Ban Tadato, Kuroda Kimiya, Nishigori Mitsuhiro, Yamashita Keisuke, Ohta Keisuke, Koshiba Takumi
Department of Protein Biochemistry, Institute of Life Science, Kurume University, Fukuoka, Japan.
Department of Chemistry, Faculty of Science, Fukuoka University, Fukuoka, Japan.
J Biol Chem. 2025 Jan;301(1):108076. doi: 10.1016/j.jbc.2024.108076. Epub 2024 Dec 13.
Prohibitins (PHBs) are ubiquitously expressed proteins in the mitochondrial inner membrane (MIM) that provide membrane scaffolds for both mitochondrial proteins and phospholipids. Eukaryotic PHB complexes contain two highly homologous PHB subunits, PHB1 and PHB2, which are involved in various cellular processes, including metabolic control through the regulation of mitochondrial dynamics and integrity. Their mechanistic actions at the molecular level, however, particularly those of PHB1, remain poorly understood. To gain insight into the mechanistic actions of PHB1, we established an overexpression system for the full-length recombinant protein using silkworm larvae and characterized its biophysical properties in vitro. Using recombinant PHB1 proteoliposomes reconstituted into MIM-mimicking phospholipids, we found that PHB1 forms an oligomer via its carboxy-terminal coiled-coil region. A proline substitution into the PHB1 coiled-coil collapsed its well-ordered oligomeric state, and its destabilization correlated with mitochondrial morphologic defects. Negative-staining electron microscopy revealed that homotypic PHB1-PHB1 interactions via the coiled-coil also induced liposome tethering with remodeling of the lipid membrane structure. We clarified that PHB1 promotes membrane fusion mediated by optic atrophy 1 (OPA1), a key regulator of MIM fusion. Additionally, the presence of PHB1 reduces the dependency of lipids and OPA1 for completing the fusion process. Our in vitro study provides structural insight into how the mitochondrial scaffold plays a crucial role in regulating mitochondrial dynamics. Modulating the structure and/or function of PHB1 may offer new therapeutic potential, not only for mitochondrial dysfunction but also for other cell-related disorders.
prohibitin(PHB)是线粒体内膜(MIM)中普遍表达的蛋白质,为线粒体蛋白质和磷脂提供膜支架。真核生物的PHB复合物包含两个高度同源的PHB亚基,即PHB1和PHB2,它们参与各种细胞过程,包括通过调节线粒体动力学和完整性来进行代谢控制。然而,它们在分子水平上的作用机制,尤其是PHB1的作用机制,仍然知之甚少。为了深入了解PHB1的作用机制,我们利用家蚕幼虫建立了全长重组蛋白的过表达系统,并在体外对其生物物理性质进行了表征。使用重组PHB1蛋白脂质体重构为模拟MIM的磷脂,我们发现PHB1通过其羧基末端的卷曲螺旋区域形成寡聚体。在PHB1卷曲螺旋中引入脯氨酸替代会破坏其有序的寡聚状态,其稳定性破坏与线粒体形态缺陷相关。负染电子显微镜显示,通过卷曲螺旋的同型PHB1-PHB1相互作用也诱导脂质体束缚并重塑脂质膜结构。我们阐明了PHB1促进由视神经萎缩1(OPA1)介导的膜融合,OPA1是MIM融合的关键调节因子。此外,PHB1的存在降低了脂质和OPA1对完成融合过程的依赖性。我们的体外研究为线粒体支架如何在调节线粒体动力学中发挥关键作用提供了结构上的见解。调节PHB1的结构和/或功能可能不仅为线粒体功能障碍,也为其他细胞相关疾病提供新的治疗潜力。
