Mitochondrial genetics as a determinant of bone health

线粒体遗传学是骨骼健康的决定因素

基本信息

批准号：
10349639
负责人：
Roman Eliseev
金额：
$ 20.33万
依托单位：
UNIVERSITY OF ROCHESTER
依托单位国家：
美国
项目类别：
财政年份：
2022
资助国家：
美国
起止时间：
2022-09-20 至 2024-08-31
项目状态：
已结题

来源：
https://reporter.nih.gov/project-details/10349639
关键词：
ATAC-seq Affect African ancestry Aging Alabama Bioenergetics Bone Marrow Bone Tissue Brain Cells Chromatin Climate Cold Climate Communication Data Energy Metabolism Epigenetic Process Female Foundations Gene Expression Genes Genetic Genetic Models Genetic study Genome Goals Haplogroup Haplotypes Histology Homeostasis Human In Vitro Inherited Knowledge Label Literature Maintenance Measures Mesenchymal Stem Cells Mission Mitochondria Mitochondrial DNA Mitochondrial Diseases Modeling Mus Myocardium Nuclear Nude Mice Organelles Osteoblasts Osteoclasts Osteogenesis Osteoporosis Oxidative Phosphorylation Pathology Patients Pattern Persons Phenotype Physiology Play Population Study Predisposition Public Health Reporting Research Role Signal Transduction Testing Tissues United States National Institutes of Health Universities biomechanical test bone bone aging bone fragility bone health disability high risk metabolomics microCT mitochondrial dysfunction novel osteogenic osteoprogenitor cell premature subcutaneous targeted treatment tool trait transcriptome sequencing zygote

项目摘要

Abstract The role of mitochondria in bone tissue physiology and pathology remains understudied. Our long-term goal is to fill this gap of knowledge and this high risk proposal is a step towards this goal. It will test if mitochondrial genetics (mtDNA haplotype) influences bone phenotype and function of osteoblasts (OB) and their precursors, bone marrow stromal (a.k.a. mesenchymal stem) cells (BMSCs). The scientific premise here is that: 1) mitochondrial oxidative phosphorylation (OxPhos) is required for osteogenic differentiation; 2) mitochondrial dysfunction plays a significant role in bone aging; 3) patients with mitochondrial diseases have fragile bones; 4) Eurasians with ‘less efficient’ mtDNA haplogroups developed as an adaptation to cold climate, also have weaker bones when compared to people of African descent with ‘more efficient’ mtDNA haplogroup L; and 5) C3H/HeN (C3H) mice with more efficient mtDNA haplotype, also have stronger bones then C57BL/6J (C57) mice with less efficient mtDNA haplotype. To study contributions of nuclear vs mtDNA genome to a phenotype, we will use a delicate new genetic model, mitochondrial/nuclear exchange (MNX) mice. These MNX mice have C57 or C3H nuclear background but C3H and C57 mtDNA, respectively (C57n;C3Hmt and C3Hn;C57mt). Cells in these mice show OxPhos activity according to their mtDNA haplotype rather than their nuclear background. Our pilot data show that C57n;C3Hmt BMSCs have higher, while C3Hn;C57mt BMSCs have lower osteogenic potential than their corresponding controls, C57 and C3H, respectively. We also observed that bone accrual in 3 mo old F mice reflected their mtDNA haplogroup (C57n;C3Hmt > C57 while C3Hn;C57mt < C3H). Our central hypothesis that mitochondrial genetics is a strong determinant of BMSC osteogenic potential, OB bone-forming function, and bone phenotype. To test it, we will determine if MNX mice have altered bone phenotype (Aim 1) and altered BMSC osteogenic and OB bone-forming function and mitochondrio-nuclear communication (Aim 2) when compared to their wild type controls. If successful, this project will lay strong foundation for a new direction in our research and bone field in general, mitochondrial genetics of bone.

抽象的线粒体在骨组织生理学和病理学中的作用仍有待研究。是为了填补这一知识空白，而这个高风险提案是朝着这一目标迈出的一步，它将测试线粒体是否存在。遗传学（mtDNA 单倍型）影响成骨细胞（OB）及其前体的骨表型和功能，骨髓基质（又名间充质干）细胞 (BMSC) 的科学前提是：1) 成骨分化需要线粒体氧化磷酸化 (OxPhos) 2) 线粒体；功能障碍在骨骼衰老中起着重要作用；3）患有线粒体疾病的患者骨骼脆弱；4）为适应寒冷气候而发展起来的线粒体DNA单倍群效率“较低”的欧亚人，其线粒体DNA单倍群的效率也较弱与具有“更高效”mtDNA 单倍群 L 的非洲人后裔相比，其骨骼更佳；5) C3H/HeN 具有更有效 mtDNA 单倍型的 (C3H) 小鼠，也比具有较少 mtDNA 单倍型的 C57BL/6J (C57) 小鼠具有更强的骨骼有效的 mtDNA 单倍型为了研究核基因组与 mtDNA 基因组对表型的贡献，我们将使用精致的新遗传模型，线粒体/核交换 (MNX) 小鼠这些 MNX 小鼠具有 C57 或 C3H。核背景，但分别为 C3H 和 C57 mtDNA（这些小鼠中的细胞为 C57n；C3Hmt 和 C3Hn；C57mt）。根据其 mtDNA 单倍型而不是我们的试验数据显示 OxPhos 活性。结果表明，C57n;C3Hmt BMSCs 具有较高的成骨潜力，而 C3Hn;C57mt BMSCs 的成骨潜力低于其我们还分别观察到 3 个月大的 F 小鼠的骨生成情况。反映了它们的 mtDNA 单倍群（C57n;C3Hmt > C57 而 C3Hn;C57mt < C3H）。线粒体遗传学是 BMSC 成骨潜力、OB 成骨功能和为了测试它，我们将确定 MNX 小鼠是否改变了骨表型（目标 1）并改变了。 BMSC 成骨和 OB 成骨功能以及线粒体-核通讯（目标 2）与野生型对照相比，如果成功，该项目将为我们的新方向奠定坚实的基础。研究和骨领域一般，骨的线粒体遗传学。