Kyung S. Lee, Ph.D.
Dr. Kyung Lee carries out pioneering research aimed at understanding the structure and function of centrosomal self-assemblies and their associated regulatory complexes in human cells. He combines cell biology, structural biology, and cryo-EM to investigate how pericentriolar proteins organize themselves and serve as a platform to physicochemically regulate centriole duplication in a three-dimensional space. A failure in this process can result in abnormal centrosome numbers, improper spindle formation, and chromosome missegregation that leads to genomic instability culminating in genetic disorders such as cancer, microcephaly, ciliopathy, and dwarfism.
Dr. Lee has also been investigating the function of mammalian polo-like kinase 1 (Plk1) and has been developing small molecule inhibitors that have potential as anti-cancer therapeutics. Through collaborations with Dr. Ken Jacobson at the National Institute of Diabetes and Digestive and Kidney Diseases, as well as multiple teams at the National Center for Advancing Translational Sciences, Dr. Lee has been steering a drug discovery program to develop inhibitors that target the noncatalytic polo-box domain (PBD) of Plk1, a unique protein-protein interaction module critical for substrate recognition. PBD inhibitors could present a new avenue for overcoming the hurdles currently facing anti-Plk1 therapy and may offer improved therapeutic potential.
1) centrosome organization and function, 2) mitotic regulation, 3) protein kinases and cell cycle control, 4) anti-cancer therapy
Life is established through varying degrees of hierarchical self-organization, from individual molecules and complexes to higher-order macromolecular assemblies. Understanding how cells orchestrate these diverse structural entities to induce a specific biological function is a key step to understanding the mystery of life. We have established an interdisciplinary research program aimed at addressing two fundamental questions:
- How are higher-order macromolecular assemblies generated?
- How are they further organized into a macroscale subcellular architecture to lay the foundations for inducing discrete intracellular processes?
The centrosome, which plays a central role as the main microtubule-organizing center for animal cell division, appears to be a particularly attractive model system for studying the formation of higher-order architectures thanks to the presence of multiple scaffold proteins that are concentrically arranged around a centriole in a highly ordered manner. For the past few years, we have been investigating the structure and function of several pericentriolar scaffolds, such as Cep192, Cep152, and Cep63, along with its effector, Polo-like kinase 4 (Plk4), a key regulator for centriole duplication. Our multifaceted approach has brought together wide-ranging fields, including cell biology (e.g., super-resolution microscopy, atomic force microscopy), biophysical chemistry (e.g., analytical ultracentrifugation, circular dichroism, SEC-MALS), structural biology (e.g., X-ray crystallography, NMR spectroscopy, SAXS), electron microscopy (e.g., thin-section TEM, cryo-EM), and nanomaterials science (e.g., nanopillar technology).
Our experience has been enriched by working effectively with supramolecular architectures generated through intricately regulated physicochemical processes. Our long-term goal is to understand the organization and function of the centrosome as a holistic functional entity. This research may offer a new paradigm for investigating the ways in which macroscale supramolecular assemblies are architected to achieve a new level of functional proficiencies, and it may provide a potential roadmap for studying other biological processes orchestrated by higher-order subcellular structures.
Selected Key Publications
Phase separation of Polo-like kinase 4 by autoactivation and clustering drives centriole biogenesis.Nat Commun. 4959, 2019. [ Journal Article ]
- Nat Comm . 10(1): 1151, 2019. [ Journal Article ]
- Nat. Struct. Mol. Biol. 21(8): 696-703, 2014. [ Journal Article ]
- Nat Chem Biol. 7(9): 595-601, 2011. [ Journal Article ]
Structural and functional analyses of minimal phosphopeptides targeting the polo-box domain of polo-like kinase 1.Nat. Struct. Mol. Biol. 18(4): 516, 2009. [ Journal Article ]
Dr. Kyung Lee received his Ph.D. in 1994 from the Department of Biochemistry at Johns Hopkins University in Baltimore. He then worked with Dr. Raymond Erikson at Harvard University as a postdoctoral fellow studying protein kinase and cancer. In 1998, he joined NIH as a tenure-track investigator in the Laboratory of Metabolism at NCI. In 2005, Dr. Lee became a senior investigator and head of the Chemistry Section, Laboratory of Metabolism.
Dr. Lee is the recipient of an NCI Intramural Research Award, a Society for Biomedical Research CKD Award, an NCI CCR Synergy Award, and several Federal Technology Transfer Awards for his inventions and patents related to Plk1. He serves as an academic editor for PLoS ONE and an editorial board member for The Journal of Biological Chemistry.
|Jong II Ahn Ph.D.||Postdoctoral Fellow (Visiting)|
|Celeste Alverez B.S.||Predoctoral Fellow (Graduate Student)|
|Yaozong Chen Ph.D.||Postdoctoral Fellow (Visiting)|
|Seong-Jin Choe Ph.D.||Postdoctoral Fellow (Visiting)|
|Jung-Eun Park, Ph.D.||Staff Scientist|
|Zhuang Wei Ph.D.||Postdoctoral Fellow (Visiting)|
|Liang Zhang Ph.D.||Postdoctoral Fellow (Visiting)|