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Amphipod diversity and metabolomics of the Antarctic sponge Dendrilla antarctica

Published online by Cambridge University Press:  07 September 2022

Jacqueline L. von Salm
Affiliation:
Department of Chemistry, University of South Florida, Tampa, FL 33620, USA Psilera, Inc., Tampa, FL 33612, USA
Christopher G. Witowski
Affiliation:
Department of Chemistry, University of South Florida, Tampa, FL 33620, USA Psilera, Inc., Tampa, FL 33612, USA
Margaret O. Amsler
Affiliation:
University of Alabama at Birmingham, Department of Biology, Birmingham, AL 35233, USA
Charles D. Amsler
Affiliation:
University of Alabama at Birmingham, Department of Biology, Birmingham, AL 35233, USA
James B. McClintock
Affiliation:
University of Alabama at Birmingham, Department of Biology, Birmingham, AL 35233, USA
Bill J. Baker*
Affiliation:
Department of Chemistry, University of South Florida, Tampa, FL 33620, USA
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Abstract

The western Antarctic Peninsula harbours a diverse benthic marine community where dense canopies of macroalgae can dominate the shallow subtidal zone (0–40 m or greater). In the lower portion of this range (below 25–35 m depending on topography), invertebrates such as sponges and echinoderms can be found in greater abundance due to reduced competition for space from the algal species. Dendrilla antarctica (previously Dendrilla membranosa) is a common demosponge that thrives in both communities and is known for producing diterpene secondary metabolites as a defence against sympatric sea star and amphipod predators. Omnivorous mesograzers such as amphipods inhabit both communities; however, they are in greatest abundance within the macroalgal canopy. Due to the differences between habitats, it was hypothesized that specific amphipod species not susceptible to the defensive metabolites of D. antarctica would take refuge from predators in the chemically defended sponge. Analysis of the metabolome and amphipod communities from sponges in both habitats found correlations of metabolic profile to both abundance and habitat. These studies serve to inform our understanding of the complex ecosystem of the Antarctic benthos that stands to be dramatically altered by the rapidly changing climate in the years to come.

Type
Biological Sciences
Creative Commons
Creative Common License - CCCreative Common License - BY
This is an Open Access article, distributed under the terms of the Creative Commons Attribution licence (http://creativecommons.org/licenses/by/4.0/), which permits unrestricted re-use, distribution and reproduction, provided the original article is properly cited.
Copyright
Copyright © The Author(s), 2022. Published by Cambridge University Press on behalf of Antarctic Science Ltd

Introduction

Antarctic marine invertebrates produce a wide range of secondary metabolites, consistent with the hypothesis that their ecology is driven as much by interspecific interaction as it is by the harsh polar environment (McClintock et al. Reference McClintock, Amsler and Baker2010, von Salm et al. Reference von Salm, Schoenrock, McClintock, Amsler, Baker, Puglisi and Becerro2019). The ecological consequences of secondary metabolites on, for example, predation pressure (Wilson et al. Reference Wilson, Maschek and Baker2013) and spatial variability (Young et al. Reference Young, von Salm, Amsler, Lopez-Bautista, Amsler, McClintock and Baker2013) have been described in recent studies on the western Antarctic Peninsula. Such studies in other systems demonstrate that ecological pressures can transform the metabolism of chemically defended marine organisms including algae (Paul & Vanalstyne Reference Paul and Vanalstyne1988, Van Alstyne Reference Van Alstyne1988, Amade & Lemee Reference Amade and Lemee1998, Matlock et al. Reference Matlock, Ginsburg and Paul1999, Wright et al. Reference Wright, de Nys and Steinberg2000), bryozoans (Mendola Reference Mendola2003, Marti et al. Reference Marti, Uriz and Turon2005), cnidarians (Harvell et al. Reference Harvell, Fenical, Roussis, Ruesink, Griggs and Greene1993, Maida et al. Reference Maida, Carroll and Coll1993, Kelman et al. Reference Kelman, Benayahu and Kashman2000, Slattery et al. Reference Slattery, Starmer and Paul2001), tunicates (Lopez-Legentil et al. Reference Lopez-Legentil, Dieckmann, Bontemps-Sublelos, Turon and Banaigs2005, Marti et al. Reference Marti, Uriz and Turon2005) and sponges (Thompson et al. Reference Thompson, Murphy, Bergquist and Evans1987, Page et al. Reference Page, West, Northcote, Battershill and Kelly2005, Rohde et al. Reference Rohde, Gochfeld, Ankisetty, Avula, Schupp and Slattery2012, Pawlik et al. Reference Pawlik, Loh, McMurray and Finelli2013). For example, transplanting the sponge Rhopaloeides odorabile to various depths and locations on the Great Barrier Reef demonstrated higher diterpene content only in shallow habitats (Thompson et al. Reference Thompson, Murphy, Bergquist and Evans1987). Stylissa massa, a chemically defended Indo-Pacific sponge, exhibited intraspecific chemical diversity due to temporal and spatial criteria, though predation had no influence on secondary metabolite concentrations (Rohde et al. Reference Rohde, Gochfeld, Ankisetty, Avula, Schupp and Slattery2012). The Antarctic sponge Dendrilla antarctica (family Darwinellidae, order Dendroceratida; previously Dendrilla membranosa) is chemically rich and widely distributed on the western Antarctic Peninsula (Shilling et al. Reference Shilling, Witowski, Maschek, Azhari, Vesely and Kyle2020), raising questions regarding how variable amphipod predation pressure might structure the secondary metabolome. Signs of predation towards D. antarctica are rare (Dayton et al. Reference Dayton, Bobilliard, Paine and Dayton1974), and collections from around the continent have afforded multiple diterpenoids (Fig. 1; Molinski & Faulkner Reference Molinski and Faulkner1989, Baker et al. Reference Baker, Kopitzke, Yoshida and McClintock1995, Fontana et al. Reference Fontana, Scognamiglio and Cimino1997, Ankisetty et al. Reference Ankisetty, Amsler, McClintock and Baker2004). Methanolic extracts of D. antarctica containing 1-methyladenine and 3-methyladenine showed tube-foot retraction activity towards the spongivorous sea star Perknaster fuscus (Baker et al. Reference Baker, Kopitzke, Yoshida and McClintock1995), and lipophilic extracts of D. antarctica displayed significant feeding deterrence towards the omnivorous amphipod Gondogeneia antarctica (Amsler et al. Reference Amsler, McClintock, Amsler, Angus and Baker2009). In addition, broad-spectrum antibiotic activity was noted for various membranoids against Staphylococcus aureus, Escherichia coli and Candida albicans (Molinski & Faulkner Reference Molinski and Faulkner1989, Ankisetty et al. Reference Ankisetty, Amsler, McClintock and Baker2004, von Salm et al. Reference von Salm, Witowski, Fleeman, McClintock, Amsler, Shaw and Baker2016, Bory et al. Reference Bory, Shilling, Allen, Azhari, Roth and Shaw2020, Shilling et al. Reference Shilling, Witowski, Maschek, Azhari, Vesely and Kyle2020). The defensive nature of these secondary metabolites constitutes an ecological advantage for D. antarctica and the potential for environmental changes to alter their production to what may be optimal in specific conditions.

Fig. 1. Diterpenes reported from Dendrilla antarctica.

Along the western Antarctic Peninsula, a subtidal macroalgal canopy supports high densities of mesograzers engaged with the algae in a community-wide mutualism of chemical defence, refuge and ecological support services (Jazdzewski et al. Reference Jazdzewski, Teodorczyk, Sicinski and Kontek1991, Kunzmann Reference Kunzmann1996, Amsler et al. Reference Amsler, McClintock and Baker2014). While the macroalgae can extend to 40 m depth and below (Wiencke et al. Reference Wiencke, Amsler, Clayton, Broyer, Koubbi, Griffiths, Raymond, d'Udekem d'Acoz and van de Putte2014), where the underwater topography becomes vertical or near-vertical, below ~25 m macroalgae are lower in abundance, with sessile invertebrates dominating. The western Antarctic Peninsula harbours amphipod mesograzers that can reach densities of 308,000 m2 in near-shore communities and can be significant consumers (Huang et al. Reference Huang, Amsler, McClintock, Amsler and Baker2007, Amsler et al. Reference Amsler, McClintock, Baker and Amsler2008, Reference Amsler, McClintock and Baker2014). The macroalgal canopy offers amphipods a site for reproduction, habitat and direct and indirect nutrition (Biernbaum Reference Biernbaum1981, Lorz & De Broyer Reference Lorz and De Broyer2004, Huang et al. Reference Huang, McClintock, Amsler and Huang2008, Amsler et al. Reference Amsler, McClintock and Baker2014), leading to a diverse amphipod community (Huang et al. Reference Huang, Amsler, McClintock, Amsler and Baker2007). Gut content analysis performed on amphipods reveals an eclectic diet of sponges, filamentous and unicellular algae, macroalgae and bryozoans, with highly variable feeding habits from omnivory to specialization and suspension feeding to grazing (Dayton et al. Reference Dayton, Bobilliard, Paine and Dayton1974, Coleman Reference Coleman1991, Jazdzewski et al. Reference Jazdzewski, Teodorczyk, Sicinski and Kontek1991, De Broyer & Jazdzewski Reference De Broyer and Jazdzewski1996, Kunzmann Reference Kunzmann1996, Iken et al. Reference Iken, Quartino, Barrera-Oro, Palermo, Wiencke and Brey1998, Lippert et al. Reference Lippert, Iken, Rachor and Wiencke2001, Takeuchi & Watanabe Reference Takeuchi and Watanabe2002, Huang et al. Reference Huang, McClintock, Amsler, Peters and Baker2006, Amsler et al. Reference Amsler, McClintock, Amsler, Angus and Baker2009, Aumack et al. Reference Aumack, Lowe, Amsler, Amsler, McClintock and Baker2017). In the circalittoral zone, which is below the macroalgal canopy zone, the diversity of amphipod species is lower, and a sponge-rich benthic community under biological mediation (Dayton et al. Reference Dayton, Robilliard, Paine and Holgate1970, McClintock Reference McClintock1987, Cattaneo-Vietti et al. Reference Cattaneo-Vietti, Bavestrello, Cerrano, Gaino, Mazzella, Pansini, Sarà, Faranda, Guglielmo and Ianora1999, Cerrano et al. Reference Cerrano, Bavestrello, Calcinai, Cattaneo-Vietti and Sarà2000, McClintock et al. Reference McClintock, Amsler, Baker and van Soest2005) supports chemically rich species (Lebar et al. Reference Lebar, Heimbegner and Baker2007, Avila et al. Reference Avila, Taboada and Núñez-Pons2008, Soldatou & Baker Reference Soldatou and Baker2017).

For omnivorous or spongivorous amphipods, the macroalgal canopy of the western Antarctic Peninsula provides refuge from fish predation (Zamzow et al. Reference Zamzow, Amsler, McClintock and Baker2010) but at the same time exposes sponges in that habitat to higher densities of potentially predatory amphipods. The highly branched inner structure of D. antarctica creates a complex network for amphipods to inhabit (Fig. 2). This in turn leads to high abundances of amphipods on and within the sponge (McClintock et al. Reference McClintock, Amsler, Baker and van Soest2005, Amsler et al. Reference Amsler, McClintock, Amsler, Angus and Baker2009). Omnivorous amphipods associated with sponges occupying the more exposed habitat that exists at depths below the algal canopy might be expected to be less common than those associated with sponges found in the algal canopy due to the lack of refugia provided by macroalgal cover. We were interested to study whether sponges can modulate their chemical defences in response to predator density.

Fig. 2. Image of Dendrilla antarctica and Colomastix fissilingua. D. antarctica (left) has a highly porous inner structure, which allows high densities of amphipods (top right) to inhabit the sponge.

We hypothesized that D. antarctica found in shallower, amphipod-rich waters with increased ecological competition would produce distinct secondary metabolites from specimens found below the algal canopy zone using metabolomics techniques (Kuhlisch & Pohnert Reference Kuhlisch and Pohnert2015). This methodology is highly useful for the study of natural products with the potential to distinguish phenotypes and provide insights into the biological processes involved in environmental responses and genetic modifications (Boccard et al. Reference Boccard, Veuthey and Rudaz2010). Our study design utilized specimens of D. antarctica from two distinct habitats - that within (W-habitat) the algal canopy and that at depths below (B-habitat) the canopy - from four distinct sites near Palmer Station, Antarctica. Individual specimens were subject to metabolomic profiling using liquid chromatography/quadrupole time-of-flight mass spectrometry (LC/QToF-MS) and assessment of amphipod distribution.

We found limited correlations between habitat and the three major secondary metabolites of D. antarctica: aplysulphurin, tetrahydroaplysulphurin and membranolide. However, multidimensional scaling (MDS) plots used to visualize full metabolomic patterns of individual sponges, which included these three diterpenoids in addition to other terpenes and secondary metabolites produced by the sponges, were able to distinguish the two habitats. Analysis of similarities (ANOSIM), similarity percentage (SIMPER) and biota and/or environment matching (BIOENV) were used to correlate the statistical relevance of site, habitat and amphipod density based on the untargeted metabolomic fingerprints.

Materials and methods

Habitat and site description

Four sampling sites were chosen within a 3.5 km boating radius from Palmer Station, including 1) Norsel Point (64°45.674'S, 64°05.467'W), 2) Bonaparte Point (64°46.748'S, 64°02.542'W), 3) Gamage Point (64°46.345'S, 64°02.915'W) and 4) Laggard Island (64°48.568'S, 64 00.984'W) (Fig. 3). Site selection was based on the presence of D. antarctica specimens within the two distinct habitats of interest: the shallow, macroalgal-dominated (W-habitat) depths and at deeper depths below (B-habitat) where macroalgae provided sufficient abundance to form a canopy. Generally, the two habitats were found at depths of < 20 and > 25 m, respectively.

Fig. 3. Map of the Palmer Station boating area. The four collection sites shown are within a 3.5 km (2 mi) radius from the station: 1) Norsel Point, 2) Bonaparte Point, 3) Gamage Point and 4) Laggard Island all surround Palmer Station (located next to Gamage Point or site 3), Anvers Island, Antarctica.

Biological specimens

Twenty sponge specimens with associated amphipods were collected from four sites by scuba. Specimens were taken in triplicate from both habitats from each site with the exception of Laggard Island, where only one specimen from each habitat was found. Fine-mesh collecting bags were used to capture amphipods associated with each specimen in the manner of Huang et al. (Reference Huang, McClintock, Amsler and Huang2008). Additional bulk D. antarctica samples were collected to produce chemical standards in support of quantification in study specimens. Sponge samples were frozen and transported back to the University of South Florida at -70°C, where tissues were lyophilized and stored at −80°C until further processing.

Larger amphipod species were separated from individual sponges by gentle agitation and sorted into species-specific bins. Amphipods hiding within sponge pores and canals (e.g. Colomastix fissilingua) were quantified under a microscope. Amphipod and algal identification were based on the methods of our previous studies of the local taxa and taxonomic keys (Huang et al. Reference Huang, Amsler, McClintock, Amsler and Baker2007, Amsler et al. Reference Amsler, McClintock, Amsler, Angus and Baker2009). Amphipods were identified to species level where possible, although in one case (Oedicerotidae) only identification to the family level was possible.

Isolation and characterization of the diterpene standards

From the bulk collection, 25.7 g of freeze-dried D. antarctica were extracted thrice with dichloromethane, then combined extracts were filtered and then concentrated in vacuo. The lipophilic extract (994 mg) was absorbed onto Waters Sep-Pak® C18 cartridges and eluted with acetonitrile. The dried material (205 mg) was separated by isocratic high-performance liquid chromatography (HPLC) using 60% acetonitrile in water on a Phenomenex Luna C18 column (250 × 10 mm, 5 μm) to afford aplysulphurin (10.2 mg), tetrahydroaplysulphurin (1.5 mg) and membranolide (8.7 mg). Compounds were analysed using 1H nuclear magnetic resonance (NMR; CDCl3, 500 MHz Varian DirectDrive spectrometer equipped with a cold probe) spectroscopy and electrospray ionization (ESI) mass spectrometry (Agilent 6540 LC/QToF). Structures assigned were based on comparison to their published data (Karuso et al. Reference Karuso, Bergquist, Cambie, Buckleton, Clark and Rickard1986, Molinski & Faulkner Reference Molinski and Faulkner1989).

Metabolomic analysis

Following a similar procedure to that used for the isolation of natural product standards, study specimens were extracted with dichloromethane and subjected to C18 solid-phase extraction. The dried eluent was then resuspended at 1.0 mg ml-1 in acetonitrile for analysis on an Agilent 6540 LC/QToF-MS with ESI in positive mode. Separation was achieved on a Phenomenex Kinetex® C18 column (50 × 2.1 mm, 2.6 μm) using water with 0.1% formic acid as mobile phase (A) and acetonitrile with 0.1% formic acid as mobile phase (B). A binary gradient was employed ramping from 40% to 60% (B) over 3 min, 60% (B) isocratic for 4 min, increased to 60–100% (B) over 3 min and finally held at 100% (B) for 2 min. The source was maintained at 300°C and a capillary voltage of 3500 V. Nitrogen was used as the drying gas (8 l min-1) and sheath gas (11 l min-1) at temperatures of 300°C and 350°C, respectively. Aplysulphurin, tetrahydroaplysulphurin and membranolide were quantified as external standards with concentration curves (data not shown). All samples were analysed in triplicate with injection volumes of 2 μl.

Statistical analysis of the metabolomic data

The top 100 compounds as determined by peak area (including known secondary metabolites) in each sponge extract were identified in the total ion chromatogram by molecular feature extraction using MassHunter Qualitative Analysis 5.0. Mass Profiler Professional 11.0 was used to classify entities by interpretation, then each entity was normalized to the crude extract mass. Blanks consisting of dried dichloromethane and acetonitrile were used to subtract solvent impurities from sample fingerprints. Compounds that were present in two of three replicates were included in the final entity list.

The entity lists for each sample were imported into PRIMER-E v6 following the recommendations of Clarke et al. (Reference Clarke, Gorley, Somerfield and Warwick2014). Chemical data were square-root transformed along with the amphipod abundance numbers, which were standardized to sponge volume by measuring displacement in seawater. A Bray-Curtis resemblance matrix was created for the top 100 compounds. To assess the validity of the chemical data influencing habitat and site, ANOSIM and SIMPER analyses were employed. Amphipod counts included only those amphipods that were deemed to be omnivorous and therefore potential predators, as well as those shown to be statistically correlated with the chemical entity data as per the BIOENV procedure as part of the BEST routine. The analysis of that matrix was plotted with dendrograms and MDS; the amphipod counts were overlaid directly as 2D bubbled factors on the MDS plot.

Results

Biological specimens

A total of approximately 2700 amphipods present on the 20 sponge specimens were characterized. Qualitatively, it was very obvious that the shallower sponge specimens contained larger amphipods in higher quantities with more diversity present. A total of 22 different taxa were identified, most to species level, with six of these being statistically correlated via the BIOENV procedure and omnivorous or potential predators (Table I, shaded in grey). Ischyroceridae found on the specimens were not included in the analysis as these species are considered filter feeders and non-predatory to Dendrilla antarctica. Other presumptive non-predators in association with D. antarctica included copepods, isopods and micrograzing amphipods Ausatelson sp., Gitanopsis squamosa, Proboloides sp., Probolisca ovata, Prothaumatelson nasutum and Thaumatelson hermani.

Table I. Amphipods found on sponges collected from habitats within (W; 0–20 m) the algal canopy and at depths below (B; 20–35 m) the algal canopy zone. Potential sponge-predator amphipods are shaded in grey.

Diterpene analysis

Three major diterpenes, membranolide, aplysulphurin and tetrahydroaplysulphurin, were identified in the sponge specimens in order to confirm their relative abundance and presence. Diterpene concentrations were highly variable among individuals, including biological replicates from the same habitat and site. The known amphipod predation deterrent membranolide varied among the 20 sponges between 0 and 3.2 mg kg-1 dry weight (DW) with an average concentration of 1.3 mg kg-1 DW (Fig. 4). Other diterpenes were generally less abundant: aplysulphurin was never present at > 0.1 mg kg-1 DW and tetrahydroaplysulphurin varied between 0 and 3.4 mg kg-1 DW but averaged only 0.9 mg kg-1 DW. None of the secondary metabolites had significant variance between sites; however, tetrahydroaplysulphurin was produced in significantly higher concentrations within the algal canopy than below it (unpaired t-test, P < 0.05). LC/MS data showed that sponges within the algal canopy (W-habitat) produced more of the known secondary metabolites aplysulphurin, tetrahydroaplysulphurin and membranolide. The sponges below the algal canopy (B-habitat) showed greater chemical diversity in their metabolite profile.

Fig. 4. Quantification of Dendrilla antarctica diterpene metabolites. Variability in the concentrations of known secondary metabolites from D. antarctica found within (W) and below (B) the algal canopy from the four study sites is shown.

Statistical analysis

Cluster analyses of metabolomic data (Fig. 4) show a clear distinction between sponges from the two habitats under consideration. The deeper-occurring sponges (B-habitat) show a 60% similarity, while the shallower sponges in the canopy region (W-habitat) display 30% similarity according to the Bray-Curtis analysis. A SIMPER test showed an average dissimilarity of 80% between the metabolomic fingerprints of the two habitats, providing evidence of how greatly chemical profiles differ among the sponges found in these two environments. The rejection or applicability of the null hypothesis pertaining to metabolite abundance vs habitat, site and amphipod density was analysed via one- and two-way ANOSIM. A global R of ~0 (R = |0.07|) for site specificity against secondary metabolite abundance shows that this is not a statistically significant factor. A global R of 0.57 for habitat against compound abundance displays overlap; however, it remains statistically significant and rejects the null hypothesis. A lone outlier in the shallower habitat at site 3 (U) clustered with sponges below the algal canopy (left of centre of Fig. 5); however, a leathery morphology and lack of associated amphipods could indicate a diseased or older sponge (J.L. von Salm & M.O. Amsler, personal observations 2011). This specimen had a similar chromatographic profile and clustered well with a B-habitat sponge collected at site 1 (data point H), also displaying a similar non-porous morphology. Two sponges from site 2 (data point C from the B-habitat and data point O from the W-habitat) are correlated by similar chromatographic profiles and nearly identical concentrations of tetrahydroaplysulphurin (0.41 and 0.47 mg kg-1 DW for data points C and O, respectively). Similarly, a site 3 specimen (data point R) had a significantly higher concentration of membranolide than its biological replicates, grouping it with other W-habitat, chemically defended sponges (data points M and O; Fig. 5).

Fig. 5. Dendrogram cluster analysis of the top 100 compounds from Dendrilla antarctica. The samples (lettered) from depths represented as within the canopy region (blue triangles) and those from depths below the canopy region (black rotated triangles) are depicted. Similarity is measured as a percentage.

A two-way ANOSIM of depth and amphipod densities as compared to secondary metabolite concentrations provided a global R of ~0 similarity (R = 0.07) for amphipod significance against compound abundance. The null hypothesis therefore applies, so SIMPER analysis was used to determine whether significant amphipod species variability exists between the W-habitat and B-habitat, with an average dissimilarity of 34.8% being found. As neither ANOSIM nor SIMPER analyses provided evidence that amphipods are a significant driving force for sponge secondary metabolism, the BIOENV procedure was performed on the whole amphipod community (amphipods, Table I) in order to assess which combination of amphipod species best describes the divergence within the chemical dataset. This test afforded seven statistically correlated amphipod taxa (Atylopsis orthodactyla, G. antarctica, Liljeborgia sp., Oedicerotidae, Paradexamine fissicauda, Prostebbingia brevicornis and Prostebbingia gracilis), of which all but Oedicerotidae and P. fissicauda were deemed potential spongivores. It was noted that the specimen from Bonaparte Point had a red alga, Plocamium cartilagineum, growing with the sponge tissue. P. fissicauda has a known preference for this algal species (Amsler et al. Reference Amsler, Amsler, von Salm, Aumack, McClintock, Young and Baker2013); however, it is still considered a potential consumer of D. antarctica. These data are overlaid as bubble plots in the 2D MDS ordination (Fig. 6). Of the correlated amphipod species, those present only within the algal canopy (W-habitat) include G. antarctica, Liljeborgia sp. and P. gracilis, while A. orthodactyla and P. brevicornis were found only rarely below the canopy (B-habitat). No species were specific only to the B-habitat.

Fig. 6. 2D multidimensional scaling (MDS) ordination of the Dendrilla antarctica metabolomic profile. The MDS plot is overlaid with statistically correlated omnivorous amphipod densities (blue circles) showing a clear distinction between sponge specimens within (W) the algal canopy (right) and specimens found at depths below (B) the canopy zone (left).

Discussion

Similarly to so many sessile organisms, sponges produce biologically active natural products in response to environmental threats such as predation and competition (Puglisi et al. Reference Puglisi, Sneed, Sharp, Ritson-Williams and Paul2014, Reference Puglisi, Sneed, Ritson-Williams and Young2019). The secondary metabolites of D. antarctica have been investigated for decades and, as a result, multiple oxidized diterpenes have been identified with a wide array of ecological and therapeutic bioactivities (Molinski & Faulkner Reference Molinski and Faulkner1989, Fontana et al. Reference Fontana, Scognamiglio and Cimino1997, Ankisetty et al. Reference Ankisetty, Amsler, McClintock and Baker2004, Bory et al. Reference Bory, Shilling, Allen, Azhari, Roth and Shaw2020, Shilling et al. Reference Shilling, Witowski, Maschek, Azhari, Vesely and Kyle2020). Among the major sponge predators influencing these defences along the western Antarctic Peninsula are small arthropods known as amphipods, which have been shown to have a more prominent presence within the algal canopy (Jazdzewski et al. Reference Jazdzewski, Teodorczyk, Sicinski and Kontek1991, Amsler et al. Reference Amsler, McClintock, Amsler, Angus and Baker2009). The current study has described evidence that sponge proximity to predatory amphipod species influences the secondary metabolism in D. antarctica. Concomitant variability in amphipod predation pressure provides an explanation; however, other ecological factors were not investigated in this study.

Analysis of the metabolomic profiles of individual D. antarctica among collection sites suggested no obvious variability, thus ruling out site specificity. However, collections from the two habitats provided a clear distinction between the metabolites produced (Figs 5 & 6). The shallow region (W-habitat) contains several stressors to consider: ultraviolet (UV) light penetration, greater fouling potential, algal competition and higher amphipod densities. Some organisms produce compounds that protect the host against UV radiation (Pavia et al. Reference Pavia, Cervin, Lindgren and Aberg1997, Shick & Dunlap Reference Shick and Dunlap2002) such as mycosporine-like amino acids (MAAs), which are found in many Antarctic invertebrates (Karentz et al. Reference Karentz, McEuen, Land and Dunlap1991). The presence of MAAs was not tested in this study, but previous work (McClintock & Karentz Reference McClintock and Karentz1997) showed modest MAA concentrations (424 μg g-1 DW) in D. antarctica from McMurdo Sound. It should be noted that diterpenes from D. antarctica are not strong absorbers of UV light, so it is improbable that these compounds would play a role in photo-induced stress. In a region with greater algal abundance, some sponges could increase their defensive compounds to prevent fouling from algae, as was suggested for the Australian sponge Rhopaloeides odorabile (Thompson et al. Reference Thompson, Murphy, Bergquist and Evans1987). Currently, the role of these secondary metabolites has not been tested as an inhibitor of algal fouling or other allelopathic interactions; therefore, the potential of such activity should not be overlooked. It has, however, been proven that extracts of D. antarctica deter the feeding behaviours of the sympatric spongivorous sea stars P. fuscus (McClintock et al. Reference McClintock, Baker, Slattery, Hamann, Koptizke and Heine1994, Baker et al. Reference Baker, Kopitzke, Yoshida and McClintock1995) and G. antarctica (Amsler et al. Reference Amsler, McClintock, Amsler, Angus and Baker2009), where membranolide has been identified as a feeding deterrent of G. antarctica. Other diterpenoids discussed have not been specifically tested regarding their ability to deter predators; however, chemical similarities within the scaffold make this role probable.

In an effort to understand whether secondary metabolites correlate to habitat or amphipod abundance, the diterpene membranolide was quantified in individual sponges. The membranolide concentration was found to be highly variable, even among biological replicates from the same site and habitat. This variability between individual sponges of the same species is not uncommon (Puyana et al. Reference Puyana, Fenical and Pawlik2003, Rohde et al. Reference Rohde, Gochfeld, Ankisetty, Avula, Schupp and Slattery2012). We hypothesized that sponges within the algal canopy (W-habitat) would have higher concentrations of membranolide due to its feeding-deterrent properties; however, no distinct trend was observed. Membranolide was present in all sponges, and it is probable that D. antarctica produces membranolide constitutively rather than as a response to environmental pressure, such as amphipod predation. This provides evidence that other predator-specific or feeding-deterrent compounds may remain unidentified. Feeding-deterrent properties have been noted for extracts of the sponge (Amsler et al. Reference Amsler, McClintock, Amsler, Angus and Baker2009), but fractionation efforts have resulted in a loss of activity (Baker et al. Reference Baker, Kopitzke, Yoshida and McClintock1995); therefore, mixtures of compounds could have a synergistic effect on deterrence or the limited quantity of the metabolites upon fractionation could reduce their activity. Variability in the production of tetrahydroaplysulphurin by D. antarctica provides evidence that this compound probably has an ecologically significant yet unknown role. Ecological factors within the algal canopy may warrant a shift in the secondary metabolism of shallower D. antarctica to focus more energy on the production of tetrahydroaplysulphurin.

Dendrogram cluster analysis of the chemical fingerprints using Bray-Curtis similarities showed a clear distinction between sponges in both habitats (Fig. 5). One of the most abundant amphipod species found to be associated with D. antarctica was C. fissilingua (Fig. 2 & Table I). Similarly to other amphipods and specifically Colomastix species (Gerovasileiou et al. Reference Gerovasileiou, Chintiroglou, Konstantinou and Voultsiadou2016), C. fissilingua inhabits the sponge as a refuge from predation rather than preying on the sponge itself. However, data published from previous investigations show high associations of C. fissilingua with multiple chemically defended sponge species: Artemisina sp., Clathria flabellata, Isodictya erinacea, Isodictya lankesteri and Lissodendoryx ramilobosa (Amsler et al. Reference Amsler, McClintock, Amsler, Angus and Baker2009, Peters et al. Reference Peters, Amsler, McClintock and Baker2010, Tripathi et al. Reference Tripathi, Satish, Horam, Raj, Lal and Arockiaraj2018). Whether this is a result of physical ease of accessibility to the inner cavities of these sponges or specific chemical associations is yet to be determined.

The prominence of amphipods found on D. antarctica that lack directly established predatory roles meant that the BIOENV routine was required to reveal species found to correlate statistically with the secondary metabolite distribution of D. antarctica (Table I, shaded in grey). These species were found to be differentially distributed only on sponges from within the canopy (W-habitat). The relative densities of the six potentially spongivorous amphipods identified were overlaid (blue bubbles in Fig. 6) with the chemical fingerprints to reveal a correlation (stress = 0.07) between omnivorous amphipod predators and depth within and below the algal canopy. Sponges associated with these six amphipod species plot in close proximity in the W-habitat (right of the MDS plot in Fig. 6), whereas the sponges from the B-habitat all cluster tightly with regards to their metabolome, and predatory amphipods are absent from these samples. Feeding-deterrent compounds probably play a role in the clustering of sponges based on their metabolite profile in the shallow, algal-dominated W-habitat, where sponges are more likely to be preyed upon; however, it should be noted that greater dissimilarity between the secondary metabolites produced is shown within the shallow W-habitat specimens compared with those from the B-habitat. The diversity and probably stressful environment in the W-habitat causes D. antarctica to modulate its metabolism accordingly, which is clearly established by the distinction in habitat observed in the MDS ordination (Figs 5 & 6). As the W-habitat specimens were the only sponges associated with the amphipod species identified by the BIOENV procedure, this provides further evidence that omnivorous amphipods are more prevalent within the macroalgal canopy and may influence the secondary metabolism of D. antarctica and other shallow invertebrates.

In similar studies near Palmer Station, the rhodophyte P. cartilagineum (Young et al. Reference Young, von Salm, Amsler, Lopez-Bautista, Amsler, McClintock and Baker2013, Shilling et al. Reference Shilling, Heiser, Amsler, McClintock and Baker2021) and the nudibranch Austrodoris kerguelenensis (Wilson et al. Reference Wilson, Maschek and Baker2013) have shown significant metabolic variations between specimens. The authors note that repeated glaciations can segregate regions, therefore causing genetic and chemical divergence among individuals of the same species (Diez-Vives et al. Reference Díez-Vives, Taboada, Leiva, Busch, Hentschel and Riesgo2020). Although site specificity was not seen for this metabolomics investigation of D. antarctica and these findings are not believed to be associated with cryptic speciation, follow-up experiments with expanded locations show evidence of location-dependent chemodiversity for this species (Shilling et al. Reference Shilling, Witowski, Maschek, Azhari, Vesely and Kyle2020). Along with the present work, this provides yet another example of metabolic divergence in the benthic community associated with the western Antarctic Peninsula. Similarly to A. kerguelenensis, predator or possibly allelopathic interactions seem to play a predominant role in the clustering of these organisms by metabolomics. The sponge microbiome may play a role in either the biological or metabolomic variability (Levia et al. Reference Leiva, Taboada, Kenny, Combosch, Giribet, Jombart and Riesgo2019, Murray et al. Reference Murray, Avalon, Bishop, Davenport, Delage and Dichosa2020, Sacristan-Soriano et al. Reference Sacristán-Soriano, Pérez Criado and Avila2020).

Many hidden interactions regulate the ecology of competing organisms in Antarctic waters. We have now identified predation stress from amphipods as a potential factor influencing the metabolome of D. antarctica. The amphipod feeding deterrent membranolide is now shown to be produced only constitutively among sponge specimens and does not account for the metabolomic variability of D. antarctica in the habitat within and at depths below the macroalgal canopy. Tetrahydroaplysulphurin has instead been identified as a major contributor to the metabolic variability between these depths. Competition at shallower depths due to sponge-algae interactions is also prominent in the phototropic zone; therefore, these and other interactions could be relevant to the observed chemical diversity in D. antarctica. It should not be overlooked that some of the most important factors for secondary metabolite production, such as temperature, salinity and pH, are not as constant in this environment as was once believed (Schram et al. Reference Schram, Schoenrock, McClintock, Amsler and Angus2015). The Antarctic Circumpolar Current provides cold, nutrient-rich waters that are essential to Antarctic marine life, and polar regions are particularly vulnerable to the effects of warming climates (Clarke et al. Reference Clarke, Murphy, Meredith, King, Peck, Barnes and Smith2007). This delicate environment harbours unique species and biodiversity with > 4000 benthic macroinvertebrate species having been identified, which we have only just started to understand (Arntz et al. Reference Arntz, Gutt and Klages1997, Clarke & Johnston Reference Clarke and Johnston2003, Gutt et al. Reference Gutt, Sirenko, Smirnov and Arntz2004, McClintock et al. Reference McClintock, Amsler, Baker and van Soest2005, Reference McClintock, Amsler and Baker2010).

Acknowledgements

We are grateful to Kate Schoenrock, Ruth McDowell, Jason Cuce and William Dent who participated in the sample collection. We thank the Raytheon Polar Services Staff at Palmer Station, without whom this work would not have been possible. The comments from two anonymous reviewers are greatly appreciated and improved the clarity of the manuscript.

Financial support

This work was supported by National Science Foundation Antarctic Organisms and Ecosystems programme awards ANT-0838773 and PLR-1341333 to CDA and JBM, ANT-0838776 and PLR-1341339 to BJB and a Center of Excellence award from the State of Florida to support the Center for Drug Discovery and Innovation, whose facilities made much of the chemical analysis possible. JBM acknowledges the support of an Endowed Professorship from the University of Alabama at Birmingham.

Author contributions

JLvS: conceived and coordinated the project, conducted the amphipod studies (including enumeration and identification) and the statistical analyses and wrote the first draft of the manuscript. CGW: conducted metabolomics and natural product analysis. MOA: conducted the amphipod studies, including enumeration and identification. CDA: conceived the project, obtained funding and field resources, conducted fieldwork (including specimen collection) and provided oversight of the amphipod analyses. JBM: conceived the project, obtained funding and field resources, conducted fieldwork and provided oversight of the amphipod analyses. BJB: conceived the project, obtained funding and field resources, conducted fieldwork (including specimen collection) and provided oversight of the chemical analyses. All authors contributed to the editing of the final manuscript.

Details of data deposit

Data are available at the United States Antarctic Program Data Center: https://www.usap-dc.org/view/project/p0010016.

References

Amade, P. & Lemee, R. 1998. Chemical defence of the Mediterranean alga Caulerpa taxifolia: variations in caulerpenyne production. Aquatic Toxicology, 43, 10.1016/S0166-445x(98)00054-X.10.1016/S0166-445X(98)00054-XCrossRefGoogle Scholar
Amsler, C.D., McClintock, J.B. & Baker, B.J. 2008. Macroalgal chemical defenses in polar marine communities. In Amsler, C.D., ed. Algal chemical ecology. Berlin: Springer-Verlag, 91103.10.1007/978-3-540-74181-7CrossRefGoogle Scholar
Amsler, C.D., McClintock, J.B. & Baker, B.J. 2014. Chemical mediation of mutualistic interactions between macroalgae and mesograzers structure unique coastal communities along the western Antarctic Peninsula. Journal of Phycology, 50, 10.1111/jpy.12137.10.1111/jpy.12137CrossRefGoogle ScholarPubMed
Amsler, M.O., McClintock, J.B., Amsler, C.D., Angus, R.A. & Baker, B.J. 2009. An evaluation of sponge-associated amphipods from the Antarctic Peninsula. Antarctic Science, 21, 10.1017/s0954102009990356.10.1017/S0954102009990356CrossRefGoogle Scholar
Amsler, M.O., Amsler, C.D., von Salm, J.L., Aumack, C.F., McClintock, J.B., Young, R.M. & Baker, B.J. 2013. Tolerance and sequestration of macroalgal chemical defenses by an Antarctic amphipod: a ‘cheater’ among mutualists. Marine Ecology Progress Series, 490, 10.3354/meps10446.10.3354/meps10446CrossRefGoogle Scholar
Ankisetty, S., Amsler, C.D., McClintock, J.B. & Baker, B.J. 2004. Further membranolide diterpenes from the antarctic sponge Dendrilla membranosa. Journal of Natural Products, 67, 10.1021/np0340551.CrossRefGoogle ScholarPubMed
Arntz, W.E., Gutt, J. & Klages, M., eds. 1997. Antarctic marine biodiversity: an overview. Antarctic communities: species, structure, and survival. Cambridge: Cambridge University Press, 314.Google Scholar
Aumack, C.F., Lowe, A.T., Amsler, C.D., Amsler, M.O., McClintock, J.B. & Baker, B.J. 2017. Gut content, fatty acid, and stable isotope analyses reveal dietary sources of macroalgal-associated amphipods along the western Antarctic Peninsula. Polar Biology, 40, 10.1007/s00300-016-2061-4.CrossRefGoogle Scholar
Avila, C., Taboada, S. & Núñez-Pons, L. 2008. Antarctic marine chemical ecology: what is next? Marine Ecology, 29, 10.1111/j.1439-0485.2007.00215.x.10.1111/j.1439-0485.2007.00215.xCrossRefGoogle Scholar
Baker, B.J., Kopitzke, R.W., Yoshida, W.Y. & McClintock, J.B. 1995. Chemical and ecological studies of the Antarctic sponge Dendrilla membranosa. Journal of Natural Products, 58, 10.1021/np50123a020.CrossRefGoogle Scholar
Biernbaum, C.K. 1981. Seasonal changes in the amphipod fauna of Microciona prolifera (Ellis and Solander) (Porifera, Demospongia) and associated sponges in a shallow salt-marsh creek. Estuaries, 4, 10.2307/1351671.10.2307/1351671CrossRefGoogle Scholar
Boccard, J., Veuthey, J.L. & Rudaz, S. 2010. Knowledge discovery in metabolomics: an overview of MS data handling. Journal of Separation Science, 33, 10.1002/Jssc.200900609.10.1002/jssc.200900609CrossRefGoogle ScholarPubMed
Bory, A., Shilling, A.J., Allen, J., Azhari, A., Roth, A., Shaw, L.N., et al. 2020. Bioactivity of spongian diterpenoid scaffolds from the Antarctic sponge Dendrilla antarctica. Marine Drugs, 18, 10.3390/md18060327.CrossRefGoogle ScholarPubMed
Cattaneo-Vietti, R., Bavestrello, G., Cerrano, C., Gaino, E., Mazzella, L., Pansini, M. & Sarà, M. 1999. The role of sponges in the Terra Nova ecosystem. In Faranda, F.M., Guglielmo, L. & Ianora, A., eds. Ross Sea Ecology Italiantartide expeditions (1987–1995). New York: Springer, 539549.Google Scholar
Cerrano, C., Bavestrello, G., Calcinai, B., Cattaneo-Vietti, R. & Sarà, A. 2000. Asteroids eating sponges from Tethys Bay, East Antarctica. Antarctic Science, 12, 425426.CrossRefGoogle Scholar
Clarke, A. & Johnston, N.M. 2003. Antarctic marine benthic diversity. Oceanography and Marine Biology Annual Review, 41, 47114.Google Scholar
Clarke, A., Murphy, E.J., Meredith, M.P., King, J.C., Peck, L.S., Barnes, D.K.A. & Smith, R.C. 2007. Climate change and the marine ecosystem of the western Antarctic Peninsula. Philosophical Transactions of the Royal Society B: Biological Sciences, 367, 149166.CrossRefGoogle Scholar
Clarke, K.R., Gorley, R.N., Somerfield, P.J. & Warwick, R.M. 2014. Change in marine communities: an approach to statistical analysis and interpretation, 3rd edition. Plymouth: PRIMER-E.Google Scholar
Coleman, C.O. 1991. Comparative fore-gut morphology of Antarctic Amphipoda (Crustacea) adapted to different food sources. Hydrobiologia, 223, 10.1007/Bf00047623.CrossRefGoogle Scholar
Dayton, P.K., Robilliard, G.A. & Paine, R.T. 1970. Benthic faunal zonation as a result of anchor ice at McMurdo Sound, Antarctica. In Holgate, M.W., ed. Antarctic ecology, vol. 1. New York: Academic Press, 244258.Google Scholar
Dayton, P.K., Bobilliard, G.A., Paine, R.T. & Dayton, L.B. 1974. Biological accomodation in the benthic community at McMurdo Sound, Antarctica. Ecological Monographs, 44, 105128.CrossRefGoogle Scholar
De Broyer, C. & Jazdzewski, K. 1996. Biodiversity of the Southern Ocean: towards a new synthesis for the Amphipoda (Crustacea). Bollettino del Museo civico di Storia Naturale di Verona, 20, 547568.Google Scholar
Díez-Vives, C., Taboada, S., Leiva, C., Busch, K., Hentschel, U. & Riesgo, A. 2020. On the way to specificity - microbiome reflects sponge genetic cluster primarily in highly structured populations. Molecular Ecology, 29, 10.1111/mec.15635.CrossRefGoogle ScholarPubMed
Fontana, A., Scognamiglio, G. & Cimino, G. 1997. Dendrinolide, a new degraded diterpenoid from the Antarctic sponge Dendrilla membranosa. Journal of Natural Products, 60, 475477.CrossRefGoogle Scholar
Gerovasileiou, V., Chintiroglou, C.C., Konstantinou, D. & Voultsiadou, E. 2016. Sponges as ‘living hotels’ in Mediterranean marine caves. Scientia Marina, 80, 10.3989/scimar.04403.14B.CrossRefGoogle Scholar
Gutt, J., Sirenko, B.I., Smirnov, I.S. & Arntz, W.E. 2004. How many macrozoobenthic species might inhabit the Antarctic shelf. Antarctic Science, 16, 1116.CrossRefGoogle Scholar
Harvell, C.D., Fenical, W., Roussis, V., Ruesink, J.L., Griggs, C.C. & Greene, C.H. 1993. Local and geographic variation in the defensive chemistry of a West Indian gorgonian coral (Briareum asbestinum). Marine Ecology Progress Series, 93, 10.3354/Meps093165.CrossRefGoogle Scholar
Huang, J.P., McClintock, J.B., Amsler, C.D. & Huang, Y.M. 2008. Mesofauna associated with the marine sponge Amphimedon viridis. Do its physical or chemical attributes provide a prospective refuge from fish predation? Journal of Experimental Marine Biology and Ecology, 362, 10.1016/J.Jembe.2008.06.007.Google Scholar
Huang, Y.M., Amsler, M.O., McClintock, J.B., Amsler, C.D. & Baker, B.J. 2007. Patterns of gammaridean amphipod abundance and species composition associated with dominant subtidal macroalgae from the western Antarctic Peninsula. Polar Biology, 30, 10.1007/s00300-007-0303-1.CrossRefGoogle Scholar
Huang, Y.M., McClintock, J.B., Amsler, C.D., Peters, K.J. & Baker, B.J. 2006. Feeding rates of common Antarctic gammarid amphipods on ecologically important sympatric macroalgae. Journal of Experimental Marine Biology and Ecology, 329, 5565.CrossRefGoogle Scholar
Iken, K., Quartino, M.L., Barrera-Oro, E., Palermo, J., Wiencke, C. & Brey, T. 1998. Trophic relations between macroalgae and herbivores. Reports on Polar and Marine Research, 299, 258262.Google Scholar
Jazdzewski, K., Teodorczyk, W., Sicinski, J. & Kontek, B. 1991. Amphipod crustaceans as an important component of zoobenthos of the shallow Antarctic sublittoral. Hydrobiologia, 223, 10.1007/Bf00047632.CrossRefGoogle Scholar
Karentz, D., McEuen, F.S., Land, M.C. & Dunlap, W.C. 1991. Survey of mycosporine-like amino acid compounds in Antarctic marine organisms: potential protection from ultraviolet exposure. Marine Biology, 108, 157166.CrossRefGoogle Scholar
Karuso, P., Bergquist, P.R., Cambie, R.C., Buckleton, J.S., Clark, G.R. & Rickard, C.E.F. 1986. Terpenoid constituents of morphologically similar sponges in the family Aplysillidae. Australian Journal of Chemistry, 39, 16431653.CrossRefGoogle Scholar
Kelman, D., Benayahu, Y. & Kashman, Y. 2000. Variation in secondary metabolite concentrations in yellow and grey morphs of the Red Sea soft coral Parerythropodium fulvum fulvum: possible ecological implications. Journal of Chemical Ecology, 26, 10.1023/A:1005423708904.CrossRefGoogle Scholar
Kuhlisch, C. & Pohnert, G. 2015. Metabolomics in chemical ecology. Natural Product Reports, 32, 10.1039/c5np00003c.CrossRefGoogle ScholarPubMed
Kunzmann, K. 1996. Associated fauna of selected sponges (Hexactinellida and Demospongiae) from the Weddell Sea, Antarctica. Ber Polarforsch 210: 193.Google Scholar
Lebar, M.D., Heimbegner, J.L. & Baker, B.J. 2007. Cold-water marine natural products. Natural Product Reports, 24, 10.1039/b516240h.CrossRefGoogle ScholarPubMed
Leiva, C., Taboada, S., Kenny, N.J., Combosch, D., Giribet, G., Jombart, T. & Riesgo, A. 2019. Population substructure and signals of divergent adaptive selection despite admixture in the sponge Dendrilla antarctica from shallow waters surrounding the Antarctic Peninsula. Molecular Ecology, 28, 10.1111/mec.15135.Google ScholarPubMed
Lippert, H., Iken, K., Rachor, E. & Wiencke, C. 2001. Macrofauna associated with macroalgae in the Kongsfjord (Spitsbergen). Polar Biology, 24, 512522.Google Scholar
Lopez-Legentil, S., Dieckmann, R., Bontemps-Sublelos, N., Turon, X. & Banaigs, B. 2005. Qualitative variation of alkaloids in color morphs of Cystodytes (Ascidiacea). Biochemical Systematics and Ecology, 33, 10.1016/J.Bse.2005.03.011.CrossRefGoogle Scholar
Lorz, A.N. & De Broyer, C. 2004. Description and ecology of a spongicolous lysianassoid amphipod (Crustacea) from Antarctica. Journal of Natural History, 38, 10.1080/0022293021000046513.CrossRefGoogle Scholar
Maida, M., Carroll, A.R. & Coll, J.C. 1993. Variability of terpene content in the soft coral Sinularia flexibilis (Coelenterata, Octocorallia), and its ecological implications. Journal of Chemical Ecology, 19, 10.1007/Bf00979664.CrossRefGoogle Scholar
Marti, R., Uriz, M.J. & Turon, X. 2005. Spatial and temporal variation of natural toxicity in cnidarians, bryozoans and tunicates in Mediterranean caves. Scientia Marina, 69, 485492.Google Scholar
Matlock, D.B., Ginsburg, D.W. & Paul, V.J. 1999. Spatial variability in secondary metabolite production by the tropical red alga Portieria hornemannii. Hydrobiologia, 399, 267273.Google Scholar
McClintock, J.B. 1987. Investigation of the relationship between invertebrate predation and biochemical composition, energy content, spicule armament and toxicity of benthic sponges at McMurdo Sound, Antarctica. Marine Biology, 94, 479487.CrossRefGoogle Scholar
McClintock, J.B. & Karentz, D. 1997. Mycosporine-like amino acids in 38 species of subtidal marine organisms from McMurdo Sound, Antarctica. Antarctic Science, 9, 392398.CrossRefGoogle Scholar
McClintock, J.B., Amsler, C.D. & Baker, B.J. 2010. Overview of the chemical ecology of benthic marine invertebrates along the western Antarctic Peninsula. Integrative and Comparative Biology, 50, 10.1093/icb/icq035.CrossRefGoogle ScholarPubMed
McClintock, J.B., Amsler, C.D., Baker, B.J. & van Soest, R.W.M. 2005. Ecology of antarctic marine sponges: an overview. Integrative and Comparative Biology, 45, 10.1093/icb/45.2.359.CrossRefGoogle ScholarPubMed
McClintock, J.B., Baker, B.J., Slattery, M., Hamann, M., Koptizke, R. & Heine, J. 1994. Chemotactic tube-foot responses of the spongivorous sea star Perknaster fuscus to organic extracts from Antarctic sponges. Journal of Chemical Ecology, 20, 859870.CrossRefGoogle Scholar
Mendola, D. 2003. Aquaculture of three phyla of marine invertebrates to yield bioactive metabolites: process developments and economics. Biomolecular Engineeering, 20, 441458.CrossRefGoogle ScholarPubMed
Molinski, T.F. & Faulkner, D.J. 1989. Metabolites of the Antarctic sponge Dendrilla membranosa. Journal of Organic Chemistry, 54, 39023907.Google Scholar
Murray, A.E., Avalon, N.E., Bishop, L., Davenport, K.W., Delage, E., Dichosa, A.E.K., et al. 2020. Uncovering the core microbiome and distribution of palmerolide in Synoicum adareanum across the Anvers Island Archipelago, Antarctica. Marine Drugs, 18, 10.3390/md18060298.CrossRefGoogle ScholarPubMed
Page, M., West, L., Northcote, P., Battershill, C. & Kelly, M. 2005. Spatial and temporal variability of cytotoxic metabolites in populations of the New Zealand sponge Mycale hentscheli. Journal of Chemical Ecology, 31, 11611174.CrossRefGoogle ScholarPubMed
Paul, V.J. & Vanalstyne, K.L. 1988. Chemical defense and chemical variation in some tropical pacific species of Halimeda (Halimedaceae, Chlorophyta). Coral Reefs, 6, 10.1007/Bf00302022.CrossRefGoogle Scholar
Pavia, H., Cervin, G., Lindgren, A. & Aberg, P. 1997. Effects of UV-B radiation and simulated herbivory on phlorotannins in the brown alga Ascophyllum nodosum. Marine Ecology Progress Series, 157, 139146.CrossRefGoogle Scholar
Pawlik, J.R., Loh, T.L., McMurray, S.E. & Finelli, C.M. 2013. Sponge communities on Caribbean coral reefs are structured by factors that are top-down, not bottom-up. PLoS ONE, 8, 10.1371/journal.pone.0062573.CrossRefGoogle Scholar
Peters, K.J., Amsler, C.D., McClintock, J.B. & Baker, B.J. 2010. Potential chemical defenses of Antarctic sponges against sympatric microorganisms. Polar Biology, 33, 10.1007/s00300-009-0741-z.CrossRefGoogle Scholar
Puglisi, M.P., Sneed, J.M., Ritson-Williams, R. & Young, R. 2019. Marine chemical ecology in benthic environments. Natural Product Reports, 36, 10.1039/C8NP00061A.CrossRefGoogle ScholarPubMed
Puglisi, M.P., Sneed, J.M., Sharp, K.H., Ritson-Williams, R. & Paul, V.J. 2014. Marine chemical ecology in benthic environments. Natural Product Reports, 31, 10.1039/c4np00017j.CrossRefGoogle ScholarPubMed
Puyana, M., Fenical, W. & Pawlik, J.R. 2003. Are there activated chemical defenses in sponges of the genus Aplysina from the Caribbean? Marine Ecology Progress Series, 246, 127135.CrossRefGoogle Scholar
Rohde, S., Gochfeld, D.J., Ankisetty, S., Avula, B., Schupp, P.J. & Slattery, M. 2012. Spatial variability in secondary metabolites of the Indo-Pacific sponge Stylissa massa. Journal of Chemical Ecology, 38, 10.1007/S10886-012-0124-8.CrossRefGoogle ScholarPubMed
Sacristán-Soriano, O., Pérez Criado, N. & Avila, C. 2020. Host species determines symbiotic community composition in Antarctic sponges (Porifera: Demospongiae). Frontiers in Marine Science, 7, 10.3389/fmars.2020.00474.CrossRefGoogle Scholar
Schram, J.B., Schoenrock, K.M., McClintock, J.B., Amsler, C.D. & Angus, R.A. 2015. Multi-frequency observations of seawater carbonate chemistry on the central coast of the western Antarctic Peninsula. Polar Research, 34, 10.3402/polar.v34.25582.CrossRefGoogle Scholar
Shick, J.M. & Dunlap, W.C. 2002. Mycosporine-like amino acids and related gadusols: biosynthesis, acumulation, and UV-protective functions in aquatic organisms. Annual Reviews in Physiology, 64, 10.1146/annurev.physiol.64.081501.155802.CrossRefGoogle ScholarPubMed
Shilling, A.J., Heiser, S., Amsler, C.D., McClintock, J.B. & Baker, B.J. 2021. Hidden diversity in an Antarctic algal forest: metabolomic profiling linked to patterns of genetic diversification in the Antarctic red alga Plocamium sp. Marine Drugs, 19, 607.CrossRefGoogle Scholar
Shilling, A.J., Witowski, C.G., Maschek, J.A., Azhari, A., Vesely, B., Kyle, D.E., et al. 2020. Spongian diterpenoids derived from the Antarctic sponge Dendrilla antarctica are potent inhibitors of the Leishmania parasite. Journal of Natural Products, 83, 10.1021/acs.jnatprod.0c00025.CrossRefGoogle ScholarPubMed
Slattery, M., Starmer, J. & Paul, V.J. 2001. Temporal and spatial variation in defensive metabolites of the tropical Pacific soft corals Sinularia maxima and S. polydactyla. Marine Biology, 138, 11831193.Google Scholar
Soldatou, S. & Baker, B.J. 2017. Cold-water marine natural products, 2006 to 2016. Natural Product Reports, 34, 10.1039/c6np00127k.CrossRefGoogle ScholarPubMed
Takeuchi, I. & Watanabe, K. 2002. Mobile epiphytic invertebrates inhabiting the brown macroalga, Desmarestia chordalis under the coastal fast ice of Lutzow-Holm Bay, East Antarctica. Polar Biology, 25, 10.1007/S00300-002-0373-Z.CrossRefGoogle Scholar
Thompson, J.E., Murphy, P.T., Bergquist, P.R. & Evans, E.A. 1987. Environmentally induced variation in diterpene composition of the marine sponge Rhopaloeides odorabile. Biochemical Systematics and Ecology, 15, 10.1016/0305-1978(87)90111-6.CrossRefGoogle Scholar
Tripathi, V.C., Satish, S., Horam, S., Raj, S., Lal, A., Arockiaraj, J., et al. 2018. Natural products from polar organisms: Structural diversity, bioactivities and potential pharmaceutical applications. Polar Science, 18, 147166.CrossRefGoogle Scholar
Van Alstyne, K.L. 1988. Herbivore grazing increases polyphenolic defenses in the intertidal brown alga Fucus distichus. Ecology, 69, 655663.CrossRefGoogle Scholar
von Salm, J.L., Schoenrock, K.M., McClintock, J.B., Amsler, C.D. & Baker, B.J. 2019. The status of marine chemical ecology in Antarctica: form and function of unique high-latitude chemistry. In Puglisi, M.P. & Becerro, M.A., eds. Marine chemical ecology. Boca Raton, FL: CRC Press, 2760.Google Scholar
von Salm, J.L., Witowski, C.G., Fleeman, R.M., McClintock, J.B., Amsler, C.D., Shaw, L.N. & Baker, B.J. 2016. Darwinolide, a new diterpene scaffold thati inhibits methicillin-resistant Staphylococcus aureus biofilm from the Antarctic sponge Dendrilla membranosa. Organic Letters, 18, 10.1021/acs.orglett.6b00979.CrossRefGoogle Scholar
Wiencke, C., Amsler, C.D. & Clayton, M.N. 2014. Macroalgae. In Broyer, C.D., Koubbi, P., Griffiths, H.J., Raymond, B., d'Udekem d'Acoz, C., van de Putte, A.P., et al. , eds. Biogeographic atlas of the Southern Ocean. Cambridge: Scientific Committee on Antarctic Research, 6673.Google Scholar
Wilson, N.G., Maschek, J.A. & Baker, B.J. 2013. A species flock driven by predation? Secondary metabolites support diversification of slugs in Antarctica. PLoS ONE, 8, 10.1371/journal.pone.0080277.CrossRefGoogle ScholarPubMed
Wright, J.T., de Nys, R. & Steinberg, P.D. 2000. Geographic variation in halogenated furanones from the red alga Delisea pulchra and associated herbivores and epiphytes. Marine Ecology Progress Series, 207, 10.3354/Meps207227.CrossRefGoogle Scholar
Young, R.M., von Salm, J.L., Amsler, M.O., Lopez-Bautista, J., Amsler, C.D., McClintock, J.B. & Baker, B.J. 2013. Site-specific variability in the chemical diversity of the Antarctic red alga Plocamium cartilagineum. Marine Drugs, 11, 10.3390/md11062126.CrossRefGoogle ScholarPubMed
Zamzow, J.P., Amsler, C.D., McClintock, J.B. & Baker, B.J. 2010. Habitat choice and predator avoidance by Antarctic amphipods: the roles of algal chemistry and morphology. Marine Ecology Progress Series, 400, 10.3354/meps08399.CrossRefGoogle Scholar
Figure 0

Fig. 1. Diterpenes reported from Dendrilla antarctica.

Figure 1

Fig. 2. Image of Dendrilla antarctica and Colomastix fissilingua. D. antarctica (left) has a highly porous inner structure, which allows high densities of amphipods (top right) to inhabit the sponge.

Figure 2

Fig. 3. Map of the Palmer Station boating area. The four collection sites shown are within a 3.5 km (2 mi) radius from the station: 1) Norsel Point, 2) Bonaparte Point, 3) Gamage Point and 4) Laggard Island all surround Palmer Station (located next to Gamage Point or site 3), Anvers Island, Antarctica.

Figure 3

Table I. Amphipods found on sponges collected from habitats within (W; 0–20 m) the algal canopy and at depths below (B; 20–35 m) the algal canopy zone. Potential sponge-predator amphipods are shaded in grey.

Figure 4

Fig. 4. Quantification of Dendrilla antarctica diterpene metabolites. Variability in the concentrations of known secondary metabolites from D. antarctica found within (W) and below (B) the algal canopy from the four study sites is shown.

Figure 5

Fig. 5. Dendrogram cluster analysis of the top 100 compounds from Dendrilla antarctica. The samples (lettered) from depths represented as within the canopy region (blue triangles) and those from depths below the canopy region (black rotated triangles) are depicted. Similarity is measured as a percentage.

Figure 6

Fig. 6. 2D multidimensional scaling (MDS) ordination of the Dendrilla antarctica metabolomic profile. The MDS plot is overlaid with statistically correlated omnivorous amphipod densities (blue circles) showing a clear distinction between sponge specimens within (W) the algal canopy (right) and specimens found at depths below (B) the canopy zone (left).