# Luke H. Chao (He/ Him/ His) Assistant Professor Department of Molecular Biology, Massachusetts General Hospital Department of Genetics, Harvard Medical School ![Luke Chao Photo](/sites/g/files/omnuum9451/files/styles/hwp_4_5__480x600/public/biophysics/files/getattachmentthumbnail.jpg?itok=U6Us45bh) location\_on 185 Cambridge Street, Simches Research Building, CPZN 6.808 Boston, MA 02114 smartphone [(617) 724-2323]() email [luke\_chao@hms.harvard.edu](mailto:luke_chao@hms.harvard.edu) laptop\_windows [Chao Laboratory Home Page](http://www.chaolab.org) laptop\_windows [Chao Lab Publications](https://www.ncbi.nlm.nih.gov/myncbi/luke.chao.1/bibliography/public/) The Chao Lab explores structural and biophysical mechanisms underlying membrane dynamics and ultrastructure. A central goal for our team is to understand the mitochondrion’s morphology, a question filled with fascinating puzzles of how conformational change across scales generates diverse subcellular forms and functions. We integrate structural and biophysical methods to understand how macromolecular assemblies generate responsive, pleomorphic shapes. Using electron cryo tomography (cryo-ET), we visualized how mitochondrial inner-membrane ultrastructure and architecture is regulated (Fry, Navarro et al., EMBO J 2024). Applying in vitro reconstitution, we uncovered a mechanism for regulating mitochondrial inner-membrane fusion, revealing how proteolytic processing controls gating of the final pore-opening step (Ge et al., eLife 2020). In other exploration of mitochondrial morphogenesis, we revealed interactions coordinating outer/inner-mitochondrial membrane fusion, and using phylogenetic approaches, identified a conserved sequence signature for an ancient membrane-shaping protein's respiratory function (Boopathy et al., JBC 2024; Benning, Bell, Nguyen et al., BioRxiv 2024). Finally, our research team has made contributions to understanding macromolecular (ultra)structure/function in other systems. We revealed mechanisms regulating cell wall organization central for bacterial cell division (Navarro Vettiger et al., Nat. Micro. 2022), and determined a cryo-EM helical reconstruction revealing baculovirus nucleocapsid assembly (Benning et al., Nat. Comm. 2024). We have also made contributions to understanding mechanisms of curvature-induction at the plasma membrane important in the generation of extracellular vesicles (Bell et al., eLife 2024). **Current Lab Members:** 1 Graduate Student 5 Postdoctoral Fellows **Selected Publications**: Navarro PP, Vettiger A, Ananda VY, Llopis PM, Allolio C, Bernhardt TG, Chao LH. Cell wall synthesis and remodeling dynamics determine bacterial division site architecture and cell shape. \[preprint\]. 2021 October. Available from: . doi: 10.1101/2021.10.02.462887. Sloutsky R, Dziedzic N, Dunn MJ, Bates RM, Torres-Ocampo AP, Boopathy S, Page B, Weeks JG, Chao LH, Stratton MM. Heterogeneity in human hippocampal CaMKII transcripts reveals allosteric hub-dependent regulation. Sci Signal. 2020 Jul 21;13(641). doi: 10.1126/scisignal.aaz0240. PubMed PMID: 32694170; PubMed Central PMCID: PMC7654443. Ge Y, Shi X, Boopathy S, McDonald J, Smith AW, Chao LH. Two forms of Opa1 cooperate to complete fusion of the mitochondrial inner-membrane. Elife. 2020 Jan 10;9. doi: 10.7554/eLife.50973. PubMed PMID: 31922487; PubMed Central PMCID: PMC7299343. - ## Faculty Alphabetical [Faculty A-E](/people-alphabetical/e) - ## People Terms [Faculty](/people-terms/faculty) [Core/ Training Grant Faculty](/people-terms/core-faculty) [Accepting Rotation Students](/people-terms/accepting-rotation-students) [Biochemistry/ Molecular Biology/ Microbiology](/people-terms/biochemistry-molecular-biology) [Imaging](/people-terms/medical-imaging) [Structural Biology](/people-terms/structural-biology)