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Fei Sun, Ph.D, Prof.

Principal Investigator
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


Research Interests: Structures and functions of biological macromolecules


Email: feisun@ibp.ac.cn


Tel: 010-64888582


Address: 15 Datun Road, Chaoyang District, Beijing, 100101, China


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Biography

1997 - 2001 Nanjing University, China, B.Sc. in Biophysics

2001 - 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

Awards
Membership in Academies & Societies
Research Interests

Our research interests are mainly related with the structure and function of biological system from molecular level to cellular level. The aim of our group is to combine various structural approaches as well as developing new methodologies to determine the architecture of biological system, in vitro and in vivo, from nano-scale to meso-scale, from static to dynamic. Our core task is conducting cutting-edge scientific research, and fostering high-quality talents. In the next five years, we will focus on (i) in situ structural biology, (ii) time resolution structural dynamics of macromolecules, (iii) 3D architectural biology.

1. In situ structural biology

After rapid development and especially the recent technological breakthroughs, cryo-electron microscopy technology (cryo-EM), such as single particle analysis, has become one of the major tools to study structures of macromolecular complexes, opening a new era of structural biology. In the future the structural study of macromolecular complexes in their intact cellular environment will become the next breakthrough of structural biology, which will be achieved with the further development of cryo-EM technology. However, due to the difficulty of sample preparation, low data integrity and low signal-to-noise ratio, most in situ structures of protein complex only have resolutions worse than 20 angstroms. Our research interest is focused on the development of the complete technique workflow, and improving and optimizing the current techniques, which include cryo-focused ion beam technique, new data collection method and strategy, and new algorithm in image processing and data mining. With these technology advances, we will study the in situ structures and functions of important macromolecular complexes in high resolution.

2. Time resolution structural dynamics of macromolecules

The electron irradiation damage is a major factor to limit the resolution of biological samples in cryo-EM technology. The emerging ultrafast electron microscopy (UEM) provides a new opportunity to solve this problem. The successful combination of UEM and cryo-EM will enable us to yield a new technique cryo-UEM and achieve high resolution imaging without radiation damage. In addition, the pump-probe mode of UEM provides us a unique tool to study the time resolved structural dynamics of macromolecular complexes from pico-second to nano-second. One way of this technique is to perform cryo-UEM in diffraction mode, which is called cryo-UED. Our research interests are focused on developing cryo-UEM and cryo-UED techniques, then exploring the physical mechanism of electron irradiation damage, and studying several important protein complexes to analyze their time-resolved dynamic process.

3. 3D architectural biology

The three-dimensional ultrastructures of biological tissues and organs are related to their functions and their changes reflect different physiological states or potential diseases. Recent technology advances of volume electron microscopy (VEM) along with serial sectioning techniques as well as the fast development of big data technology have allowed us to study the architectures of tissues and organs in 3D space and nano-meter resolution, which is called 3D architectural biology. With our recent developed VEM technique (AutoCUTS-SEM) and more in next step in collaborating with Center for Biological Imaging, Institute of Biophysics, we will focus on image processing algorithm developments including registration, segmentation, annotation and quantification, then studying three dimensional ultrastructures of important tissue model systems and investigating quantitative relations between 3D architectures and diseases.

Grants
Selected Publications

1. Huang X.#, Zhang L.#, Wen Z., Chen H., Li S., Ji G., Yin C.C. andSun 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]

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, 3: 468. doi: 10.1038/s42003-020-01121-x

3. Shi Y.#, Xin Y.#, Wang C.#, Blankenship R.E.,Sun F.*and Xu XL.* (2020) Cryo-EM structure of the air-oxidized and dithionite-reduced photosynthetic alternative complex III from Roseiflexus castenholzii.Science Advances, 6 (31): eaba2739. doi: 10.1126/sciadv.aba2739

4. Xia S., Liu M., Wang C., Xu W., Lan Q., Feng S., Qi F., Bao L., Du L., Liu S., Qin C.,Sun F.&, Shi Z.&, Zhu Y.*&, Jiang S.*&, and Lu L.*& (2020) Inhibition of SARS-CoV-2 (previously 2019-nCoV) infection by a highly potent pan-coronavirus fusion inhibitor targeting its spike protein that harbors a high capacity to mediate membrane fusion.Cell Research, 30 (4): 343-355. doi: 10.1038/s41422-020-0305-x. (&: co-senior authors)

5. Zhang D., Zhang Y., Ma J., Zhu C., Niu T., Chen W., Pang X., Zhai Y., andSun F.*(2020) Cryo-EM structures of S-OPA1 reveal its interactions with membrane and changes upon nucleotide binding.eLife9: e50294. doi: 10.7554/eLife.50294

6. 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., Reedtz-Runge 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.

7. Zhu G., Zeng H., Zhang S., Juli J., Pang X., Hoffmann J., Zhang Y., Morgner N., Zhu Y.*, Peng G.*, Michel H.* andSun 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

8. 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.

9. Li X., Zhang S., Zhang J. andSun 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.

10. 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.Science362(6418), pii: eaat8923. doi: 10.1126/science.aat8923.

11. Xin Y., Shi Y., Niu T., Wang Q., Niu W., Huang X., Ding W., Yang L., Blankenship R. E., Xu X.* andSun F.*(2018) Cryo-EM structure of the RC-LH core complex from an early branching photosynthetic prokaryote.Nature communications, 9:1568. doi: 10.1038/s41467-018-03881-x.

12. Li S., Ji G.*, Shi Y., Klausen L.H., Niu T., Wang S., Huang X., Ding W., Zhang X., Dong M., Xu W., andSun 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.

13. Lu G., Xu Y., Zhang K., Xiong Y., Li H., Cui L., Wang X., Lou J., Zhai Y.*,Sun F.*and Zhang X.C.* (2017), Crystal structure of E. coli apolipoprotein N-acyltransferase.Nature Communications, 8:15948.

14. Chen R., Gao B., Liu, X., Ruan F., Zhang Y., Lou J., Feng K., Wunsch C., Li S.M., Dai J.* andSun F.*(2016), Molecular insights into the enzyme promiscuity of an aromatic prenyltransferase.Nature Chemical Biology(Advanced online at Dec. 19, 2016)

15. 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 Research26: 977-994 (Cover story).

Selected Patents

1. Zhang Jianguo; Ji Gang; Xu Wei;Sun Fei. Sample clamping tool and transfer box for frozen water-containing slices prepared by focused ion beam method. ZL201510010319.7.

2. Huang Xiaojun; Ji Gang;Sun Fei. Preparation method of grid of transmission electron microscope. ZL201510355339.8.

3.Sun Fei; Pang Xiaoyun; Zhai Yujia; Wang Ganggang; Xie Tian. DNA molecule for presenting target protein on bacteria surface and application of DNA molecule. ZL201310750736.6.

4. Ji Gang; Li Xixia; Xu Wei;Sun Fei. Ultrasonic vibration ultrathin section blade holder. ZL201721306345.5.

5. Ji Gang; Huang Xiaojun; Xu Wei;Sun Fei. A phase plate device for TEM formation of image. ZL201721224014.7

6. Ji Gang; Li Xixia;Sun Fei; Xu Wei. A automatic collection device for continuous ultrathin section. ZL201720895284.4.

(From Fei Sun, November 8, 2020)

Contact Us

Tel: 010-64889872

E-Mail: webadmin@ibp.ac.cn

Address: No 15 Datun Road, Chaoyang District, Beijing

Postcode: 100101

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