Discovery of Highly Conserved Evolutionary Regions in Polyhydroxyalkanoate Synthase (PhaC) From Pseudomonas sp. Using Bioinformatics and In-silico Approaches

International Journal of Scientific and Research Publications (IJSRP) Pub Date : 2022-07-24 DOI:10.29322/ijsrp.12.07.2022.p12702

Ubaid Mehmood, Faiza Muneer, Xiao Junhua, H. Nadeem

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Abstract

- Microbial polyesters such as polyhydroxyalkanoates (PHAs) are biopolymers with unique physicochemical and thermal properties that can replace synthetic polymers from the environment. The ability of these polymers to aid multiple processes in pharmaceuticals, drug delivery systems, and bioplastic materials has increased their worth in the polymer industry. Polyhydroxyalkanoate synthase (PhaC) has a crucial role in the biosynthesis of PHA and is produced by various microbes. Pseudomonas strains have a high potential to produce PhaC. Due to limited structural, functional, and phylogenetic studies of the PhaC, its important evolutionary and underlying molecular functional characteristics remain unknown. This study envisaged finding out the phylogenetic relation, conserved motifs, and 3D structural coherence in PhaC for various species of the Pseudomonas . Three highly regions conserved evolutionary regions named R1, R2, and R3 were identified in forty strains of Pseudomonas including five conserved regions in each phylogenetic group formed. R1 with amino acid sequence of (Arg-263)-(Glu-264)-(Trp-265)-(Gly-266)-(Leu-267), R2 with (Phe-367)-(Ala-368)-(Trp-369)-(Met-370)-(Arg-371)-(Pro-372)-(Asn-373)-(Asp-374)-(Leu-375)-(Ile-376) and R3 having (Asp-452)-(His-453)-(Ile-454)-(Thr-455)-(Pro-456)-(Trp-457) amino acid sequence were determined. Ramachandran plot analysis for the PhaC of P. fluorescens, P. stutzeri, P. putida, P. aeruginosa , and P. syringae suggested that nearly 87% of the residues of PhaC are in favored regions with 11-12% in additionally allowed and 1-2% in allowed regions. This study has confirmed for the first time the presence of three highly conserved in the PhaC protein of the Pseudomonas genus additionally with conserved sites in each phylogenetic group that can help in understanding and improving the function of this protein in the future. Comparative analysis of PhaC 3-D structures for Chromobacterium sp. USM2 and Ralstonia eutropha with the predicted structures of PhaC of Pseudomonas strains was performed. It showed that the binding ability of the catalytic site of Pseudomonas strains is different as compared to that already predicted in Chromobacterium sp. USM2 (PDB ID 6K3C), Ralstonia

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利用生物信息学和计算机技术发现假单胞菌聚羟基烷酸合酶高度保守的进化区域

微生物聚酯，如聚羟基烷酸酯(pha)是具有独特的物理化学和热性能的生物聚合物，可以取代从环境中合成的聚合物。这些聚合物在制药、药物输送系统和生物塑料材料的多个过程中的辅助能力增加了它们在聚合物工业中的价值。聚羟基烷酸合成酶(PhaC)在PHA的生物合成中起着至关重要的作用，由多种微生物产生。假单胞菌菌株产生PhaC的潜力很大。由于PhaC的结构、功能和系统发育研究有限，其重要的进化和潜在的分子功能特征仍然未知。本研究设想找出不同种类假单胞菌PhaC的系统发育关系、保守基序和三维结构一致性。在40株假单胞菌中鉴定出3个高度区域保守的进化区R1、R2和R3，其中每个形成的系统发育群中有5个保守区。R1具有(Arg-263)-(Glu-264)-(Trp-265)-(Gly-266)-(Leu-267)氨基酸序列，R2具有(phe367)-(Ala-368)-(Trp-369)-(Met-370)-(Arg-371)-(Pro-372)-(Asn-373)-(Asp-374)-(Leu-375)-(Ile-376)氨基酸序列，R3具有(Asp-452)-(His-453)-(Ile-454)-(Thr-455)-(Pro-456)-(Trp-457)氨基酸序列。对P. fluorescens、P. stutzeri、P. putida、P. aeruginosa和P. syringae的PhaC进行Ramachandran图分析，结果表明，PhaC在有利区残基占近87%，在额外允许区残基占11-12%，在允许区残基占1-2%。本研究首次证实了假单胞菌属PhaC蛋白中存在3个高度保守的位点，并且在每个系统发育群中都有保守位点，这有助于今后了解和改善该蛋白的功能。对嗜铬杆菌USM2和富营养化Ralstonia PhaC的三维结构与假单胞菌PhaC的预测结构进行了比较分析。结果表明，假单胞菌菌株催化位点的结合能力与先前预测的在Ralstonia的Chromobacterium sp. USM2 (PDB ID 6K3C)中有所不同

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International Journal of Scientific and Research Publications (IJSRP)

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