We previously documented that individual microtubules in the axons of cultured juvenile rodent neurons consist of a labile domain and a stable domain and that experimental depletion of tau results in selective shortening and partial stabilization of the labile domain. After first confirming these findings in adult axons, we sought to understand the mechanism that accounts for the formation and maintenance of these microtubule domains. We found that fluorescent tau and MAP6 ectopically expressed in RFL-6 fibroblasts predominantly segregate on different microtubules or different domains on the same microtubule, with the tau-rich ones becoming more labile than in control cells and the MAP6-rich ones being more stable than in control cells. These and other experimental findings, which we studied further using computational modeling with tunable parameters, indicate that these two MAPs do not merely bind to pre-existing stable and labile domains but actually create stable and labile domains on microtubules.
Journal article
Tau and MAP6 establish labile and stable domains on microtubules
iScience, v 28(3), 111785
Jan 2025
Featured in Collection : UN Sustainable Development Goals @ Drexel
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- Title
- Tau and MAP6 establish labile and stable domains on microtubules
- Creators
- Koray KirimtayWenqiang HuangXiaohuan SunLiang QiangDong V. WangCalvin T. SprouseErin M. CraigPeter W. Baas
- Publication Details
- iScience, v 28(3), 111785
- Publisher
- CELL PRESS
- Number of pages
- 24
- Grant note
- USA National Institutes of Health: R01NS115977 USA Department of Defense: W81XWH2110189 NSF Research at Undergraduate Institutes Award: 1915477 Alzheimer's Association: 24AARG-D-1191264 Christopher and Dana Reeve Postdoctoral Fellowship
We thank the members of the laboratories of Peter Baas, Liang Qiang, Dong Wang, and Erin Craig for their technical support and valuable insight on this project, as well as several colleagues from around the world who shared their DNA plasmids with us. We thank Ionis Pharmaceuticals for providing the tau and control antisense oligonucleotides for these studies. This work was sup-ported by grants from the USA National Institutes of Health (R21AG068597 and R01NS28785) and the USA Department of Defense (W81XWH2110189) to P.W.B., the NSF Research at Undergraduate Institutes Award 1915477 to E.M.C., and grants from the USA National Institutes of Health (R01NS115977) and the Alzheimer's Association (24AARG-D-1191264) to L.Q.. K.K. is the recipient of a Christopher and Dana Reeve Postdoctoral Fellowship, administered through the Department of Neurobiology and Anat-omy at Drexel University.
- Resource Type
- Journal article
- Language
- English
- Academic Unit
- Neurobiology and Anatomy; Pharmacology and Physiology
- Web of Science ID
- WOS:001429254200001
- Scopus ID
- 2-s2.0-85217968840
- Other Identifier
- 991022024204004721
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- Collaboration types
- Domestic collaboration
- Web of Science research areas
- Cell Biology