Yongli Zhang, PhD, MS
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About
Titles
Professor of Cell Biology
Biography
Dr. Zhang obtained a bachelor's degree in applied physics and a master's degree in theoretical physics in China before he came to the US in 1997. He began to use pipettes as a graduate student in the Department of Molecular Biophysics and Biochemistry at Yale University and barely passed his qualifying exams. Fortunately, he seemed to do research well under the supervision of Prof. Donald M. Crothers and got a Ph. D. in 2003. His thesis work is related to the sequence-dependent DNA bending and flexibility. Dr. Zhang then became a postdoctoral fellow in Prof. Carlos Bustamante's lab at UC Berkeley. Using optical tweezers, he found that representative chromatin remodeling factors contain DNA translocases and first measured their translocation speed, processivity, and stall force.
Prof. Zhang has broad interests and skills in measuring the intra- and inter-molecular forces and the forces generated by molecular machines. He tries to use these measurements to better understand the working mechanisms and biological functions of macromolecules. With his collaborators, Prof. Zhang combines high-resolution optical tweezers with single-molecule fluorescence microscopy to simultaneously manipulate and visualize single molecules in real time. As a result, dynamic structures of proteins inaccessible by other experimental methods can be obtained. Prof. Zhang's primary interests are mechanical force in biology and folding dynamics of proteins involved in fundamental biological processes and human diseases, with a focus on SNARE proteins and their regulators essential for intracellular vesicle fusion.
Appointments
Cell Biology
ProfessorPrimaryMolecular Biophysics and Biochemistry
Associate Professor TenureSecondary
Other Departments & Organizations
- Biochemistry, Quantitative Biology, Biophysics and Structural Biology (BQBS)
- Cell Biology
- Cell Biology Research
- Diabetes Research Center
- Membrane Traffic
- Molecular Biophysics and Biochemistry
- Molecular Cell Biology, Genetics and Development
- Yale Combined Program in the Biological and Biomedical Sciences (BBS)
- Yale Ventures
- Zhang Laboratory of Single-Molecule Biophysics & Biochemistry
Education & Training
- Postdoc fellow
- University of California (2006)
- PhD
- Yale School of Medicine, Department of Molecular Biophysics and Biochemistry (2003)
- MS
- Chinese Academy of Sciences, Institute of Theoretical Physics (1997)
Research
Overview
We are focused on understanding the molecular mechanisms that underlie three important biological processes:
1. Regulated SNARE folding and assembly.
The membrane fusion machinery contains SNARE proteins, Sec1/Munc18 (SM) proteins, synaptotagmin, complexin, NSF, SNAP, and Munc13. Among these proteins, SNAREs are key players. They couple their dynamical assembly and disassembly to membrane fusion in a precisely controlled manner. Specifically, SNARE assembly generates force to draw two membranes into proximity and use their folding energy to lower the energy barrier of membrane fusion. SM proteins, synaptotagmin, and complexin regulate SNARE assembly and enable membrane fusion to occur at right time and location. After membrane fusion, NSF and SNAP disassemble the fully assembled SNARE complexes in an ATP-dependent manner, recycling SNAREs for next round of fusion. We plan to understand how the above mentioned proteins work together to control exocytosis and how malfunctions of the fusion machinery cause diseases.
Sudhof, T.C., and Rothman, J.E. (2009). Membrane fusion: Grappling with SNARE and SM proteins. Science 323, 474-477.
Y. Gao, S. Zorman, G. Gundersen, Z. Q. Xi, G. Sirinakis, J. E. Rothman*, Y. L. Zhang*, Single reconstituted neuronal SNARE complexes zipper in three distinct stages. Science 337: 1340-1343 (2012).
L. Ma, A. A. Rebane, G. Yang, Z. Xi, Y. Kang, Y. Gao, Y. L. Zhang, Munc18-1-regulated stage-wise SNARE assembly underlying synaptic exocytosis. eLIFE 4, e09580 (2015).
S. Zorman, A. A. Rebane, L. Ma, G. Yang, M. A. Molski, J. Coleman, F. Pincet, J. E. Rothman*, Y. L. Zhang*, Common intermediates and kinetics, but different energetics, in the assembly of SNARE proteins. eLIFE 3, e03348 (2014).
Y. L. Zhang, Energetics, kinetics, and pathway of SNARE folding and assembly revealed by optical tweezers, Protein Sci. 26, 1252-1265 (2017).
A. A. Rebane, B. Wang, L. Ma, H. Qu, J. Coleman, S. S. Krishnakumar, J. E. Rothman*, Y. L. Zhang*, Two disease-causing SNAP-25B mutations selectively impair SNARE C-terminal assembly. J. Mol. Biol. 430, 479 (2018).
J. Jiao, M. He, S. A. Port, R. W. Baker, Y. Xu, H. Qu, Y. Xiong, Y. Wang, H. Jin, T. J. Eisemann, F. M. Hughson*, Y. L. Zhang*, Munc18-1 catalyzes neuronal SNARE assembly by templating SNARE association. Elife 7, e41771 (2018).
* Co-corresponding authors.
2. Membrane protein folding, stability, and protein-membrane interactions.
Optical tweezers have been widely applied to study folding dynamics of soluble proteins, but not membrane proteins so far. We have been developing novel approaches to measure the folding energy and kinetics of membrane proteins using high-resolution optical tweezers. We are also interested in proteins that help membrane proteins get in and out membranes.
L. Ma, Y. Cai, Y. Li, J. Jiao, Z. Wu, B. O'Shaughnessy, P. De Camilli*, E. Karatekin*, Y. L. Zhang*, Single-molecule force spectroscopy of protein-membrane interactions. Elife 6, e30493 (2017)
3. Development of new single-molecule methods.
We have been developing new instruments or upgrading our machines by combining high-resolution optical tweezers, single-molecule fluorescence detection, and microfluidics to better study single proteins or protein complexes. We have been also developing new methods or algorithms to analyze data from single molecule experiments.
G. Sirinakis, Y. X. Ren, Y. Gao, Z. Q. Xi, Y. L. Zhang, Combined and versatile high-resolution optical tweezers and single-molecule fluorescence microscopy. Rev Sci Instrum. 83: 093708-(1-9) (2012).
Y. L. Zhang, J. Jiao, A. A. Rebane, Hidden Markov modeling with detailed balance and its application to single protein folding Biophys J 111, 2110 (2016).
A. A. Rebane, L. Ma, Y. L. Zhang, Structure-based derivation of protein folding intermediates and energies from optical tweezers. Biophys J 110, 441 (2016).
4. Molecular mechanism of the mechanosensitive ion channel NOMPC.
NOMPC is involved in mechanosensation of touch and hearing in flies. Unlike many mechanosensitive ion channels that sense membrane tension or force in the membrane, NOMPC has been proposed to sense force out of the membrane through a gating spring. In collaboration with groups of Yifan Cheng and Yuh-Nung Jan in UCSF, we have been investigating whether and how force modulates the ion conductance of NOMPC, using optical tweezers and fluorescence imaging.
- P. Jin, D. Bulkley, Y. M. Guo, W. Zhang, Z. H. Guo, W. Huynh, S. P. Wu, S. Meltzer, T. Cheng, L. Y. Jan, Y. N. Jan, Y. F. Cheng, Electron cryo-microscopy structure of the mechanotransduction channel NOMPC. Nature 547, 118 (2017).
- W. Zhang, L. E. Cheng, M. Kittelmann, J. F. Li, M. Petkovic, T. Cheng, P. Jin, Z. H. Guo, M. C. Gopfert, L. Y. Jan, Y. N. Jan, Ankyrin repeats convey force to gate the NOMPC mechanotransduction channel. Cell 162, 1391 (2015).
Medical Subject Headings (MeSH)
Academic Achievements and Community Involvement
Links & Media
Media
News
- November 30, 2023
Meet Our Speakers: Shixin Liu
- April 29, 2022
Dr. Avinash Kumar's new recognition.
- March 15, 2021
Avinash Kumar Joined Our Group on March 1, 2021
- July 17, 2020
Position Openings in the Zhang lab
Get In Touch
Contacts
Cell Biology
PO Box 208002, 333 Cedar Street
New Haven, CT 06520-8002
United States
Locations
Wet Lab
Lab
Sterling Hall of Medicine, I-Wing
Academic Office
Tweezers Lab
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