Effect of Partial Elimination of Mitochondrial DNA on Genome-Wide Identified AOX Gene Family in Chlamydomonas reinhardtii

IF 2.8 4区工程技术 Q2 ENGINEERING, CHEMICAL

Processes Pub Date : 2024-08-07 DOI:10.3390/pr12081654

Asadullah Khan, Zuo Jihong, Haolin Luo, Ali Raza, Quaid Hussain, Zhangli Hu

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Abstract

Using Chlamydomonas as a model organism, we attempted to eliminate mitochondrial DNA (mtDNA) similar to rho0 or rho− cells (completely or partially mtDNA-eliminated cells) in yeast. We successfully generated partially mtDNA-eliminated cells named as crm- cells, causing the inactivation of mitochondrial activity. We used three different chemicals to eliminate mtDNA including acriflavine (AF), ethidium bromide (EB) and dideoxycytidine (ddC) which prevents replication, inhibits POLG (DNA polymerase gamma) and terminates the mtDNA chain, respectively. The qPCR method was used to detect the mtDNA copy number and the selected rrnL6 gene for the detection of mitochondria, as well as the selected Chlamydomonas CC-124 strain. A reduction in the mitochondrial copy number led to a higher expression of AOX1, UCP1, PGRL1 and ICL1, which indicates the disturbance of the mitochondria–chloroplast ATP and NADPH balance. We selected AOX genes to further study this family and carried out a genome-wide search to identify AOX genes in green algae (C. reinhardtii). Our results revealed that C. reinhardtii contains four AOX genes, i.e., CrAOX1, CrAOX2, CrAOX3 and CrAOX4, which are distributed on Chr 3, Chr7 and Chr9. All CrAOX genes were predicted to localize in mitochondria using bioinformatics tools. Phylogenetic analysis suggests that these CrAOXs are subdivided into four groups and genes existing in the same group could perform identical functions. Collinearity analysis describes the strong evolutionary relationships of AOXs between the unicellular green algae Chlamydomonas reinhardtii and the multicellular green algae Volvox carteri. GO (gene ontology) annotation analysis predicted that CrAOXs played an integral part in carrying out alternate oxidative and respirative activities. Three putative miRNAs, cre-miR1162-3p, cre-miR1171 and cre-miR914, targeting the CrAOX2 gene were identified. Our studies have laid a foundation for the further use of partially mtDNA-eliminated cells and elucidating the functional characteristics of the AOX gene family.

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部分消除线粒体 DNA 对衣藻全基因组已识别 AOX 基因家族的影响

我们以衣藻为模式生物，尝试消除线粒体 DNA（mtDNA），类似于酵母中的 rho0 或 rho- 细胞（完全或部分消除 mtDNA 的细胞）。我们成功生成了部分去除 mtDNA 的细胞，命名为 crm- 细胞，导致线粒体活性失活。我们使用了三种不同的化学物质来消除 mtDNA，包括吖啶黄（AF）、溴化乙锭（EB）和双脱氧胞苷（ddC），它们分别能阻止复制、抑制 POLG（DNA 聚合酶 gamma）和终止 mtDNA 链。采用 qPCR 方法检测 mtDNA 拷贝数和用于检测线粒体的 rrnL6 基因，以及所选的衣藻 CC-124 菌株。线粒体拷贝数的减少导致了 AOX1、UCP1、PGRL1 和 ICL1 的高表达，这表明线粒体-叶绿体 ATP 和 NADPH 平衡被打破。我们选择了 AOX 基因来进一步研究这个家族，并进行了全基因组搜索，以确定绿藻（C. reinhardtii）中的 AOX 基因。结果发现，绿藻含有四个 AOX 基因，即 CrAOX1、CrAOX2、CrAOX3 和 CrAOX4，它们分布在 Chr 3、Chr7 和 Chr9 上。利用生物信息学工具预测，所有 CrAOX 基因都定位于线粒体。系统发育分析表明，这些 CrAOX 基因可细分为四组，同一组中的基因可发挥相同的功能。共线性分析表明，AOXs 在单细胞绿藻 Chlamydomonas reinhardtii 和多细胞绿藻 Volvox carteri 之间有很强的进化关系。GO（基因本体）注释分析预测，CrAOXs 在交替进行氧化和呼吸活动中发挥着不可或缺的作用。研究还发现了三个靶向 CrAOX2 基因的假定 miRNA，即 cre-miR1162-3p、cre-miR1171 和 cre-miR914。我们的研究为进一步利用部分去除了mtDNA的细胞和阐明AOX基因家族的功能特点奠定了基础。

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来源期刊

Processes Chemical Engineering-Bioengineering

CiteScore

5.10

自引率

11.40%

发文量

2239

审稿时长

14.11 days

期刊介绍： Processes (ISSN 2227-9717) provides an advanced forum for process related research in chemistry, biology and allied engineering fields. The journal publishes regular research papers, communications, letters, short notes and reviews. Our aim is to encourage researchers to publish their experimental, theoretical and computational results in as much detail as necessary. There is no restriction on paper length or number of figures and tables.