatje2012, Güller et al. Reference Güller, Puccinelli and Zelaya2020, Muñoz-Ramírez et al. Reference Muñoz-Ramírez, Barnes, Cárdenas, Meredith, Morley and Roman-Gonzalez2020). Their trochophore larva, with its high dispersal potential, plays a key role in this process (De Assis et al. Reference De Assis, Bleidorn, Crhistoffersen, Purschke, Westheide and Böggemann2021). Furthermore, the abundance of soft-bottom habitats in Antarctica provides an ideal environment in which maldanids can build tubes, supporting their ecological success (Pan & Pratolongo Reference Pan, Pratolongo, Pan and Pratolongo2022). Its wide distribution also suggests its persistence in glacial refugia, with evolutionary and plastic adaptations, such as cold and depth tolerance, enabling its survival through environmental changes (Thatje et al. Reference Thatje, Hillenbrand and Larter2005, Hoffmann & Sgrò Reference Hoffmann and Sgrò2011, Munday et al. Reference Munday, Warner, Monro, Pandolfi and Marshall2013). These characteristics, combined with the fact that the size-frequency histogram of this population displays a normal distribution with a central peak, suggest a stable and undisturbed population with balanced recruitment and mortality rates (Fig. S2).

Limitations of the study and future perspectives

The present study was conducted at two stations within a specific Antarctic fjord based on a limited sampling scope that did not allow for statistically representative spatial comparisons to be made within the bay. Despite this clear limitation, our study offers a comprehensive biological and ecological characterization of marine assemblages in a relatively underexplored region, establishing an important baseline for future research. These preliminary findings are significant for understanding the structure and functioning of the ecosystem and may also be useful in the development of conservation strategies for this region. Further studies should analyse the composition of the assemblages along the fjord after species begin to colonize the ice-free seabed following glacier retreat (Grange & Smith Reference Grange and Smith2013, Sahade et al. Reference Sahade, Lagger, Torre, Momo, Monien and Schloss2015, Lagger et al. Reference Lagger, Servetto, Torre and Sahade2017). It is important to note that although Huntress Glacier is not retreating as fast as other glaciers in the region (e.g. Cook et al. Reference Cook, Holland, Meredith, Murray, Luckman and Vaughan2016), studying such changes is key. In addition, it would be interesting to relate these biological variables with environmental data (e.g. chlorophyll-a, sediment grain size, temperature) to obtain a more holistic view of this ecosystem. These kinds of studies are also useful for improving our understanding of how fjords are becoming pivotal ‘blue carbon’ ecosystems in terms of negative feedback for climate change by sequestering and storing organic carbon in new ice-free habitats (Barnes et al. Reference Barnes, Sands, Cook, Howard, Roman Gonzalez and Muñoz–Ramirez2020, Zwerschke et al. Reference Zwerschke, Sands, Roman-Gonzalez, Barnes, Guzzi and Jenkins2022).

Several limitations were encountered when searching for biological and ecological data regarding M. sarsi antarctica in the literature. First, data on abundances and specimen sizes were not always provided (most of the available records do not provide species-specific quantitative information). This is because abundance data for M. sarsi antarctica were mainly reported collectively, grouping this species with other, different species from benthic assemblages of Polychaeta, while specimen size data were often completely absent. This limitation highlights the need for more specific quantitative studies on Antarctic fauna. Second, although 186 records of M. sarsi antarctica were found across the Southern Ocean (Fig. S1 & Data S1), some previous studies have identified this species as the parent species Maldane sarsi Malmgren, Reference Malmgren1865 (e.g. Drennan et al. Reference Drennan, Dahlgren, Linse and Glover2021), without specifically mentioning the subspecies M. sarsi antarctica. This is probably due to the fact that the subspecies’ diagnostic characteristics (colour and gland patterns) are not always considered robust taxonomic traits (Wang & Li Reference Wang and Li2016). Though recent studies, including Brasier et al. (Reference Brasier, Wiklund, Neal, Jeffreys, Linse, Ruhl and Glover2016), have suggested that the genetic differences and long geographical distances between Antarctic populations and the type locality of M. sarsi raise questions about the status of M. sarsi antarctica as a subspecies, being more likely a valid species on its own. Thus, although these records as M. sarsi were not considered in our analysis, they probably correspond to the same Antarctic subspecies here discussed. This issue highlights a gap in the current literature and in accurately identifying Antarctic M. sarsi, emphasizing the urgent need for further taxonomic clarification.

Conclusions

Our findings provide the first description of the benthic marine fauna from False Bay (Livingston Island, South Shetland Islands, Antarctica), revealing an assemblage dominated by infaunal, deposit-feeding polychaetes. In particular, False Bay is a paradise for the circum-Antarctic-distributed polychaete M. sarsi antarctica, which appears to have a stable and undisturbed population. Our data highlight the importance of exploring poorly studied areas to improve our knowledge of Antarctic biodiversity. Moreover, as many factors are currently threatening polar ecosystems, our results are key to establishing a baseline for assessing future changes in benthic assemblages, especially those related to global change and other human impacts.

Supplementary material

To view supplementary material for this article, please visit http://doi.org/10.1017/S0954102025000185.

Acknowledgements

We appreciate the contributions of all members involved in the CHALLENGE project and their assistance in sample collection and sorting during the Antarctic campaign. We thank the R/V BIO-Hespérides crew for their support during the cruise. We also thank the taxonomic specialists Dr David Barnes (Bryozoa), Dr Anna Soler (Pycnogonida), Dr Katrin Linse (Bivalvia), Dr Chester Sands (Ophiuroidea), Dr Camille Moureau (Asteroidea), Dr Anna Jażdżewska (Amphipoda), Dr Stephanie Kaiser (Isopoda), Dr Sebastián Rosenfeld (Gastropoda) and Dr José-Ignacio Sáiz-Salinas (Priapulida) for their contributions to the identification and classification of the marine fauna. This study is a contribution to the ‘Integrated Science to inform Antarctic and Southern Ocean Conservation’ (Ant-ICON) research programme supported by the Scientific Committee on Antarctic Research (SCAR). We also wish to thank the reviewers of the manuscript for their very helpful comments and suggestions.

Competing interests

The authors declare none.

Author contributions

MB and CA conceptualized and designed the study; MB, AP, MG-P, PM-R, TA-G, AA-M, GM-V, YT, EB and CA were responsible for sample collection; MB, AP, MG-P, PM-R, TA-G, AA-M, MdL and JG conducted the laboratory analyses and bioinformatic analyses; MB and AP processed, interpreted and discussed the results; MG-P performed the data visualization; CA supervised the study and secured the funding; MB and AP drafted the initial manuscript with contributions from all of the authors to the final version.

Financial support

This work was supported by the CHALLENGE (PID2019-107979RB-100 funded by MICIU/AEI/10.13039/501100011033) and CHALLENGE-2 (PID2022-141628NB-I00 funded by MICIU/AEI/10.13039/501100011033) research grants from the Spanish Government and by European Regional Development Fund (ERDF-EU). The ‘Marine Biodiversity and Evolution’ SGR (Research Quality Group) funding of the Generalitat de Catalunya (MBE; 2021SGR01271) also supported this work. MB acknowledges financial support from Agencia Nacional de Investigacion y Desarrollo (ANID), Becas Chile para Doctorado en el extranjero 72220140. AP acknowledges financial support from an FPI Grant (PRE2019-091200) funded by MICIU/AEI/10.13039/501100011033 and by ‘ESF Investing in your future’. MG-P acknowledges financial support from a FI-SDUR 2021 fellowship from the Departament de Recerca i Universitats of the Catalan Government (Generalitat de Catalunya). PM-R acknowledges financial support from PREDOCS-UB. TA-G acknowledges financial support from a Severo Ochoa FPI Grant PRE2020-096185 funded by MCIN/AEI/10.13039/501100011033 and by ‘ESF Investing in your future’. AA-M acknowledges funding from the CHALLENGE project during this work. JG was funded by an ongoing collaborative protocol signed with CRÉOCÉAN (France).

Footnotes

†

These authors have contributed equally to this work

References

Ahn, I.Y. & Kang, Y.C. 1991. Preliminary study on the macrobenthic community of Maxwell Bay, South Shetland Islands, Antarctica. Korean Journal of Polar Research, 2, 61–71.Google Scholar

Altafim, G.L., Alves, A.V., Trevizani, T.H., Figueira, R.C.L., Gallucci, F. & Choueri, R.B. 2023. Ocean warming and CO₂-driven acidification can alter the toxicity of metal-contaminated sediments to the meiofauna community. Science of the Total Environment, 885, 10.1016/j.scitotenv.2023.163687.10.1016/j.scitotenv.2023.163687CrossRef Google Scholar

Andrew, N. & Mapstone, B. 1987. Sampling and the description of spatial pattern in marine ecology. Oceanography and Marine Biology: Annual Review, 25, 39–90.Google Scholar

Angulo-Preckler, C., Tuya, F. & Avila, C. 2017a. Abundance and size patterns of echinoderms in coastal soft-bottoms at Deception Island (South Shetland Islands, Antarctica). Continental Shelf Research, 137, 10.1016/j.csr.2016.12.010.10.1016/j.csr.2016.12.010CrossRef Google Scholar

Angulo-Preckler, C., Leiva, C., Avila, C. & Taboada, S. 2017b. Macroinvertebrate communities from the shallow soft-bottoms of Deception Island (Southern Ocean): a paradise for opportunists. Marine Environmental Research, 127, 10.1016/j.marenvres.2017.03.008.10.1016/j.marenvres.2017.03.008CrossRef Google Scholar

Angulo-Preckler, C., Figuerola, B., Núñez-Pons, L., Moles, J., Martín-Martín, R., Rull-Lluch, J., et al. 2018. Macrobenthic patterns at the shallow marine waters in the caldera of the active volcano of Deception Island, Antarctica. Continental Shelf Research, 157, 10.1016/j.csr.2018.02.005.10.1016/j.csr.2018.02.005CrossRef Google Scholar

Arnaud, P.M., López, C.M., Olaso, I., Ramil, F., Ramos-Esplá, A.A. & Ramos, A. 1998. Semi-quantitative study of macrobenthic fauna in the region of the South Shetland Islands and the Antarctic Peninsula. Polar Biology, 19, 10.1007/s003000050229.10.1007/s003000050229CrossRef Google Scholar

Aronson, R.B. & Blake, D.B. 2001. Global climate change and the origin of modern benthic communities in Antarctica. American Zoologist, 41, 27–39.Google Scholar

Arwidsson, I. 1911. Die Maldaniden. Wissenschaftliche Ergebnisse der Schwedischen Südpolar Expedition 1901–1903. Stockholm, 44 pp.Google Scholar

Barnes, D.K.A. & Clarke, A. 2011. Antarctic marine biology. Current Biology, 21, 10.1016/j.cub.2011.04.012.10.1016/j.cub.2011.04.012CrossRef Google Scholar PubMed

Barnes, D.K.A. & Sands, C.J. 2017. Functional group diversity is key to Southern Ocean benthic carbon pathways. PLoS ONE, 12, 10.1371/journal.pone.0179735.10.1371/journal.pone.0179735CrossRef Google Scholar PubMed

Barnes, D.K.A., Sands, C.J., Cook, A., Howard, F., Roman Gonzalez, A., Muñoz–Ramirez, C., et al. 2020. Blue carbon gains from glacial retreat along Antarctic fjords: what should we expect? Global Change Biology, 26, 10.1111/gcb.15055.10.1111/gcb.15055CrossRef Google Scholar PubMed

Bolam, S.G. & Fernandes, T.F. 2002. Dense aggregations of tube-building polychaetes: response to small-scale disturbances. Journal of Experimental Marine Biology and Ecology, 269, 10.1016/S0022-0981(02)00003-5.10.1016/S0022-0981(02)00003-5CrossRef Google Scholar

Brasier, M.J., Wiklund, H., Neal, L., Jeffreys, R., Linse, K., Ruhl, H. & Glover, A.G. 2016. DNA barcoding uncovers cryptic diversity in 50% of deep-sea Antarctic polychaetes. Royal Society Open Science, 3, 160432.10.1098/rsos.160432CrossRef Google Scholar PubMed

Brierley, A.S. & Kingsford, M.J. 2009. Impacts of climate change on marine organisms and ecosystems. Current Biology, 19, 10.1016/j.cub.2009.05.046.10.1016/j.cub.2009.05.046CrossRef Google Scholar PubMed

Brueggeman, P. 1998. Underwater field guide to Ross Island & McMurdo Sound, Antarctica. San Diego, CA: The National Science Foundation's Office of Polar Progams.Google Scholar

Cantone, G. 1995. Polychaeta ‘Sedentaria’ of Terra Nova Bay (Ross Sea, Antarctica): Capitellidae to Serpulidae. Polar Biology, 15, 10.1007/BF00239851.10.1007/BF00239851CrossRef Google Scholar

Cataldo-Mendez, C., Brante, A. & Urzúa, Á. 2024. The impact of glacial meltwater on the integrated bioenergetic condition of two key Antarctic benthic polychaetes (Maldane sarsi antarctica, Notomastus latericeus). Regional Studies in Marine Science, 73, 10.1016/j.rsma.2024.103493.10.1016/j.rsma.2024.103493CrossRef Google Scholar

Clarke, A. & Crame, A. 2010. Evolutionary dynamics at high latitudes: speciation and extinction in polar marine faunas. Philosophical Transactions of the Royal Society of London . Series B, Biological sciences, 365, 10.1098/rstb.2010.0270. Google Scholar

Clarke, A., Aonson, R.B., Crame, J.A.,Gili, J.-M. & Blake, D.B. 2004. Evolution and diversity of the benthic fauna of the Southern Ocean continental shelf. Antarctic Science, 16, 10.1017/S0954102004002329.Google Scholar

Convey, P., Chown, S.L., Clarke, A., Barnes, D.K., Bokhorst, S., Cummings, V., et al. 2014. The spatial structure of Antarctic biodiversity. Ecological Monographs, 84, 10.1890/12-2216.1.10.1890/12-2216.1CrossRef Google Scholar

Cook, A.J., Fox, A. & Thomson, J. 2021. Coastal change data for the Antarctic Peninsula region, 1843 to 2008. 2 files, 37 MB. 10.5285/07727663-9B94-4069-A486-67E4D82177D3.Google Scholar

Cook, A.J., Holland, P.R., Meredith, M.P., Murray, T., Luckman, A. & Vaughan, D.G. 2016. Ocean forcing of glacier retreat in the western Antarctic Peninsula. Science, 353, 10.1126/science.aae0017.10.1126/science.aae0017CrossRef Google Scholar PubMed

Cosson, N., Sibuet, M. & Galeron, J. 1997. Community structure and spatial heterogeneity of the deep-sea macrofauna at three contrasting stations in the tropical northeast Atlantic. Deep Sea Research I - Oceanographic Research Papers, 44, 10.1016/S0967-0637(96)00110-0.Google Scholar

Crespo, D. & Pardal, M.Â. 2020. Ecological and economic importance of benthic communities. In Leal Filho, W., Azul, A.M., Brandli, L., Lange Salvia, A. & Wall, T., eds, Life below water. Encyclopedia of the UN Sustainable Development Goals. Cham: Springer International Publishing, 10.1007/978-3-319-71064-8_5-1.Google Scholar

Davison, B.J., Hogg, A.E., Gourmelen, N., Jakob, L., Wuite, J., Nagler, T., et al. 2023. Annual mass budget of Antarctic ice shelves from 1997 to 2021. Science Advances, 9, 10.1126/sciadv.adi0186.10.1126/sciadv.adi0186CrossRef Google Scholar PubMed

Day, J.H. 1967. A monograph on the Polychaeta of Southern Africa. Part 2. Sedentaria. London: British Museum (Natural History), 459–878 pp.Google Scholar

Dayton, P., Robilliard, G., Paine, R. & Dayton, L. 1975. Biological accommodation in the benthic community at McMurdo Sound, Antarctica. Ecological Monographs, 44, 10.2307/1942321.Google Scholar

De Assis, J.E. & Christoffersen, M.L. 2011. Phylogenetic relationships within Maldanidae (Capitellida, Annelida), based on morphological characters. Systematics and Biodiversity, 9, 10.1080/14772000.2011.604358.10.1080/14772000.2011.604358CrossRef Google Scholar

De Assis, J.E., Alonso, C. & Christoffersen, M.L. 2007. A catalogue and taxonomic keys of the subfamily Nicomachinae (Polychaeta: Maldanidae) of the world. Zootaxa, 1657, 41–55.10.11646/zootaxa.1657.1.3CrossRef Google Scholar

De Assis, J.E., Bleidorn, C. & Crhistoffersen, M.L. 2021. Maldanidae . In Purschke, G., Westheide, W. & Böggemann, M., eds, Handbook of zoology. Annelida, Volume 3 : Sedentaria III, Errantia I. Berlin/Boston, MA: De Gruyter, 186–201.Google Scholar

Drennan, R., Dahlgren, T.G., Linse, K. & Glover, A.G. 2021. Annelid fauna of the Prince Gustav Channel, a previously ice-covered seaway on the northeastern Antarctic Peninsula. Frontiers in Marine Science, 7, 10.3389/fmars.2020.595303.10.3389/fmars.2020.595303CrossRef Google Scholar

Ducklow, H., Fraser, W., Meredith, M., Stammerjohn, S., Doney, S., Martinson, D., et al. 2013. West Antarctic Peninsula: an ice-dependent coastal marine ecosystem in transition. Oceanography, 26, 10.5670/oceanog.2013.62.10.5670/oceanog.2013.62CrossRef Google Scholar

Dufour, S., White, C., Desrosiers, G. & Juniper, S. 2008. Structure and composition of the consolidated mud tube of Maldane sarsi (Polychaeta: Maldanidae). Estuarine, Coastal and Shelf Science, 78, 10.1016/j.ecss.2007.12.013.10.1016/j.ecss.2007.12.013CrossRef Google Scholar

Dunlop, K., Harendza, A., Plassen, L. & Keeley, N. 2020. Epifaunal habitat associations on mixed and hard bottom substrates in coastal waters of northern Norway. Frontiers in Marine Science, 7, 10.3389/fmars.2020.568802.10.3389/fmars.2020.568802CrossRef Google Scholar

Ellingsen, K. 2001. Biodiversity of a continental shelf soft-sediment macrobenthos community. Marine Ecology Progress Series, 218, 10.3354/meps218001.10.3354/meps218001CrossRef Google Scholar

Ellingsen, K. & Gray, J.S. 2002. Spatial patterns of benthic diversity: is there a latitudinal gradient along the Norwegian continental shelf? Journal of Animal Ecology, 71, 10.1046/j.1365-2656.2002.00606.x.10.1046/j.1365-2656.2002.00606.xCrossRef Google Scholar

Engl, W. 2012. Shells of Antarctica. Hackenheim: Conchbooks, 402 pp.Google Scholar

Fauchald, K. & Jumars, P. 1979. The diet of worms: a study of polychaete feeding guilds. Oceaonography and Marine Biology, 17, 193–284.Google Scholar

Freedman, D. & Diaconis, P. 1981. On the histogram as a density estimator: L₂ theory. Zeitschrift für Wahrscheinlichkeitstheorie und verwandte Gebiete, 57, 10.1007/BF01025868.10.1007/BF01025868CrossRef Google Scholar

Garraffoni, A.R., Moura, F.R., Vasconcelos, P.E., Araújo, F.F. & Passos, F.D. 2012. Levantamento de polychaeta (Annelida) na Baía do Almirantado, Ilha Rei George (Antártica). Papéis Avulsos de Zoologia, 52, 10.1590/S0031-10492012001300001.10.1590/S0031-10492012001300001CrossRef Google Scholar

Giangrande, A., Gambi, M.C. & Gravina, M.F. 2020. Polychaetes as habitat former: structure and function. In Rossi, S. & Bramanti, L., eds, Perspectives on the marine animal forests of the world. Cham: Springer International Publishing, 10.1007/978-3-030-57054-5_8.Google Scholar

Gissi, E., Manea, E., Mazaris, A.D., Fraschetti, S., Almpanidou, V., Bevilacqua, S., et al. 2021. A review of the combined effects of climate change and other local human stressors on the marine environment. Science of the Total Environment, 755, 10.1016/j.scitotenv.2020.142564.10.1016/j.scitotenv.2020.142564CrossRef Google Scholar PubMed

Glover, A.G., Smith, C.R., Mincks, S.L., Sumida, P.Y.G. & Thurber, A.R. 2008. Macrofaunal abundance and composition on the West Antarctic Peninsula continental shelf: evidence for a sediment ‘food bank’ and similarities to deep-sea habitats. Deep Sea Research II - Topical Studies in Oceanography, 55, 10.1016/j.dsr2.2008.06.008.Google Scholar

Grange, L.J. & Smith, C.R. 2013. Megafaunal communities in rapidly warming fjords along the West Antarctic Peninsula: hotspots of abundance and Beta diversity. PLoS ONE, 8, 10.1371/journal.pone.0077917.10.1371/journal.pone.0077917CrossRef Google Scholar PubMed

Gray, J. 2002. Species richness of marine soft sediments. Marine Ecology Progress Series, 244, 10.3354/meps244285.10.3354/meps244285CrossRef Google Scholar

Grimes, C.J., Donnelly, K., Ka, C., Noor, N., Mahon, A.R. & Halanych, K.M. 2023. Community structure along the Western Antarctic continental shelf and a latitudinal change in epibenthic faunal abundance assessed by photographic surveys. Frontiers in Marine Science, 10, 10.3389/fmars.2023.1094283.10.3389/fmars.2023.1094283CrossRef Google Scholar

Güller, M., Puccinelli, E. & Zelaya, D.G. 2020. The Antarctic Circumpolar Current as a dispersive agent in the Southern Ocean: evidence from bivalves. Marine Biology, 167, 10.1007/s00227-020-03746-2.10.1007/s00227-020-03746-2CrossRef Google Scholar

Gutt, J. 2007. Antarctic macro-zoobenthic communities: a review and an ecological classification. Antarctic Science, 19, 10.1017/S0954102007000247.10.1017/S0954102007000247CrossRef Google Scholar

Gutt, J., Arndt, J., Kraan, C., Dorschel, B., Schröder, M., Bracher, A. & Piepenburg, D. 2019. Benthic communities and their drivers: a spatial analysis off the Antarctic Peninsula. Limnology and Oceanography, 64, 10.1002/lno.11187.10.1002/lno.11187CrossRef Google Scholar

Gutt, J., Barratt, I., Domack, E., d'Acoz, C., Dimmler, W., Grémare, A., et al. 2011. Biodiversity change after climate-induced ice-shelf collapse in the Antarctic. Deep Sea Research II - Topical Studies in Oceanography, 58, 10.1016/j.dsr2.2010.05.024.Google Scholar

Henley, S.F., Schofield, O.M., Hendry, K.R., Schloss, I.R., Steinberg, D.K., Moffat, C., et al. 2019. Variability and change in the West Antarctic Peninsula marine system: research priorities and opportunities. Progress in Oceanography, 173, 10.1016/j.pocean.2019.03.003.10.1016/j.pocean.2019.03.003CrossRef Google Scholar

Hoffmann, A.A. & Sgrò, C.M. 2011. Climate change and evolutionary adaptation. Nature, 470, 10.1038/nature09670.10.1038/nature09670CrossRef Google Scholar PubMed

Hutchings, P. 1998. Biodiversity and functioning of polychaetes in benthic sediments. Biodiversity and Conservation, 7, 10.1023/A:1008871430178.10.1023/A:1008871430178CrossRef Google Scholar

Hutchings, P., Ward, T., Waterhouse, J. & Walker, L. 1993. Infauna of marine sediments and seagrass beds of Upper Spencer Gulf near Port Pirie, South Australia. Transactions of the Royal Society of South Australia, 117, 1–14.Google Scholar

IPCC. 2023. Climate change 2023: synthesis report . Contribution of Working Groups I, II and III to the Sixth Assessment Report of the Intergovernmental Panel on Climate Change [Core Writing Team, Lee and, H. Romero, J. (eds.)]. Geneva: Intergovernmental Panel on Climate Change, 10.59327/IPCC/AR6-9789291691647.Google Scholar

Jażdżeski, K., Jurasz, W., Kittel, W., Presler, E., Presler, P. & Siciński, J. 1986. Abundance and biomass estimates of the benthic fauna in Admiralty Bay, King George Island, South Shetland Islands. Polar Biology, 6, 10.1007/BF00446235.10.1007/BF00446235CrossRef Google Scholar

Jiménez-Cueto, M.S. & Salazar-Vallejo, S.I. 1997. Maldánidos (Polychaeta) del Caribe Mexicano con una clave para las especies del Gran Caribe. Revista de Biología Tropical, 45, 1459–1480.Google Scholar

Jumars, P.A., Dorgan, K.M. & Lindsay, S.M. 2015. Diet of worms emended: an update of Polychaete feeding guilds. Annual Review of Marine Science, 7, 10.1146/annurev-marine-010814-020007.10.1146/annurev-marine-010814-020007CrossRef Google Scholar PubMed

Kendall, M., Widdicombe, S. & Weslawski, J. 2003. A multi-scale study of the biodiversity of the benthic infauna of the high-latitude Kongsfjord, Svalbard. Polar Biology, 26, 10.1007/s00300-003-0496-x.10.1007/s00300-003-0496-xCrossRef Google Scholar

Knox, G. 1977. The role of polychaetes in benthic soft-bottom communities. In Reish, D.J. & Fauchald, K., eds, Essays on polychaetous annelids in memory of Dr. Olga Hartman. Los Angeles, CA: University of Southern California, Allan Hancock Press, 547–604.Google Scholar

Kongsrud, J.A. & Rapp, H.T. 2012. Nicomache (Loxochona) lokii sp. nov. (Annelida: Polychaeta: Maldanidae) from the Loki’s Castle vent field: an important structure builder in an Arctic vent system. Polar Biology, 35, 10.1007/s00300-011-1048-4.10.1007/s00300-011-1048-4CrossRef Google Scholar

Kristensen, E., Penha-Lopes, G., Delefosse, M., Valdemarsen, T., Organo Quintana, C. & Banta, G. 2012. What is bioturbation? Need for a precise definition for fauna in aquatic science. Marine Ecology Progress Series, 446, 10.3354/meps09506.10.3354/meps09506CrossRef Google Scholar

Lagger, C., Servetto, N., Torre, L. & Sahade, R. 2017. Benthic colonization in newly ice-free soft-bottom areas in an Antarctic fjord. PLoS ONE, 12, e0186756.10.1371/journal.pone.0186756CrossRef Google Scholar

Learman, D.R., Henson, M.W., Thrash, J.C., Temperton, B., Brannock, P.M., Santos, S.R., et al. 2016. Biogeochemical and microbial variation across 5500 km of Antarctic surface sediment implicates organic matter as a driver of benthic community structure. Frontiers in Microbiology, 7, 284.10.3389/fmicb.2016.00284CrossRef Google Scholar PubMed

Levin, L.A., Blair, N.E., DeMaster, D.J., Plaia, G.R., Fornes, W.L. , Martin, C. & Thomas, C.L. 1997. Rapid subduction of organic matter by maldanid polychaetes on the North Carolina slope. Journal of Marine Research, 55, 595–611.10.1357/0022240973224337CrossRef Google Scholar

Lohrer, D. & Hancock, N. 2004. Marine soft sediments: more diversity than meets the eye. Water and Atmosphere, 12, 26–27.Google Scholar

Macdonald, T., Burd, B. & Van Roodselaar, A. 2012. Facultative feeding and consistency of trophic structure in marine soft-bottom macrobenthic communities. Marine Ecology Progress Series, 445, 10.3354/meps09478.10.3354/meps09478CrossRef Google Scholar

Malmgren, A.J. 1865. Nordiska Hafs-Annulater. Öfversigt af Königlich Vetenskapsakademiens förhandlingar, 22, 181–192.Google Scholar

Martins, R., Quintino, V. & Rodrigues, A. 2013. Diversity and spatial distribution patterns of the soft-bottom macrofauna communities on the Portuguese continental shelf. Journal of Sea Research, 83, 173–186.10.1016/j.seares.2013.03.001CrossRef Google Scholar

Meadows, P.S., Meadows, A. & Murray, J.M.H. 2012. Biological modifiers of marine benthic seascapes: their role as ecosystem engineers. Geomorphology, 157 – 158, 10.1016/j.geomorph.2011.07.007.Google Scholar

Mermillod-Blondin, F. 2011. The functional significance of bioturbation and biodeposition on biogeochemical processes at the water–sediment interface in freshwater and marine ecosystems. Journal of the North American Benthological Society, 30, 10.1899/10-121.1.10.1899/10-121.1CrossRef Google Scholar

Mincks, S.L., Smith, C.R., Jeffreys, R.M. & Sumida, P.Y.G. 2008. Trophic structure on the West Antarctic Peninsula shelf: detritivory and benthic inertia revealed by δ¹³C and δ¹⁵N analysis. Deep Sea Research II - Topical Studies in Oceanography, 55, 10.1016/j.dsr2.2008.06.009.Google Scholar

Mohd Nasir, N., Barnes, D. & Wan Hussin, W.M.R. 2024. Benthic functionality under climate-induced environment changes offshore on the Antarctic Peninsula continental shelf. Marine Environmental Research, 194, 10.1016/j.marenvres.2024.106341.10.1016/j.marenvres.2024.106341CrossRef Google Scholar PubMed

Munday, P.L., Warner, R.R., Monro, K., Pandolfi, J.M. & Marshall, D.J. 2013. Predicting evolutionary responses to climate change in the sea. Ecology Letters, 16, 10.1111/ele.12185.10.1111/ele.12185CrossRef Google Scholar PubMed

Muñoz-Ramírez, C.P., Barnes, D.K., Cárdenas, L., Meredith, M.P., Morley, S.A., Roman-Gonzalez, A., et al. 2020. Gene flow in the Antarctic bivalve Aequiyoldia eightsii (Jay, 1839) suggests a role for the Antarctic Peninsula Coastal Current in larval dispersal. Royal Society Open Science, 7, 10.1098/rsos.200603.10.1098/rsos.200603CrossRef Google Scholar PubMed

Noble, T.L., Rohling, E.J., Aitken, A.R.A., Bostock, H.C., Chase, Z., Gomez, N., et al. 2020. The sensitivity of the Antarctic ice sheet to a changing climate: past, present, and future. Reviews of Geophysics, 58, 10.1146/annurev-marine-040323-074354.10.1029/2019RG000663CrossRef Google Scholar

Orsi, A.H., Whitworth, T. & Nowlin, W.D. 1995. On the meridional extent and fronts of the Antarctic Circumpolar Current. Deep Sea Research I - Oceanographic Research Papers, 42, 10.1016/0967-0637(95)00021-W.Google Scholar

Ortiz, M., Hermosillo-Nuñez, B., González, J., Rodríguez-Zaragoza, F., Gómez, I. & Jordán, F. 2017. Quantifying keystone species complexes: ecosystem-based conservation management in the King George Island (Antarctic Peninsula). Ecological Indicators, 81, 10.1016/j.ecolind.2017.06.016.10.1016/j.ecolind.2017.06.016CrossRef Google Scholar

Pabis, K. & Sobczyk, R. 2015. Small-scale spatial variation of soft-bottom polychaete biomass in an Antarctic glacial fjord (Ezcurra Inlet, South Shetlands): comparison of sites at different levels of disturbance. Helgoland Marine Research, 69, 10.1007/s10152-014-0420-5.10.1007/s10152-014-0420-5CrossRef Google Scholar

Pabis, K., Sicinski, J. & Krymarys, M. 2011. Distribution patterns in the biomass of macrozoobenthic communities in Admiralty Bay (King George Island, South Shetlands, Antarctic). Polar Biology, 34, 10.1007/s00300-010-0903-z.10.1007/s00300-010-0903-zCrossRef Google Scholar

Pabis, K., Sicinski, J. & Krymarys, M. 2012. Is polychaete diversity in the deep sublittoral of an Antarctic fiord related to habitat complexity?. Polish Polar Research, 2, 10.2478/v10183-012-0009-0.Google Scholar

Paiva, P.C., Seixas, V.C. & Echeverría, C.A. 2015. Variation of a polychaete community in nearshore soft bottoms of Admiralty Bay, Antarctica, along austral winter (1999) and summer (2000–2001). Polar Biology, 38, 10.1007/s00300-015-1698-8.10.1007/s00300-015-1698-8CrossRef Google Scholar

Pan, J. & Pratolongo, D. 2022. Soft-bottom marine benthos. In Pan, J. & Pratolongo, D., eds, Marine biology: a functional approach to the oceans and their organisms. Boca Raton, FL: CRC Press, 10.1201/9780429399244-10.Google Scholar

Parapar, J., López, E., Gambi, M.C., Núñez, J. & Ramos, A. 2011. Quantitative analysis of soft-bottom polychaetes of the Bellingshausen Sea and Gerlache Strait (Antarctica). Polar Biology, 34, 10.1007/s00300-010-0927-4.10.1007/s00300-010-0927-4CrossRef Google Scholar

Paterson, G.L.J., Glover, A.G., Barrio Froján, C.R.S., Whitaker, A., Budaeva, N., Chimonides, J. & Doner, S. 2009. A census of abyssal polychaetes. Deep Sea Research II - Topical Studies in Oceanography, 56, 10.1016/j.dsr2.2009.05.018.Google Scholar

Pearson, T.H. 2001. Functional group ecology in soft-sediment marine benthos: the role of bioturbation. Oceanography and Marine Biology: An Annual Review, 39, 233–267.Google Scholar

Piepenburg, D. 2005. Recent research on Arctic benthos: common notions need to be revised. Polar Biology, 28, 10.1007/s00300-005-0013-5.10.1007/s00300-005-0013-5CrossRef Google Scholar

Post, E., Alley, R.B., Christensen, T.R., Macias-Fauria, M., Forbes, B.C., Gooseff, M.N., et al. 2019. The polar regions in a 2°C warmer world. Science Advances, 5, 10.1126/sciadv.aaw9883.10.1126/sciadv.aaw9883CrossRef Google Scholar

Pritchard, Hd., Ligtenberg, S.R., Fricker, H.A., Vaughan, D.G., van den Broeke, M.R. & Padman, L. 2012. Antarctic ice-sheet loss driven by basal melting of ice shelves. Nature, 484, 10.1038/nature10968.10.1038/nature10968CrossRef Google Scholar PubMed

Purich, A. & Doddridge, E.W. 2023. Record low Antarctic sea ice coverage indicates a new sea ice state. Communications Earth & Environment, 4, 10.1038/s43247-023-00961-9.10.1038/s43247-023-00961-9CrossRef Google Scholar

Quintanar-Retama, O., Vázquez-Bader, A.R. & Gracia, A. 2023. Macrofauna abundance and diversity patterns of deep sea southwestern Gulf of Mexico. Frontiers in Marine Science, 9, 10.3389/fmars.2022.1033596.10.3389/fmars.2022.1033596CrossRef Google Scholar

Rabaut, M., Guilini, K., Van Hoey, G., Vincx, M. & Degraer, S. 2007. A bio-engineered soft-bottom environment: the impact of Lanice conchilega on the benthic species-specific densities and community structure. Estuarine, Coastal and Shelf Science, 75, 10.1016/j.ecss.2007.05.041.10.1016/j.ecss.2007.05.041CrossRef Google Scholar

Rauschert, M., Arntz, W.E. & Hempel, G. 2015. Antarctic macrobenthos: a field guide of the invertebrates living at the Antarctic seafloor. Wurster Nordseekueste: Arntz & Rauschert Selbstverlag, 143 pp.Google Scholar

Rogers, A.D. 2007. Evolution and biodiversity of Antarctic organisms: a molecular perspective. Philosophical Transactions of the Royal Society B: Biological Sciences, 362, 10.1098/rstb.2006.1948.10.1098/rstb.2006.1948CrossRef Google Scholar PubMed

Rogers, A.D., Frinault, B.A.V., Barnes, D.K.A., Bindoff, N.L., Downie, R., Ducklow, H.W., et al. 2020. Antarctic futures: an assessment of climate-driven changes in ecosystem structure, function, and service provisioning in the Southern Ocean. Annual Review of Marine Science, 12, 10.1146/annurev-marine-010419-011028.10.1146/annurev-marine-010419-011028CrossRef Google Scholar PubMed

Rouse, G.W. & Pleijel, F. 2001. Polychaetes. Oxford/New York: Oxford University Press, 354 pp.Google Scholar

Sahade, R., Lagger, C., Torre, L., Momo, F., Monien, P., Schloss, I., et al. 2015. Climate change and glacier retreat drive shifts in an Antarctic benthic ecosystem. Science Advances, 1, 10.1126/sciadv.1500050.10.1126/sciadv.1500050CrossRef Google Scholar

Sáiz-Salinas, J.I., Ramos, A., García, F.J., Troncoso, J.S., San Martín, G., Sanz, C. & Palacin, C. 1997. Quantitative analysis of macrobenthic soft-bottom assemblages in South Shetland waters (Antarctica). Polar Biology, 17, 10.1007/PL00013382.10.1007/PL00013382CrossRef Google Scholar

San Martín, G., Parapar, J., García, F.J. & Redondo, M.S. 2000. Quantitative analysis of soft bottoms infaunal macrobenthic polychaetes from South Shetland Islands (Antarctica). Bulletin of Marine Science, 67, 83–102.Google Scholar

Sanders, H.L., Goudsmit, E.M., Mills, E.L. & Hampson, G.E. 1962. A study of the intertidal fauna of Barnstable Harbor, Massachusetts. Limnology and Oceanography, 7, 10.4319/lo.1962.7.1.0063.10.4319/lo.1962.7.1.0063CrossRef Google Scholar

Sañé, E., Isla, E., Gerdes, D., Montiel, A. & Gili, J.-M. 2012. Benthic macrofauna assemblages and biochemical properties of sediments in two Antarctic regions differently affected by climate change. Continental Shelf Research, 35, 10.1016/j.csr.2011.12.008.10.1016/j.csr.2011.12.008CrossRef Google Scholar

Sardá, R., Martin, D., Pinedo, S., Dueso, A. & Cardell, M.J. 1995. Seasonal dynamics of shallow soft-bottom communities in western Mediterranean. In Eleftheriou, A., Ansell, A.D. & Smith, C.J., eds, The biology and ecology of shallow coastal waters. Fredensborg: Olsen & Olsen, 191–198.Google Scholar

Schratzberger, M. & Ingels, J. 2018. Meiofauna matters: the roles of meiofauna in benthic ecosystems. Journal of Experimental Marine Biology and Ecology, 502, 10.1016/j.jembe.2017.01.007.10.1016/j.jembe.2017.01.007CrossRef Google Scholar

Sebens, K.P. 1991. Habitat structure and community dynamics in marine benthic systems. In Bell, S.S., McCoy, E.D. & Mushinsky, H.R., eds, Habitat structure. Population and Community Biology Series, vol. 8. Dordrecht: Springer, 211–234.10.1007/978-94-011-3076-9_11CrossRef Google Scholar

Siciński, J. 1986. Benthic assemblages of Polychaeta in chosen regions of the Admiralty Bay (King George Island, South Shetland Islands). Polish Polar Research, 7, 63–78.Google Scholar

Siciński, J. 2000. Polychaeta (Annelida) of Admiralty Bay: species richness, diversity, and abundance. Polish Polar Research, 21, 153–169.Google Scholar

Siciński, J., Jażdżewski, K., Broyer, C.D., Presler, P., Ligowski, R., Nonato, E.F., et al. 2011. Admiralty Bay benthos diversity - a census of a complex polar ecosystem. Deep Sea Research II - Topical Studies in Oceanography, 58, 10.1016/j.dsr2.2010.09.005.Google Scholar

Smith, C., DeMaster, D., Thomas, C., Srsen, P., Grange, L., Evrard, V. & DeLeo, F. 2012. Pelagic-benthic coupling, food banks, and climate change on the West Antarctic Peninsula shelf. Oceanography, 25, 10.5670/oceanog.2012.94.10.5670/oceanog.2012.94CrossRef Google Scholar

Smith, S.D.A. 2000. Evaluating stress in rocky shore and shallow reef habitats using the macrofauna of kelp holdfasts. Journal of Aquatic Ecosystem Stress and Recovery, 7, 10.1023/A:1009993611262.10.1023/A:1009993611262CrossRef Google Scholar

Snelgrove, P.V.R. 1999. Getting to the bottom of marine biodiversity: sedimentary habitats. BioScience, 49, 10.2307/1313538.10.2307/1313538CrossRef Google Scholar

Snelgrove, P.V.R. 1998. The biodiversity of macrofaunal organisms in marine sediments. Biodiversity and Conservation, 7, 10.1023/A:1008867313340.10.1023/A:1008867313340CrossRef Google Scholar

Snelgrove, P., Blackburn, T.H., Hutchings, P., Alongi, D.M., Grassle, J.F., Hummel, H., et al. 1997. The importance of marine sediment biodiversity in ecosystem processes. Ambio, 26, 578–583.Google Scholar

Soto, E., Quiroga, E., Ganga, B. & Alarcón, G. 2017. Influence of organic matter inputs and grain size on soft-bottom macrobenthic biodiversity in the upwelling ecosystem of central Chile. Marine Biodiversity, 47, 10.1007/s12526-016-0479-0.10.1007/s12526-016-0479-0CrossRef Google Scholar

Souster, T.A., Barnes, D.K., Primicerio, R. & Jørgensen, L.L. 2024. Quantifying zoobenthic blue carbon storage across habitats within the Arctic’s Barents Sea. Frontiers in Marine Science, 10, 10.3389/fmars.2023.1260884.10.3389/fmars.2023.1260884CrossRef Google Scholar

Thatje, S. 2012. Effects of capability for dispersal on the evolution of diversity in Antarctic benthos. Integrative & Comparative Biology, 52, 10.1093/icb/ics105.10.1093/icb/ics105CrossRef Google Scholar PubMed

Thatje, S., Hillenbrand, C.-D. & Larter, R. 2005. On the origin of Antarctic marine benthic community structure. Trends in Ecology & Evolution, 20, 10.1016/j.tree.2005.07.010.10.1016/j.tree.2005.07.010CrossRef Google Scholar PubMed

Valdivia, N., Garrido, I., Bruning, P., Piñones, A. & Pardo, L.M. 2020. Biodiversity of an Antarctic rocky subtidal community and its relationship with glacier meltdown processes. Marine Environmental Research, 159, 10.1016/j.marenvres.2020.104991.10.1016/j.marenvres.2020.104991CrossRef Google Scholar PubMed

Valdivia, N., Garcés-Vargas, J., Garrido, I., Gómez, I., Huovinen, P., Navarro, N.P., et al. 2021. Beta diversity of Antarctic and sub-Antarctic benthic communities reveals a major role of stochastic assembly processes. Frontiers in Marine Science, 8, 10.3389/fmars.2021.780268.10.3389/fmars.2021.780268CrossRef Google Scholar

Vause, B.J., Morley, S.A., Fonseca, V.G., Jażdżewska, A., Ashton, G.V., Barnes, D.K.A., et al. 2019. Spatial and temporal dynamics of Antarctic shallow soft-bottom benthic communities: ecological drivers under climate change. BMC Ecology, 19, 10.1186/s12898-019-0244-x.10.1186/s12898-019-0244-xCrossRef Google Scholar PubMed

Vellend, M. 2016. The theory of ecological communities (MPB-57). Princeton, NJ: Princeton University Press, 248 pp.10.1515/9781400883790CrossRef Google Scholar

Vlaminck, E., Moens, T., Braeckman, U. & Van Colen, C. 2023. Ocean acidification and warming modify stimulatory benthos effects on sediment functioning: an experimental study on two ecosystem engineers. Frontiers in Marine Science, 10, 10.3389/fmars.2023.1101972.10.3389/fmars.2023.1101972CrossRef Google Scholar

Waldbusser, G.G., Marinelli, R.L., Whitlatch, R.B. & Visscher, P.T. 2004. The effects of infaunal biodiversity on biogeochemistry of coastal marine sediments. Limnology and Oceanography, 49, 10.4319/lo.2004.49.5.1482.10.4319/lo.2004.49.5.1482CrossRef Google Scholar

Wang, Y. & Li, X. 2016. A new Maldane species and a new Maldaninae genus and species (Maldanidae, Annelida) from coastal waters of China. ZooKeys, 1, 10.3897/zookeys.603.9125.Google Scholar

Williamson, P. & Guinder, V.A. 2021. Effect of climate change on marine ecosystems. In Letcher, T.M., ed., The impacts of climate change. Amsterdam: Elsevier, 10.1016/B978-0-12-822373-4.00024-0.Google Scholar

Xavier, J.C., Cherel, Y., Boxshall, G., Brandt, A., Coffer, T., Forman, J., et al. 2020. Crustacean guide for predator studies in the Southern Ocean. Cambridge: Scientific Committee on Antarctic Research, 253 pp.Google Scholar

Zhulay, I., Iken, K., Renaud, P.E. & Bluhm, B.A. 2019. Epifaunal communities across marine landscapes of the deep Chukchi borderland (Pacific Arctic). Deep Sea Research I - Oceanographic Research Papers, 151, 10.1016/j.dsr.2019.06.011.Google Scholar

Zwerschke, N., Sands, C.J., Roman-Gonzalez, A., Barnes, D.K.A., Guzzi, A., Jenkins, S., et al. 2022. Quantification of blue carbon pathways contributing to negative feedback on climate change following glacier retreat in West Antarctic fjords. Global Change Biology, 28, 10.1111/gcb.15898.10.1111/gcb.15898CrossRef Google Scholar PubMed

Table II. Summary of abundances and biomasses for the main groups and species found in this study. Data extracted from the full Table S1.

Figure 2. Images of the most representative specimens collected during the second expedition of the CHALLENGE project in False Bay (Livingston Island): a. Phoxocephalidae (Amphipoda), b.Aphelochaeta sp. (Polychaeta), c.Natatolana sp. (Isopoda), d.Maldane sarsi antarctica (Polychaeta), e.Thyasira debilis (Bivalvia), f.Nymphon charcoti (Pycnogonida), g.Amphiura cf. joubini (Ophiuroidea) and h.Amphiura sp. (Ophiuroidea). All scale bars = 1 cm, except for e. scale bar = 2 mm.

Figure 7. Relative contribution (%) of all sampled individuals according to their feeding behaviour (left) and physical habitat (right).

Table III. Main taxonomic groups, based on the total abundance, found in previous similar studies from soft-bottom habitats around the world, from low to high latitudes.

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Article contents

A paradise for Maldane sarsi antarctica: preliminary characterization of the marine soft-bottom fauna of False Bay (Livingston Island, South Shetland Islands, Antarctica)

Abstract

Keywords

Information

Introduction

Methods

Study location

Environmental variables

Sample collection and classification

Taxonomic identification and feeding guilds

Distribution and population features of Maldane sarsi antarctica

Results

Environmental variables

Assemblage characteristics

Distribution and population features of Maldane sarsi antarctica

Discussion

Composition of benthic assemblages

Ecological importance of Polychaeta and population features of Maldane sarsi antarctica

Limitations of the study and future perspectives

Conclusions

Supplementary material

Acknowledgements

Competing interests

Author contributions

Financial support

Footnotes

References

Bascur et al. supplementary material

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