Metebolomics and Immunology Cultivation

hliu092

This journal article is previously published as: Liu Huan. (2021). Metabolomics and Immunology Cultivation. Journal of Environment and Health Science (ISSN 2314-1628), 2021(02). https://doi.org/10.58473/JBS0008, which is converted into Journal of Biological Sciences (ISSN 2958-4035). Both Journals belong to the same publisher, Liu Huan. The previous journal article is closed to the public, but the previous reference is still valid.

2023. Copyrights Certificate Registered by Brock Chain Technology: Brock Chain ID. (8444745e9b2991dadf50bb061e9d267e113e23ec03cdd77523d88e55ce345f50) ;

2016. Copyrights Register Information: The majority of these materials are registered as book '著作权人：刘焕；作品：《研究生文凭进展（第三版）》' 2016, which can be cataloged in National Copyright Database: http://qgzpdj.ccopyright.com.cn/

2016. 版权注册信息：本文大多数内容已经以图书形式登记注册在全国版权数据库，登记入库信息：著作权人：刘焕；作品：《研究生文凭进展（第三版）》 2016;可在全国版权登记数据库检索 http://qgzpdj.ccopyright.com.cn/

The formally published serials is the printing <Journal of Biological Sciences (ISSN 2958-4035)>, and the serials NO. is the month/year when the materials is accessible on this website, authorized by publisher；正式发表的期刊是印刷版《生物科学杂志 (ISSN 2958-4035)》，期刊期号为文章内容在本网站上网年/月，出版人许可自行正式发表。

Originality Certificate: The originality of text in English is 99% tested by Turnitin (International). The Turnitin Originality Report is attached in PDF summary.

All Copyrights Reserved.

Latest revised on 29/05/2023.

Article Download (Google Drive)   Open Access Repository-Zenodo

论文下载（提取码: yvbn，百度网盘链接与提取码仅仅允许本香港主机网站用户使用，禁止转载）

Cited as: DOI: 10.58473/JBS0008      Retrieval from official database: www.crossref.org

Scilit Database Retrieval URL : Link    Researchgate Retrieval URL: Link

Web of Science Retrieval URL: https://publons.com/wos-op/publon/66151035/

Bielefeld Academic Search Engine: Link     PlumX Metrics: Link

Article 6-1: Metebolomics and Immunology Cultivation /新陈代谢组学与免疫力培养

Author: Liu Huan (1983-), Master of Science (First Class Honours,2009), The University of Auckland. ORCID: https://orcid.org/0000-0003-4881-8509

Introduction

This article designs a novel method to analyze the isozyme electrophoretograms across different isozyme families, targeting the cultivation of environmental adaptiveness or immunology.

Methods:

The same strain of microbes is divided into two samples for the bio-signal simulation:

1.There are two kinds of cultivation conditions simulated in Lab for microbe reproduction process: one is the ‘comfortable’ condition (Sample 1); the other is under UV-B radiation for cultivation (Sample 2). The microbe samples are collected after sufficient reproduction process (at least ten generations).

2.After sufficient reproduction process, the UV-B radiation simulation stops. Then both sample 1 and sample 2 are separately transferred into moisture simulation process: different moisture conditions of microbial cultivation are simulated in Lab, and labeled as T1, T2, ..., Tn.

3.Metabolomics tests are conducted after moisture simulation of T1, T2, ..., Tn respectively, resulting in different zymograms as: M1, M2, ..., Mn. The procedure of this test is presented in previous article of this journal[2].

4.Each isozyme family is labeled as 1, 2, 3..., and E; It is hypothesized that the bands at the same line across different isozyme families are the enzyme species at the same locus, named as enzyme ‘species i’ (i = 1, 2, ..., I), and each isozyme family has the same amount (I) of enzyme species (Please note: this is different from the identification of real enzyme species). Then there is a 3-dimension (I× E × N) matrix presented in this research. I is the total amount of enzyme species within a isozyme family; E is the total amount of isozyme families; N is the total amount of zymograms among different simulated moisture conditions:

5.Then there is a 3-dimension (I× E × N) matrix presented in this research. I is the total amount of enzyme species within a isozyme family; E is the total amount of isozyme families; N is the total amount of zymograms among different simulated moisture conditions:

X= │Xien │( i = 1, 2, ....I; e = 1, 2, .... E; n= 1, 2, ... N) (See PDF Article)

Xien is the occurrence of enzyme ‘species i’ in the isozyme ‘family e’ during simulated moisture condition Tn. The value of Xien is one or zero. If the electrophoresis band occurs at this locus, the value is one;otherwise it is zero. The matrix X is below:

                                                                             (See PDF Article)

Matrix Se = Xe × (Xe)T , where Xe = │Xin│( i = 1, 2, ....I; n= 1, 2, ... N); (Xe)T is the transpose of the matrix Xe. The matrix Xe is below:

The Principal Components Analysis (PCA) method of matrix X is specified [1]. However, the overall matrix X can be divided by sub-factors: PCA is firstly conducted on the basis of matrix Se, revealing the biochemical dynamics of a isozyme ‘family e’ among different simulated moisture conditions. In matrix Se, it is hypothesized that the variable in PCA represents the biochemistry dynamics of each enzyme ‘species i’.

Matrix S = (e = 1, 2, ..., E) (See PDF Article)

PCA is further conducted on the basis of matrix S, revealing the biochemical dynamics among different isozyme families over the whole simulated moisture conditions. In matrix S, it is hypothesized that the variable in PCA represents the biochemistry dynamics of each enzyme ‘species i’ across all the isozyme families. Further application has been discussed in later articles of this journal.

6.However, for the comparison between sample 1 and sample 2, this article needs to present more procedures for subsequent analysis: in matrix Se, the biochemistry dynamics of the first three enzyme species, which contribute to the most variations by PCA in an isozyme family, are selected for comparison between sample 1 and sample 2; in matrix S, the biochemistry dynamics of the first three enzyme species, which contribute to the most variations by PCA across all the isozyme families, are selected for comparison between sample 1 and sample 2; the sum percentages of the first three enzyme species in an isozyme family (= the sum Variance Contribution Ratio (VCR) of the first three enzyme species in matrix Se), represents the total variation of an isozyme family over the whole simulated moisture conditions; the sum percentages of the first three enzyme species across all the isozyme families (= the sum Variance Contribution Ratio (VCR) of the first three enzyme species in matrix S), represents the variation of the total zymograms over the whole simulated moisture conditions. Finally, the sum VCP are compared between sample 1 and sample 2.

Discussion

1.The higher variation in biochemical dynamics of enzyme expression, the better environmental adaptiveness or immunology. It is deduced that the biochemistry dynamics of the first three isozyme families (the sum VCR), which explain the highest variation by PCA, determines the conclusion of this comparison;

2.It is expected that sample 2 leads to higher variation in biochemical dynamics of enzyme expression, in terms of the higher sum VCR, which is also revealed by the higher adaptiveness during drought stress or higher immunology.

3.The findings of this article further support the theory proposed by other articles of this journal: the memory of cells can be ‘trained’ by the biophysical simulation in site, indicated by the zymograms in metabolomics test. Consequently, the memory of cells, in terms of identifying the bio-signals of a specific environmental factor (can be biotic or abiotic) triggering the gene expression for environmental adaptiveness or immunology, can be trained and strengthened by the biophysical simulation of other environmental factors, because multiple gene traits of environmental adaptiveness or immunology should be located in the same linkage group of genome. The next article (biophysical simulation for blood cell division) further supports above theories (please note: the theory, ‘memory’ of gene expression, is also applicable on cell division in an individual) by assessment of resistance or immunology in host cells.

This is the revised materials in book “Proceedings for Degree of Postgraduate Diploma in Environmental Science (3rd Edition).” Published in 2016. The ‘chapter’ content mentioned in this article is in previous book. Firstly Revised on 05/01/2021; Secondly Revised on 04/02/2021; Thirdly revised on 25/09/2021; Fourthly Revised on 22/12/2021.This journal article is previously published as: Liu Huan. (2021). Article 10-1: Metebolomics and Immunology Cultivation. Journal of Environment and Health Science (ISSN 2314-1628), 2021(02)., which is converted into Journal of Biological Sciences (ISSN 2958-4035). Both Journals belong to the same publisher, Liu Huan. The previous journal article is closed to the public, but the previous reference is still valid. Latest revised on 18/04/2023; 29/05/2023.

References:

[1] 陶玲，任裙 （2004）。进化生态学的数量研究方法。第一章，第六节，第 49 页。中国林业出版社。ISBN：7-5038-3735-7。

[2]. Liu Huan (2021), Article 7: Metabolomics (1) --- The Systematic Chemistry Fingerprints Between Genotype and Phenotype and its Application on the Conservation Genetics. Serial in Feb, 2021. Journal of Environment and Health Science.  https://doi.org/10.58473/JBS0005