Rab7 Investigation Insights into the Existence of White Spot Syndrome Virus in Crustaceans: An In Silico Approach.

IF 1.1 Q4 VIROLOGY Advances in Virology Pub Date : 2022-10-20 eCollection Date: 2022-01-01 DOI:10.1155/2022/3887441
Mehedi Mahmudul Hasan, M Nazmul Hoque, Md Robiul Hasan, Mohammad Asaduzzaman, Farha Matin Juliana
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引用次数: 1

Abstract

In this study, previously published Rab7 sequences from National Center for Biotechnology Information (NCBI) have been investigated from chordates, mollusks, annelids, cnidarians, amphibians, priapulids, brachiopods, and arthropods including decapods and other groups. Among decapod crustacean isolates, amino acid variations were found in 13 locations. Penaeid shrimps had variations in positions 13 (I ⟶ J), 22 (T ⟶ A), 124 (G ⟶ X), and 149 (V ⟶ X) while interestingly the freshwater prawn and mitten crab both had amino acid substitutions in positions 87 (V ⟶ C) and 95 (T ⟶ S) along with the other disagreements in amino acid positions 178 (S ⟶ N), 201 (D ⟶ E), 181 (E ⟶ D), 182 (L ⟶ I), 183 (Y ⟶ G), 184 (N ⟶ H), and 198 (A ⟶ T). Among 100 isolates of Rab7 from organisms of various phyla, mutations were observed in several positions. These mutations caused variations in hydrophobicity and isoelectric point which impact the ligand-protein binding affinity. Some common mutations were found in the organisms of the same phylum and among different phyla. Homology modeling of Rab7 proteins from different organisms was done using SWISS-MODEL and validated further by developing Ramachandran plots. Protein-protein docking showed that active residues were there in the binding interfaces of Rab7 from organisms of seven different phyla and VP28 of WSSV. Similarities were observed in the Rab7-VP28 complexes in those selected organisms which differed from the Rab7-VP28 complex in the case of Penaeid shrimp. The findings of this study suggest that WSSV may exist in different marine organisms that have Rab7 protein and transmit to crustaceans like shrimps and crabs which are of commercial importance.

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白斑综合征病毒在甲壳类动物中存在的调查见解:计算机方法
本研究利用国家生物技术信息中心(NCBI)先前公布的Rab7序列,对脊索动物、软体动物、环节动物、刺胞动物、两栖动物、原肢动物、腕足动物和节肢动物(包括十足动物)等群体进行了研究。在十足类甲壳类分离物中,有13个位点存在氨基酸变异。Penaeid虾在位置变化13(我⟶J), 22 (T⟶),124 (G⟶X)和149 (V⟶X),而有趣的是淡水虾和中华绒蝥蟹氨基酸替换87年职位(V⟶C)和95 (T⟶S)以及其他分歧在氨基酸位置178 (S⟶N), 201 (D⟶E), 181 (E⟶D), 182 (L⟶I), 183 (Y⟶G)、184 (N⟶H)和198(⟶T)。从不同门的生物中分离到的100株Rab7在多个位置发生了突变。这些突变引起疏水性和等电点的变化,从而影响配体与蛋白质的结合亲和力。在同一门和不同门的生物中发现了一些共同的突变。利用SWISS-MODEL对来自不同生物的Rab7蛋白进行了同源性建模,并通过Ramachandran图进一步验证。蛋白-蛋白对接结果表明,7个不同门生物的Rab7与WSSV的VP28结合界面存在活性残基。与对虾的Rab7-VP28复合物不同,所选生物的Rab7-VP28复合物具有相似性。本研究结果表明,WSSV可能存在于含有Rab7蛋白的不同海洋生物中,并传播给具有重要商业价值的虾、蟹等甲壳类动物。
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CiteScore
2.30
自引率
0.00%
发文量
23
审稿时长
22 weeks
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