Gold, A.L., Hurlock, M.E., Guevara, A.M., Isenberg, L.Y.Z., and Kim, Y. (2024) Identification of the Polo-like kinase substrate required for homologous synapsis in C. elegans. bioRxiv doi: https://doi.org/10.1101/2024.08.13.607834, accepted at J Cell Biol.
Blundon, J.M.*, Cesar, B.I.*, Bae, J.W., Čavka I., Haversat, J., Ries, J., Köhler, S., and Kim, Y. (2024) Skp1 proteins are structural components of the synaptonemal complex in C. elegans. Science Advances DOI: 10.1126/sciadv.adl4876, *Contributed equally.
Haversat J., Woglar, A., Klatt, K., Akerib, C.C., Roberts, V., Chen, S-Y., Arur, S., Villeneuve, A.M., and Kim, Y. (2022) Robust designation of meiotic crossover sites by CDK-2 through phosphorylation of the MutSg complex. PNAS 119 (21) e2117865119
Baudrimont, A., Paouneskou, D., Mohammad, A., Lichtenberger, R., Blundon, J., Kim, Y., Hartl, M., Falk, S., Schedl, T., and Jantsch, V. (2022) Release of CHK-2 from PPM-1.D anchorage schedules meiotic entry. Science Advances DOI: 10.1126/sciadv.abl8861
Brandt, J.N. and Kim, Y. (2021) Targeting Polo-like kinase in space and time during C. elegans meiosis. Cell Cycle DOI: 10.1080/15384101.2021.1953232
Brandt, J.N., Hussey, K.A., and Kim, Y. (2020) Spatial and temporal control for targeting Polo-like kinase during meiotic prophase. J Cell Biol (Cover) 219 (11): e202006094
Hurlock, M.E., Čavka, I., Kursel, L.E., Haversat, J., Wooten, M., Nizami, Z., Turniansky, R., Hoess, P., Ries, J., Gall, J.G., Rog, O., Köhler, S., and Kim, Y. (2020) Identification of novel synaptonemal complex components in C. elegans. J Cell Biol 219 (5): e201910043
Before Johns Hopkins
Yu, Z.*, Kim, Y.*, and Dernburg, A.F. (2016) Meiotic recombination and the crossover assurance checkpoint in C. elegans. Semin Cell Dev Biol 54, 106-116. *Contributed equally
Kim, Y., Kostow, N., and Dernburg, A.F. (2015) The chromosome axis mediates feedback control of CHK-2 to ensure crossover formation in C. elegans. Dev Cell 35, 247-261
Kim, Y.*, Rosenberg, S.C.*, Kugel, C.L., Kostow, N., Rog, O., Davydov, V., Su, T.Y., Dernburg, A.F.†, and Corbett, K.D.† (2014) The chromosome axis controls meiotic events through a hierarchical assembly of HORMA domain proteins. Dev Cell 31, 487-502. *Contributed equally, †Co-corresponding authors
Vitre, B.*, Gudimchuk, N.*, Borda, R., Kim, Y., Heuser, J.E., Cleveland, D.W., and Grishchuk, E.L. (2014) Kinetochore-microtubule attachment throughout mitosis potentiated by the elongated stalk of the kinetochore kinesin CENP-E. Mol Biol Cell 25, 2272-81. *Contributed equally
Gudimchuk, N.*, Vitre, B.*, Kim, Y., Kiyatkin, A., Cleveland, D.W., Ataullakhanov, F.I., and Grishchuk, E.L. (2013) Kinetochore kinesin CENP-E is a processive bi-directional tracker of dynamic microtubule tips. Nat Cell Biol 15, 1079-1088. *Contributed equally.
Kim, Y.*, Holland, A.J.*, Lan, W., and Cleveland, D.W. (2010) Aurora kinases and protein phosphatase 1 mediate chromosome congression through regulation of CENP-E. Cell 142, 444-455 *Contributed equally.
Shin, W.D., Fischer, R., Kanchanawong, P., Kim, Y., Lim, J., Myers, K., Nishimura, Y., Plotnikov, S., Thievessen, I., Yarar, D., Sabass, B., and Waterman, C.M. (2010) A versatile, multi-color total internal reflection fluorescence and spinning disk confocal microscope system for high-resolution live cell imaging. Live Cell Imaging: A laboratory manual, 2nd edition Chapter 7, 119-138. Cold Spring Harbor Laboratory Press, Cold Spring Harbor, New York
Kim, Y., Heuser, J.E., Waterman, C.M., and Cleveland, D.W. (2008) CENP-E combines a slow, processive motor with a flexible coiled-coil to produce an essential, motile kinetochore tether. J Cell Biol (Cover) 181, 411-419.
Kops, G.J.P.L., Kim, Y., Weaver, B.A.A., Mao, Y., McLeod, I., Yates III., J.R., Tagaya, M., and Cleveland, D.W. (2005) Zw10 links mitotic checkpoint signaling to the structural kinetochore. J Cell Biol 169, 49-60.