新型 sp. PWN6 快速生物降解椰枣叶生产柠檬酸的确定性筛选设计与人工神经网络建模

Definitive Screening Design and Artificial Neural Network for Modeling a Rapid Biodegradation of Date Palm Fronds by a New sp. PWN6 into Citric Acid.

机构信息

Central Laboratory of Date Palm Research and Development, Agricultural Research Center, Giza 12112, Egypt.

Seed Pathology Department, Plant Pathology Institute, Agricultural Research Center, Giza 12112, Egypt.

出版信息

Molecules. 2021 Aug 20;26(16):5048. doi: 10.3390/molecules26165048.

DOI:10.3390/molecules26165048

PMID:34443635

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC8400321/

Abstract

Generally, the bioconversion of lignocellulolytics into a new biomolecule is carried out through two or more steps. The current study used one-step bioprocessing of date palm fronds (DPF) into citric acid as a natural product, using a pioneer strain of (PWN6) that has been selected from six tested isolates based on the highest organic acid (OA) productivity (195.41 µmol/g), with the lowest amount of the released glucose. sp. PWN6 was morphologically and molecularly identified, and the GenBank accession number was MW78912.1. Both definitive screening design (DSD) and artificial neural network (ANN) were applied, for the first time, for modeling the bioconversion process of DPF. Although both models are capable of making accurate predictions, the ANN model outperforms the DSD model in terms of OA production, as ANN is characterized by a higher value of R (0.963) and validation R (0.967), and lower values of the RMSE (13.44), MDA (11.06), and SSE (9749.5). Citric acid was the only identified OA as was confirmed by GC-MS and UPLC, with a total of 1.5%. In conclusion, DPF together with PWN6 is considered an excellent new combination for citric acid biosynthesis, after modeling with artificial intelligence procedure.

摘要

通常，木质纤维素转化为新生物分子是通过两步或更多步骤进行的。本研究使用一步法生物转化枣椰树叶（DPF）为柠檬酸，作为一种天然产物，使用一种从六种测试分离株中选择的先锋菌株（PWN6），该菌株基于最高的有机酸（OA）生产力（195.41 µmol/g）和最低的葡萄糖释放量。 sp。PWN6 通过形态学和分子鉴定，GenBank 登录号为 MW78912.1。首次应用确定性筛选设计（DSD）和人工神经网络（ANN）对 DPF 的生物转化过程进行建模。虽然这两种模型都能够进行准确的预测，但 ANN 模型在 OA 生产方面优于 DSD 模型，因为 ANN 的 R 值（0.963）和验证 R 值（0.967）较高，而 RMSE（13.44）、MDA（11.06）和 SSE（9749.5）的值较低。通过 GC-MS 和 UPLC 确认，柠檬酸是唯一鉴定出的有机酸，含量为 1.5%。总之，DPF 与 PWN6 一起被认为是柠檬酸生物合成的极好的新组合，经过人工智能程序建模。

https://cdn.ncbi.nlm.nih.gov/pmc/blobs/c0f6/8400321/cce8270340dc/molecules-26-05048-g001.jpg

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新型 sp. PWN6 快速生物降解椰枣叶生产柠檬酸的确定性筛选设计与人工神经网络建模

Definitive Screening Design and Artificial Neural Network for Modeling a Rapid Biodegradation of Date Palm Fronds by a New sp. PWN6 into Citric Acid.

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