Background: The Great Australian Bight (GAB) comprises the majority of Australia's southern coastline, but to date its deep water fauna has remained almost unknown. Recent issuing of oil and gas leases in the region has highlighted this lack of baseline biological data and established a pressing need to characterise benthic abyssal fauna. Methods: From 2013 to 2017, six large-scale systematic surveys of the GAB were conducted from 200 to 5000 m depth, constituting the deepest systematic biological sampling in Australia. Sampling was conducted on soft sediment and hard substrates, both at predetermined depth intervals along north-south transect lines and at sites of interest identified by multibeam sonar. Results: A total of 66,721 invertebrate specimens were collected, comprising 1267 species, with 401 species (32%) new to science. In addition to the novelty of the fauna, there was a high degree of rarity, with 31% of species known only from single specimens. Conclusions: In this paper, we provide an annotated checklist of the benthic invertebrate fauna of the deep GAB, supplemented with colour photos of live specimens and commentary on taxonomy, diversity and distributions. This work represents an important addition to knowledge of Australia's deep sea fauna, and will provide the foundation for further ecological, biogeographical and systematic research.
Rapid progress in transcriptomic and proteomic studies of sea anemones has led to the identification of a large number of new peptide sequences. Some of these peptides have high sequence similarity and identical cysteine frameworks to those of previously reported sequences. One such peptide we have identified from a transcriptomic study of Oulactis sp is OspTx2a, which has a cysteine framework similar to that of ShK (from Stichodactyla helianthus) and BgK (from Bunodosoma granulifera). This peptide was made using solid‐phase peptide synthesis, but, upon oxidative folding, it generated two peptides with identical masses (OspTx2a‐p1 and OspTx2a‐p2) that were distinguishable by high‐performance liquid chromatography. The structures of OspTx2a‐p1 and OspTx2a‐p2 were determined using nuclear magnetic resonance spectroscopy, and voltage‐clamp electrophysiology assays were performed in order to assess the activity against a range of potassium channels. The structures of the two peptides were very similar to each other and to BgK, with the same disulfide bond connectivities, and both had an all‐trans backbone conformation. In functional assays, both OspTx2a‐p1 and OspTx2a‐p2 inhibited KV1.2 and KV1.6 channel currents at low µM concentrations, with similar but not identical IC50 values. Peptides containing a C‐terminal Cys residue are particularly sensitive to racemization at this residue, and the two products obtained for OspTx2a could be a consequence of racemization of the Cys residue at its C‐terminus during synthesis. NMR chemical shift differences between the two products and their structural preferences for a d‐Cys residue were consistent with this interpretation.
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