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Building Nuclear Pore Mimics with DNA Origami

日期: 2023-02-21

金沙威尼斯欢乐娱人城定量生物学中心

学术报告 

题    目: Building Nuclear Pore Mimics with DNA Origami

报告人: Qi Shen, Ph.D.

Associate Research Scientist in Department of Molecular Biophysics and Biochemistry & Department of Cell Biology, Yale University

时    间: 2月22日(周三)11:00-12:00

地    点: ZOOM线上报告

Meeting ID: 724 429 3098

Password: 654321

https://zoom.us/j/7244293098?pwd=UGRQT1ZTY3dkOUJQY0lXY3J4SndsUT09

主持人: 林一瀚 研究员

摘 要:

The nuclear pore complexes (NPCs) on the nuclear envelope control the bidirectional exchange of molecules between the nucleus and cytoplasm. Delivering the virus genome into the host nucleus through the NPC is pivotal in human immunodeficiency virus 1 (HIV-1) infection. However, the molecular mechanisms of viral nuclear entry remain poorly understood due to the complexity of the NPC and technical challenges in recapitulating such a complex system in vitro. Here we built a suite of NPC mimics — DNA-origami channels containing nucleoporins with programmable arrangements — to model the nuclear entry of HIV-1. The artificial NPC platform provides a transformative toolset for the investigation of functional molecular interactions that govern the physiological nucleocytoplasmic transport and the nuclear entry of retroviruses.

报告人简介:

Qi Shen obtained his PhD in physical chemistry from Peking University, focusing on structure-based design of peptide and small-molecule drugs. He did postdoc research at Yale University, where he worked on multidisciplinary projects and became well versed in DNA nanotechnology, protein engineering, biochemistry, and structural biology. Specifically, he used DNA origami technology to construct artificial nuclear pore complexes (NPCs) to study the mechanisms underlying the nuclear transport of HIV-1 virus, which has led to an innovative synthetic biology platform and the discovery of a wealth of biological insights. Dr. Shen has published 12 articles as the first/co-first author in prestigious journals, including Nat. Struct. & Mol. Biol., Nat. Chem., JACS, Angew. Chem., ACS nano, and PNAS. He is broadly interested in interdisciplinary research at the crossroads of nanotechnology, biophysics, and synthetic biology.