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Principal Investigator

Fei Sun, Ph.D

Professor
Webpage: Dr. Fei Sun

Personal profile
Professor of Structural Biology Institute of Biophysics, CAS
National Laboratory of Biomacromolecules, IBP
Core Facility for Protein Research, CAS
National Science Fund for Distinguished Young Scholars
Young Scholar of Chang Jiang Scholars Program


 
 
Education/Training
    • 2001  Nanjing University, China, B.Sc. in Biophysics
    • 2006  Tsinghua University, China, Ph.D. in Biophysics
    • 2006 -           Principal Investigator, Institute of Biophysics, Chinese Academy of Sciences; Chief scientist and director, Center for Biological Imaging, Core Facilities for Protein Sciences, Chinese Academy of Sciences, Beijing, China.
    • 2018.01 -      Young Scholar of Chang Jiang Scholars Program, University of Chinese academy of Sciences




Personal Statement
The research interests of my team (http://www.ibp.cas.cn/feilab) are mainly related with the structures and functions of biological macromolecules including membrane proteins and supra macromolecular assemblies. The aim of our group is to utilize and develop advanced biological imaging approaches, especially cryo-electron microscopy, to study the architecture of the biological system, in vitro and in vivo, from nano-scale to meso-scale. Currently we are focusing on molecular mechanism of bio-membrane dynamics, structure and function of supra macromolecular assembly and bio-imaging methodology development. In recent years, together with my colleagues and collaborators, I have got great achievements in both scientific researches and methodology developments. I authored 143 peer-review papers with 90 in my supervision.
Besides, I am also leading another team to manage a biological imaging center (Centre for Biological Imaging, CBI, see http://www.ibp.cas.cn/cbi), which provides biologists in the nation with our state-of-art imaging services from structure biology, cell biology to architecture biology. The overall goal of our center is to combine different imaging tools (majorly electron microscopy and fluorescence microscopy) to achieve 3D imaging of biological system from nao-scale to meso-scale in nanometer resolution. Besides facility operation and services offer, we are also performing various technology developments to expand the efficiency, capacity and resolution of our facility. Based on our technology support, our users got great scientific achievements including cryoEM structure of 30-nm chromatin fiber and near-atomic structure of spinach photosystem II-LHCII supercomplex.
In addition, in 2019, I became an adjunct professor in BioLand Laboratory of Guangzhou and began to lead another team to focus on scientific instrument development, especially for the application of biological electron microscopy. We have successfully developed two kinds of electron microscopes, including field emission scanning electron microscope for biological volume microcopy and high throughput field emission scanning transmission electron microscope for pathological sections imaging. These instrumentation work will be commercialized later.
In the future, I will continue technology developments by focusing on high resolution cryo-electron tomography and realize the possibility of resolving high resolution structure of macromolecular assemblies in their intact states. Based on the latest technologies, I will continue to investigate important supra macromolecular assemblies in the cell.
 
 
 
 
 
Positions and Honors
Positions and Employment
  • Jul. 2006 – present  Professor, Principal Investigator Laboratory of Biological Electron Microscopy and Structural Biology (Fei Sun’s lab), Institute of Biophysics, Chinese Academy of Sciences
  • Jul. 2006 – present Director and Chief Scientist Center for Biological Imaging, Core Facilities for Protein Sciences, Institute of Biophysics, Chinese Academy of Sciences
  • Sep. 2015 – present Professor School of Life Science, University of Chinese Academy of Sciences
  • Jun. 2019 – present Adjunct Professor
  • BioLand Laboratory, Guangzhou, Guangdong Province, China
 
Other Experience and Professional Memberships
  • 2021 – present Editor, Bulletin of Botany
  • 2021 – present Associate Editor, Progress of Biophysics and Biochemistry
  • 2018 – present Co-editor, CryoEM Section of IUCrJ
  • 2014 – present Associate Editor, Biophysics Reports
  • 2018 – present Executive member of the council of the Biophysical Society of China (BSC)
  • 2018 – present Vice president of Chinese CryoEM sub-society of BSC
  • 2018 – present Executive member of the council of Chinese Electron Microscopy Society
  • 2018 – present Vice president of Beijing Electron Microscopy Society
  • 2012 – present Council member of Chinese Crystallographic Society

Honors
  • China National Funds for Distinguished Young Scientists, 2020 
  • National Middle-&-Youth Talent of Science and Technology Innovation, 2019 
  • Youth professor, Chang Jiang Scholars Program of China, 2018 
  • Outstanding contribution of Chinese cryo-electron microscopy society, 2017 
  • National Youth Top-notch Talent, 2012 
  • Beishi Zhang Prize for Young Scientist in Biophysics, 2009
  • Top 100, Excellent Ph.D thesis of China, 2008




Contributions to Science
1. Cellular internal membrane system (mitochondrion, ER, Golgi complex, endosome) play the very important role in cellular physiological process, e.g. cargo traffic, energy transformation and signal transduction. The dynamics of these membrane, fusion/fission, remodeling and biogenesis, are highly relevant to regulation of cellular physiological process. We studied how protein factors (SNX1, MiD51, OPA1, ACAP1, Ups1/Mdm35, Coatomer and PI4KIIa) interact with membrane and how they regulate the dynamics of membrane.
  1. Zhang Y.#, Pang X.#, Li J., Xu J., Hsu V.W.*, and Sun F.* (2021). Structural insights into membrane remodeling by SNX1. Proc Natl Acad Sci U S A 118(10):e2022614118. doi: 10.1073/pnas.2022614118.
  2. Lu J., Chan C., Yu L., Fan J.*, Sun F.* and Zhai Y.* (2020) Molecular mechanism of mitochondrial phosphatidate transfer by Ups1. Communications Biology. doi: 10.1038/s42003-020-01121-x (in press)
  3. Zhang D., Zhang Y., Ma J., Zhu C., Niu T., Chen W., Pang X., Zhai Y., and Sun F.* (2020) Cryo-EM structures of S-OPA1 reveal its interactions with membrane and changes upon nucleotide binding. eLife 9: e50294. doi: 10.7554/eLife.50294
  4. Ma J., Zhai Y., Chen M., Zhang K., Chen Q., Pang X.*, and Sun F.* (2019), New interfaces on MiD51 for Drp1 recruitment and regulation. PLoS One 14, e0211459.
  5. Chan C. Pang X., Zhang Y., Niu T., Yang S., Zhao D., Li J., Lu L., Hsu, V.W., Zhou J.*, Sun F.* and Fan J.* (2019), ACAP1 assembles into an unusual protein lattice for membrane deformation through multiple stages. PLOS Computational Biology,15 (7): e1007081. doi: 10.1371/journal.pcbi.1007081.
  6. Wang S., Zhai Y., Pang X., Niu T., Ding Y.H., Dong, M.Q., Hsu W.V. Sun Z.* and Sun F.* (2016), Structural characterization of coatomer in its cytosolic state. Protein Cell 7(8): 586-600.
  7. Pang, X., Fan, J., Zhang, Y., Zhang, K., Gao, B., Ma, J., Li, J., Deng, Y., Zhou, Q., Egelman, E.H., Hsu, V.W.* and Sun, F.* (2014), A PH Domain in ACAP1 Possesses Key Features of the BAR Domain in Promoting Membrane Curvature. Developmental Cell, 31(1): 3-4.
  8. Zhou, Q., Li, J., Yu, H., Zhai, Y., Gao Z., Liu, Y., Pang, X., Zhang, L., Schulten K., Sun, F.* and Chen, C.* (2014), Molecular insights into the membrane-associated phosphatidylinositol 4-kinase IIα. Nature Communications, 5:3552. doi:10.1038/ncomms4552.

2. Most supra macromolecular complexes have large molecular weight, comprises multi-subunits and are highly structural dynamic, which have become a huge barrier to cope with to study their structures and functions. In recent years, with the advantages of direct electron detectors and sophisticated image processing algorithm, cryo-electron microscopy (cryo-EM) has gone into its evolution phase and become the most important and unique approach to study the 3D structures of supra macromolecular complex. We utilized our expertise in high-resolution electron cryo-microscopy to study structures of various supra macromolecular complexes, especially membrane complexes, respiratory complex, light harvesting complex and calcium channel.

  1. Du J.#, Wang D.#, Fan H.#, Xu C#, Tai L#, Lin S#, Han S., Tan Q., Wang X., Xu T., Zhang H., Chu X., Yi C., Liu P., Wang X., Zhou Y., Pin J.P., Rondard P., Liu H., Liu J*, Sun F.*, Wu B.* and Zhang Q.* (2021) Structures of human mGlu2 and mGlu7 homo-and heterodimers. Nature 594(7864): 589-93.
  2. Zhu G.#, Zeng H.#, Zhang S.#, Juli J., Tai L., Zhang D., Pang X., Zhang Y., Lam S.M., Zhu Y.,*, Peng G.*, Michel H.* and Sun F.* (2021) The unusual homodimer of a heme-copper terminal oxidase allows itself to utilize two electron donors. Angew Chem Int Ed Engl. doi: 10.1002/anie.202016785. [Epub ahead of print]
  3. Shi Y.#, Xin Y.#, Wang C.#, Blankenship R.E., Sun F.* and Xu XL.* (2020) Cryo-EM structure of the airoxidized and dithionite-reduced photosynthetic alternative complex III from Roseiflexus castenholzii. Science Advances, 6 (31): eaba2739. doi: 10.1126/sciadv.aba2739.
  4. Qiao A., Han S., Li X., Li Z., Zhao P., Dai A., Chang R., Tai L., Tan Q., Chu X., Ma L., Thorsen T.S., ReedtzRunge S., Yang D., Wang M., Sexton P.M., Wootten D., Sun F.*, Zhao Q.*, and Wu B.* (2020) Structural basis of Gs and Gi recognition by the human glucagon receptor. Science, 367: 1346-1352. doi: 10.1126/science.aaz5346.
  5. Zhu G., Zeng H., Zhang S., Juli J., Pang X., Hoffmann J., Zhang Y., Morgner N., Zhu Y.*, Peng G.*, Michel H.* and Sun F.* (2020) A 3.3 A-resolution structure of hyperthermophilic respiratory complex III reveals the mechanism of its thermal stability. Angew Chem Int Ed Engl. 59 (1): 343-351. doi: 10.1002/anie.201911554.
  6. Ren Z., Zhang Y., Zhang Y., He Y., Du P., Wang Z., Sun F.* and Ren H.* (2019) Cryo-EM structure of actin filaments from Zea mays pollen. Plant Cell. pii: tpc.00973.2018. doi: 10.1105/tpc.18.00973.
  7. Gong H., LI L., Xu A., Tang Y., Ji W., Gao R., Wang S., Yu L., Tian C., Li J., Yen H.Y., Lam S.M., Shui G., Yang X., Sun Y., Li X., Jia M., Yang C., Jiang B., Lou Z., Robinson C., Wong L.L., Guddat L.W., Sun F.*, Wang Q.* and Rao Z.* (2018), A electron transfer path connects subunits of a mycobacterial respiratory supercomplex. Science 362 (6418), eaat8923.
  8. Xin Y., Shi Y., Niu T., Wang Q., Niu W., Huang X., Ding W., Yang L., Blankenship R. E., Xu X.* and Sun F.* (2018) Cryo-EM structure of the RC-LH core complex from an early branching photosynthetic prokaryote. Nature communications, 9: 1568.
  9. Wei R., Wang X., Zhang Y., Mukherjee S., Zhang L., Chen Q., Huang X., Jing S., Liu C., Li S., Wang G., Xu Y., Zhu S., Williams A., Sun F.* and Yin C.C.* (2016), Structural insights into Ca2+ -activated long-range allosteric channel gating of RyR1. Cell Research 26: 977-994 (Cover story).

3. In the past ten years, cryoEM has been developed very fast not only on the hardware but also on the image processing software as well as sample preparation methods. According to different sample characteristics, cryoEM contains three different technologies, which are single particle analysis, electron tomography and electron crystallography. Cryo-electron tomography (cryo-ET) will be the next phase of technology to study macromolecular structures in situ. To achieve high resolution cryo-ET, lots of technology developments from sample preparation, imaging technology to image processing are demanded. We developed D-cryoFIB and VHUT-cryoFIB techniques to enable preparation of cryo-lamella of both cellular and tissue sample. We developed a novel cryo-correlative fluorescence and electron microscopy system called HOPE to enable cryoET of target region. We developed a software package AuTom (including many new algorithms, MarkerAuto, FIRT and ICON) to enable high throughput processing of cryo-ET dataset with high resolution and quality.

  1. Fan H.#, Wang B., Zhang Y., Zhu Y., Bong B., Xu H., Zhai Y., Qiao M.* and Sun F.* (2021) A cryo-electron microscopy support film formed by 2D crystals of hydrophobin HFBI. Nature Communications 12(1): 7257.
  2. Zhang J.#, Zhang D.#, Sun L.#, Ji G., Huang X., Niu T., Xu J., Ma C., Zhu Y., Gao N., Xu W. and Sun F.* (2021) VHUT-cryo-FIB, a method to fabricate frozen hydrated lamellae from tissue specimens for in situ cryo-electron tomography. Journal of Structural Biology 213(3): 107763.
  3. Huang X.#, Zhang L.#, Wen Z., Chen H., Li S., Ji G., Yin C.C. and Sun F.* (2020) Amorphous nickel titanium alloy film: a new choice for cryo electron microscopy sample preparation. Progress in Biophysics and Molecular Biology. doi: 10.1016/j.pbiomolbio.2020.07.009 [Epub ahead of print]
  4. Li S., Ji G.*, Shi Y., Klausen L.H., Niu T., Wang S., Huang X., Ding W., Zhang X., Dong M., Xu W., and Sun F.* (2018), High-vacuum optical platform for cryo-CLEM(HOPE): a new solution for non-integrated multiscale correlative light and electron microscopy. Journal of Structural Biology 201(1): 63-75.
  5. Han R., Wan X., Wang Z., Hao Y., Zhang J., Chen Y., Gao X., Liu Z., Ren F., Sun F.*, and Zhang F.* (2017), AuTom: a novel automatic platform for electron tomography reconstruction. Journal of Structural Biology 199(3): 196-208. doi: 10.1016/j.jsb.2017.07.008.
  6. Zhang J., Ji G., Huang X., Xu W.*, and Sun F.*, (2016) An improved cryo-FIB method for fabrication of frozen hydrated lamella. Journal of Structural Biology 194(2): 218-223.
  7. Deng Y., Chen Y., Zhang Y., Wang S., Zhang F.* and Sun F.* (2016), ICON: 3D reconstruction with ‘missinginformation’ restoration in biological electron tomography. Journal of Structural Biology 195(1): 100-112.
  8. Chen Y., Zhang Y., Zhang K.*, Deng Y., Zhang F.* and Sun F.* (2016), FIRT: filtered iterative reconstruction technique with information restoration. Journal of Structural Biology 195(1): 49-61.
  9. Han R., Wang L., Liu Z., Sun F.* and Zhang F.* (2015), A novel fully automatic scheme for fiducial marker-based alignment in electron tomography. Journal of Structural Biology 192: 403-17.

4. Orientating the future of biological electron microscopy, we also developed various new techniques including cryoFIB-MicroED and AutoCUTS-SEM. CryoFIB-MicroED expands the capability of MicroED and enables us to utilize MicroED to study large protein crystals. AutoCUTS-SEM is an important technique of volume electron microcopy and has wide application in developmental and neuron biology.

  1. Li X., Zhang S., Zhang J. and Sun F.* (2018), In situ protein micro-crystal fabrication by cryo-FIB for electron diffraction. Biophysics Reports 4(6): 339-347. doi: 10.1007/s41048-018-0075-x.
  2. Li X., Ji G.*, Chen X., Ding W., Sun L., Xu W., Han H., and Sun F.* (2017), Large scale three-dimensional reconstruction of an entire Caenorhabditis elegans larva using AutoCUTS-SEM. Journal of Structural Biology, 200(2): 87-96.




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