Nuclear Genome-Encoded Mitochondrial OXPHOS Complex I Genes in Female Buffalo Show Tissue-Specific Differences.

IF 2.4 4区生物学 Q3 BIOCHEMISTRY & MOLECULAR BIOLOGY

Molecular Biotechnology Pub Date : 2025-06-01 Epub Date: 2024-06-15 DOI:10.1007/s12033-024-01206-6

E M Sadeesh, Madhuri S Lahamge, Anuj Malik, A N Ampadi

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Abstract

Buffalo physiology intricately balances energy, profoundly influencing health, productivity, and reproduction. This study explores nuclear-mitochondrial crosstalk, revealing OXPHOS Complex I gene expression variations in buffalo tissues through high-throughput RNA sequencing. Unveiling tissue-specific disparities, the research elucidates the genomic landscape of crucial energy production genes, with broader implications for veterinary and agricultural progress. Post-slaughter, tissues from post-pubertal female buffaloes underwent meticulous processing and RNA extraction using the TRIzol method. RNA-Seq library preparation and IlluminaHiSeq 2500 sequencing were performed on QC-passed samples. Data underwent stringent filtration, mapping to the Bubalus bubalis genome using HISAT2. DESeq2 facilitated differential expression gene (DEG) analysis focusing on 57 Mitocarta 3-derived genes associated with OXPHOS complex I. Nuclear-encoded mitochondrial protein transcripts of OXPHOS complex 1 exhibited tissue-specific variations, with 51 genes expressing significantly across tissues. DEG analysis emphasized tissue-specific expression patterns, highlighting a balanced OXPHOS complex I subunit expression in the kidney vs. brain. Gene Ontology (GO) enrichment showcased mitochondria-centric terms, revealing distinct proton motive force-driven mitochondrial ATP synthesis regulation. Kyoto Encyclopedia of Genes and Genomes (KEGG) pathway analyses emphasized Thermogenesis and OXPHOS pathways, enriching our understanding of tissue-specific energy metabolism. Noteworthy up-regulation of NDUFB10 in the heart and kidney aligned with heightened metabolic activity. Brain-specific up-regulation of NDUFAF6 indicated a focus on mitochondrial function, while variations in NDUFA11 and ACAD9 underscored pivotal roles in the heart and kidney. GO and KEGG analyses highlighted tissue-specific mitochondrial ATP synthesis and NADH dehydrogenase processes, providing molecular insights into organ-specific metabolic demands and regulatory mechanisms. Our study unveils conserved and tissue-specific nuances in nuclear-encoded mitochondrial OXPHOS complex I genes, laying a foundation for understanding diverse energy demands and potential health implications.

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雌性水牛核基因组编码的线粒体 OXPHOS 复合物 I 基因显示出组织特异性差异。

水牛的生理机能复杂地平衡着能量，对健康、生产力和繁殖产生着深远的影响。这项研究通过高通量 RNA 测序，揭示了水牛组织中 OXPHOS 复合物 I 基因表达的变化，探索了核与线粒体之间的相互影响。该研究揭示了组织特异性差异，阐明了关键能量生产基因的基因组图谱，对兽医和农业进步具有更广泛的意义。屠宰后，对青春期后雌性水牛的组织进行了细致的处理，并使用TRIzol方法提取RNA。RNA-Seq 文库制备和 IlluminaHiSeq 2500 测序均在通过 QC 的样本上进行。数据经过严格过滤，并使用 HISAT2 映射到 Bubalus bubalis 基因组。DESeq2促进了差异表达基因（DEG）分析，重点分析了57个与OXPHOS复合体I相关的Mitocarta 3衍生基因，OXPHOS复合体1的核编码线粒体蛋白转录本表现出组织特异性变化，其中51个基因在不同组织间有显著表达。DEG 分析强调了组织特异性表达模式，突出了肾脏与大脑中 OXPHOS 复合物 I 亚基的平衡表达。基因本体（GO）富集显示了以线粒体为中心的术语，揭示了不同的质子动力驱动的线粒体 ATP 合成调控。京都基因和基因组百科全书》（KEGG）通路分析强调了产热和氧合OS通路，丰富了我们对组织特异性能量代谢的了解。值得注意的是，NDUFB10 在心脏和肾脏的上调与代谢活动的增强相一致。脑特异性上调 NDUFAF6 表明线粒体功能受到关注，而 NDUFA11 和 ACAD9 的变化则强调了其在心脏和肾脏中的关键作用。GO 和 KEGG 分析强调了组织特异性线粒体 ATP 合成和 NADH 脱氢酶过程，为器官特异性代谢需求和调控机制提供了分子见解。我们的研究揭示了核编码线粒体 OXPHOS 复合物 I 基因的保守性和组织特异性的细微差别，为了解不同的能量需求和潜在的健康影响奠定了基础。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Molecular Biotechnology 医学-生化与分子生物学

CiteScore

4.10

自引率

3.80%

发文量

165

审稿时长

6 months

期刊介绍： Molecular Biotechnology publishes original research papers on the application of molecular biology to both basic and applied research in the field of biotechnology. Particular areas of interest include the following: stability and expression of cloned gene products, cell transformation, gene cloning systems and the production of recombinant proteins, protein purification and analysis, transgenic species, developmental biology, mutation analysis, the applications of DNA fingerprinting, RNA interference, and PCR technology, microarray technology, proteomics, mass spectrometry, bioinformatics, plant molecular biology, microbial genetics, gene probes and the diagnosis of disease, pharmaceutical and health care products, therapeutic agents, vaccines, gene targeting, gene therapy, stem cell technology and tissue engineering, antisense technology, protein engineering and enzyme technology, monoclonal antibodies, glycobiology and glycomics, and agricultural biotechnology.