Pemodelan protein dan analisis molecular docking enzim β-glukanase solat Bacillus subtilis W3.15

E-Journal Menara Perkebunan Pub Date : 2023-04-28 DOI:10.22302/iribb.jur.mp.v91i1.523

Ainia Hanifitri, L. Ambarsari, N. R. Mubarik

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Abstract

The β-glucanase enzyme is an enzyme protein that can hydrolyze β-glucan, one of the main components of the fungal cell wall. This enzyme protein is produced by several bacteria, one of which is B. subtilis. The three-dimensional (3D) structure of proteins is necessary to understand their properties and functions of proteins. Enzyme proteins can be analyzed for their structure and function using in silico method. This study aims to detect the β-glucanase gene from B. subtilis W3.15 and analyze it using the in silico method. The methods in this research are homology modeling and molecular docking analyses. Modeling was carried out using the SWISS-MODEL server and docking analysis using the PLANTS 1.1 program. Modeling the β-glucanase enzyme is based on the template of the β-glucanase enzyme protein model with PDB code 3o5s. The results of sequence alignment and model visualization were quite good as indicated by the model having a Ramachandran Plot value in the favored area of 91.10 %, a MolProbity score of 0.95, and a QMEAN value of 0.90 ± 0.06. The β-glucanase enzyme model was then docked using the PLANTS1.1 program with native ligand B3P, 1,4-β-D-Glucan, D-glucose, β-D-Glucan from oats, and N-Acetyl glucosamine. The results of docking analysis showed that the β-glucan ligand (β-D-glucan from oats) used as a substrate in the cultivation of isolate B. subtilis W3.15 had a better binding energy prediction value compared to the B3P ligand, which is a natural ligand in the template proteins. [Keywords: β-Glucan, β-D-Glucan from oat, ligand, PLANTS 1.1, 3D structure, SWISS-MODEL]

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β-葡聚糖酶是一种能够水解真菌细胞壁主要成分之一β-葡聚糖的酶蛋白。这种酶蛋白是由几种细菌产生的，其中一种是枯草芽孢杆菌。蛋白质的三维结构是了解蛋白质性质和功能的必要条件。酶蛋白的结构和功能可以用计算机分析方法进行分析。本研究旨在对枯草芽孢杆菌W3.15中β-葡聚糖酶基因进行检测，并采用硅基法对其进行分析。本研究采用同源建模和分子对接分析方法。采用SWISS-MODEL服务器进行建模，采用PLANTS 1.1程序进行对接分析。β-葡聚糖酶的建模是基于PDB代码为3o5s的β-葡聚糖酶蛋白模型模板。结果表明，该模型的Ramachandran Plot值为91.10%，MolProbity评分为0.95,QMEAN值为0.90±0.06。然后使用PLANTS1.1程序将β-葡聚糖酶模型与天然配体B3P、1,4-β- d -葡聚糖、d -葡萄糖、燕麦β- d -葡聚糖和n -乙酰氨基葡萄糖进行对接。对接分析结果表明，与模板蛋白中的天然配体B3P配体相比，在培养枯草芽孢杆菌W3.15分离物时，作为底物的β-葡聚糖配体(来自燕麦的β- d -葡聚糖)具有更好的结合能预测值。[关键词:β-葡聚糖，燕麦β- d -葡聚糖，配体，PLANTS 1.1, 3D结构，SWISS-MODEL]

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E-Journal Menara Perkebunan

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