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W2972154328 abstract "Alicella gigantea (Alicelloidae) is a scavenger with the largest body size among amphipods. It is a participant in the foodweb of deepsea ecosystem and distributed with vast bathymetric and geographic ranges. In this study, the mitochondrial genome of A. gigantea was completely assembled and characterized. The complete sequence has a total length of 16,851 bp, comprising the usual eukaryotic components, with 13 protein-coding genes (PCGs), 2 ribosomal RNA genes (rRNAs), 22 transfer RNA genes (tRNAs), and 2 noncoding control regions (CRs). The gene rearrangement and reverse nucleotide strand bias of its mitochondrial genome are similar to those observed in the deepsea amphipod Eurythenes maldoror (Eurytheneidae), but different from the characters of Halice sp. MT-2017 (Dexaminoidea), an inhabitant of a deeper environment. Phylogenetic analysis indicates that A. gigantea occupies the basal branch of deepsea species—E. maldoror and Hirondellea gigas. This phylogeny supports the hypothesis that the evolution of hadal amphipods has undergone a transition from the abyssal depth. Compared to 41 available shallow water equivalents, the four accessible mitochondrial genomes from the deep sea, including the one produced in this study, show significantly fewer charged amino acids in the 13 PCGs, which suggests an adaption to the deepsea environment." @default.
W2972154328 created "2019-09-12" @default.
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W2972154328 date "2019-12-01" @default.
W2972154328 modified "2023-09-30" @default.
W2972154328 title "The complete mitochondrial genome of the largest amphipod, Alicella gigantea: Insight into its phylogenetic relationships and deep sea adaptive characters" @default.
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W2972154328 cites W1563514911 @default.
W2972154328 cites W1789737750 @default.
W2972154328 cites W1963957860 @default.
W2972154328 cites W1972231653 @default.
W2972154328 cites W1974116356 @default.
W2972154328 cites W1974222493 @default.
W2972154328 cites W1983102293 @default.
W2972154328 cites W1987546636 @default.
W2972154328 cites W1989083100 @default.
W2972154328 cites W2003488151 @default.
W2972154328 cites W2006831581 @default.
W2972154328 cites W2007624454 @default.
W2972154328 cites W2014995392 @default.
W2972154328 cites W2025037653 @default.
W2972154328 cites W2025489215 @default.
W2972154328 cites W2025504839 @default.
W2972154328 cites W2026197201 @default.
W2972154328 cites W2033135097 @default.
W2972154328 cites W2047977243 @default.
W2972154328 cites W2053141782 @default.
W2972154328 cites W2058286752 @default.
W2972154328 cites W2061646041 @default.
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W2972154328 cites W2120902911 @default.
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W2972154328 cites W2124141733 @default.
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W2972154328 cites W2128863631 @default.
W2972154328 cites W2131271579 @default.
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W2972154328 cites W2138618895 @default.
W2972154328 cites W2141157874 @default.
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W2972154328 cites W2146058063 @default.
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W2972154328 cites W2149429041 @default.
W2972154328 cites W2155858493 @default.
W2972154328 cites W2156592409 @default.
W2972154328 cites W2157748357 @default.
W2972154328 cites W2160378127 @default.
W2972154328 cites W2164017550 @default.
W2972154328 cites W2170551349 @default.
W2972154328 cites W2177477838 @default.
W2972154328 cites W2343595506 @default.
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W2972154328 cites W4241520600 @default.
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W2972154328 doi "https://doi.org/10.1016/j.ijbiomac.2019.09.050" @default.
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