{"id":11,"date":"2021-04-27T20:39:38","date_gmt":"2021-04-27T20:39:38","guid":{"rendered":"https:\/\/blogs.oregonstate.edu\/qiulab\/?page_id=11"},"modified":"2025-04-03T19:41:43","modified_gmt":"2025-04-03T19:41:43","slug":"publications","status":"publish","type":"page","link":"https:\/\/blogs.oregonstate.edu\/qiulab\/publications\/","title":{"rendered":"Publications"},"content":{"rendered":"\n
Publications at Oregon State University<\/strong>\n\u2756Gao, Y.*, Visootsat, A.*, Williamson, O., Perrino, D. and Qiu, W.H.#<\/sup> (2025) Engineer C-terminal Kinesin Motors with Plus-End-Directed Processivity. Under Review.<\/strong><\/em> \n\n\u2756Visootsat, A.*, Popchock, A.*, Gao, Y., and Qiu, W.H.#<\/sup> (2025) TinA enables kinesin-14\/KlpA to switch directionality and exhibit processive minus-end-directed motility.<\/strong> In Revision.<\/strong><\/em> \n\n\u2756Guo, W.H.*, Gao, Y. *, Du, D., Sanchez, J., Li, Y.P., Qiu, W.H.#<\/sup>, and Li, L#<\/sup> (2025) Elucidating the Interactions between Kinesin-5\/BimC and the Microtubule: Insights from TIRF Microscopy and Molecular Dynamics Simulations. Brief. Bioinform.<\/strong><\/em> In Press<\/em><\/strong>.\n\n\u2756Liu X.L.*, Rao, L. *, Qiu W.H., Berger, F.#<\/sup>, and Gennerich, A.#<\/sup> (2024) Kinesin-14 HSET and KlpA are non-processive microtubule motors with load-dependent power strokes. Nat. Commun.<\/em><\/strong> 15(1), https:\/\/doi.org\/10.1038\/s41467-024-50990-x\n\n\u2756Li Q.*, Ferrare J.T., Silver J., Wilson J.O,, Arteaga-Castaneda L, Qiu W.H., Vershinin M, King S.J., Neuman K.C., and Xu J.#<\/sup>. (2023) Cholesterol in the cargo membrane amplifies tau inhibition of kinesin-1-based transport. Proc. Natl. Acad. Sci. USA.<\/em><\/strong> 120 (3) e2212507120 https:\/\/doi.org\/10.1073\/pnas.2212507120.\n\n\u2756Guo W.*, Sun S., Sanchez J.E, Lopez-Hernandez A.E., Ale T.A., Chen J., Afrin T., Qiu W.H., Xie Y., and Li L.#<\/sup>. (2022) Using a comprehensive approach to investigate the interaction between Kinesin-5\/Eg5 and the microtubule. Comput Struct Biotechnol J.<\/em><\/strong> 2022 Aug 11;20:4305-4314. doi: 10.1016\/j.csbj.2022.08.020.\n\n\u2756Xian Y.J.*, Xie Y.X, Silva S.M., Karki C.B., Qiu W.H. and Li L#<\/sup>. (2021) StructureMan: A structure manipulation tool to study large scale biomolecular interactions. Front. Mol. Biosci.<\/em><\/strong> 7:627087.\n\n\u2756Tseng K.-F.*, Mickolajczyk K.J.*, Feng G.X.*, Feng Q.Z., Kwok E.S., Howe J., Barbar E.J., Dawson S.C., Hancock W.O., and Qiu W.H.#<\/sup> (2021) The tail of kinesin-14a in Giardia is a dual regulator of motility. Cur. Biol.<\/em><\/strong> 30:3664-3671.e4.\n\n\u2756Swentowsky K.W.*, Gent J.I., Lowry E.G., Schubert V, Ran X, Tseng K.-F., Harkess AE, Qiu W.H., Dawe R.K.#<\/sup> (2020) Distinct kinesin motors drive two types of maize neocentromeres. Genes Dev.<\/strong><\/em> 34:1239-1251.\n\n\u2756Gicking A.M.*, Wang P.*, Liu C., Mickolajczyk K.J., Guo L.J., Hancock W.O., and Qiu W.H.#<\/sup> (2019) The orphan kinesin PAKRP2 achieves processive motility via a noncanonical stepping mechanism. Biophys. J.<\/em><\/strong> 116:1270-1281.\n\n\u2756Popchock A.R., Jana S., Mehl R.A.#<\/sup>, and Qiu W.H.#<\/sup> (2018) Engineering heterodimeric kinesins through genetic incorporation of noncanonical amino acids. ACS Chem. Biol.<\/em><\/strong> 13: 2229\u20132236.\n\nGicking A.M., Swentowsky K.W., Dawe R.K.#<\/sup>, and Qiu W.H.#<\/sup> (2018) Functional diversification of the kinesin-14 family in land plants. FEBS Letters<\/em><\/strong> 592: 1918-1928. \n\nWang P.*, Tseng K.-F.*, Gao Y., Cianfrocco M., Guo L.J., and Qiu W.H.# (2018) The central stalk determines the motility of mitotic kinesin-14 homodimers. Cur. Biol.<\/em><\/strong> 28:2302-2308. \n\n\u2756Gicking A.M., Qiu, W.H.#<\/sup>, and Hancock W.O.#<\/sup> (2018) Mitotic kinesins in action: Diffusive searching, directional switching and ensemble coordination. Mol. Biol. Cell<\/em><\/strong>, 29: 1153-1156. \n\n\u2756Dawe R.K.#<\/sup>, Lowry E.G., Gent J.I., Stitzer M.C., Swentowski K.W., Higgins D.M., Ross-Ibarra J., Wallacem J.G., Kanizay L.B., Alabady M., Qiu W.H., Tseng K.-F., Wang N., Gao Z., Birchler J.A., Harkess A.E., Hodges A.L., and Hiatt E.N. (2018) A kinesin-14 motor activates neocentromeres to promote meiotic drive in Maize. Cell<\/strong><\/em>, 173, 839\u2013850.\n\n\u2756Tseng K.-F.*, Wang P.*, Lee Y.-R.*, Bowen J., Gicking A.M., Guo, L., Liu B.#<\/sup>, and Qiu W.H.#<\/sup>. (2018) The preprophase band-associated kinesin-14 OsKCH2 is a processive minus-end-directed microtubule motor. Nat. Commun.<\/em><\/strong>, 9:1067\nFeatured in EurekAlert!, ScienceDaily and Phys.org.\n\n\u2756 Li Q., Tseng K.-F., King S.J., Qiu W.H., and Xu J.#<\/sup> (2018) A fluid membrane enhances the velocity of cargo transport by small teams of kinesin-1. J. Chem. Phys.<\/em><\/strong> 148, 123318.\n\n\u2756Hams N. Padmanarayana, M., Qiu W.H., and Johnson C.P.#<\/sup> (2017) \u00a0Otoferlin is a multivalent calcium sensitive scaffold linking SNAREs and calcium channels. Proc. Natl. Acad. Sci. USA<\/em><\/strong>,114, 8023\u20138028\n\n\u2756Popchock A.R.*, Tseng K.-F.*, Wang P., Karplus P.A., Xiang X., and Qiu W.H.#<\/sup> (2017) The mitotic kinesin-14 KlpA contains a context-dependent directionality switch. Nat. Commun.<\/em><\/strong>, 8,\u00a013999.\n\n\u2756Lee Y.-R., Qiu W.H., and Liu B.# (2015). Kinesin Motors in Plants: From Subcellular Dynamics to Motility Regulation.\u00a0Curr. Opin. Plant Biol.<\/em><\/strong>\u00a028, 120\u2013126.\n\nSelected publications\u00a0prior to\u00a0Oregon State University<\/strong>\n\u2756 Cheng L., Desai J., Miranda C.J., Duncan J.S., Qiu W.H., Nugent A.A., Kolpak A.L., Wu C.C., Drokhlyansky E., Delisle M.M., Chan W.-M., Wei Y., Propst F., Reck-Peterson S.L., Fritzsch, B. and Engle E.C. (2014). Human CFEOM1 mutations attenuate KIF21A autoinhibition and cause oculomotor axon stalling. Neuron 82, 334-49.\n\n\u2756 Qiu W. H.*, Derr N.D.*, Goodman B. S., Villa E., Wu D., Shih W., and Reck-Peterson S.L. (2012) Dynein achieves processive motion using both stochastic and coordinated stepping. Nat. Struct. Mol. Biol. 19, 193-200.\n\nHighlighted Nature Research News & Views: Nature 482, 44-45 (2012).\n\u2756 Su X.L., Qiu W. H., Gupta M.L., Pereira-Leal J.B., Reck-Peterson S.L., and Pellman D. (2011). Mechanisms underlying the dual-mode regulation of microtubule dynamics by Kip3\/Kinesin-8. Mol. Cell 43, 751-763.\n\n\u2756 Qiu W. H.*, Li T. P.*, Zhang L. Y., Kao Y.-T., Wang L. J., and Zhong D. P. (2008). Ultrafast quenching of tryptophan fluorescence in proteins: Interresidue and intrahelical electron transfer. Chem. Phys. 350, 154-164.\n\n\u2756 Zhang L.Y., Wang L.J., Kao Y.-T., Qiu W.H., Yang Y., Okobiah O., and Zhong D.P. (2007). Mapping hydration dynamics around a protein surface. Proc. Natl. Acad. Sci. USA 104, 18461-18466.\n\n\u2756 Qiu W.H., Wang L.J., Lu W.Y., Boechler A., Sanders D.A.R., and Zhong D.P. (2007). Dissection of complex protein dynamics in human thioredoxin. Proc. Natl. Acad. Sci. USA 104, 5366-5371.\n\n\u2756 Qiu W.H., Kao Y.-T., Zhang L.Y., Yang Y., Wang L.J., Stites W.E., Zhong D.P., and Zewail A.H. (2006). Protein surface hydration mapped by site-specific mutations. Proc. Natl. Acad. Sci. USA 103, 13979-13984.\n\n\u2756 Kim J., Lu W.Y., Qiu W.H., Wang L.J., Caffrey M., and Zhong D.P. (2006). Ultrafast hydration dynamics in the lipidic cubic phase: Discrete water structures in nanochannels. J. Phys. Chem. B 110, 21994-22000.\n\n\u2756 Zhang L.Y., Kao Y.-T., Qiu W. H., Wang L.J., and Zhong D.P. (2006). Femtosecond studies of tryptophan fluorescence dynamics in proteins: Local solvation and electronic quenching. J. Phys. Chem. B 110, 18097-18103.\n\n\u2756 Qiu W.H.*, Zhang L.Y.*, Okobiah O., Yang Y., Wang L.J., Zhong D.P., and Zewail A.H. (2006). Ultrafast solvation dynamics in human serum albumin: Correlations with conformational transitions and site-selected recognition. J. Phys. Chem. B 110, 10540-10549.\n\n\u2756 Qiu W.H., Zhang L.Y., Kao Y.-T., Lu W.Y., Li T.P., Kim J., Sollenberger G.M., Wang L.J., and Zhong D.P. (2005). Ultrafast hydration dynamics in melittin folding and aggregation: Helix formation and tetramer self-assembly. J. Phys. Chem. B 109, 16901-16910.\n\n\u2756 Lu W.Y., Qiu W.H., Kim J., Okobiah O., Hu H.X., Gokel G.W., and Zhong D.P. (2004). Femtosecond studies of crown ethers: supramolecular solvation, local solvent structure and cation pi interaction. Chem. Phys. Letters 394, 415-422.\n\n\u2756 Lu W.Y., Kim J., Qiu W.H., and Zhong D.P. (2004). Femtosecond studies of tryptophan solvation: correlation function and water dynamics at lipid surfaces. Chem. Phys. Letters 388, 120 126.\n\n* denotes equal contribution\n# denotes correspondence or co-correspondence<\/code><\/pre>\n\n\n\n
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