Microtubule lattice spacing governs cohesive envelope formation of tau family proteins
Language English Country United States Media print-electronic
Document type Journal Article, Research Support, N.I.H., Extramural, Research Support, Non-U.S. Gov't
Grant support
MC_UP_A025_1011
Medical Research Council - United Kingdom
R35 GM124889
NIGMS NIH HHS - United States
R35 GM133688
NIGMS NIH HHS - United States
PubMed
35996000
PubMed Central
PMC9613621
DOI
10.1038/s41589-022-01096-2
PII: 10.1038/s41589-022-01096-2
Knihovny.cz E-resources
- MeSH
- Humans MeSH
- Microtubules metabolism MeSH
- Neurodegenerative Diseases * metabolism MeSH
- Microtubule-Associated Proteins metabolism MeSH
- tau Proteins * metabolism MeSH
- Proteins metabolism MeSH
- Tubulin metabolism MeSH
- Check Tag
- Humans MeSH
- Publication type
- Journal Article MeSH
- Research Support, Non-U.S. Gov't MeSH
- Research Support, N.I.H., Extramural MeSH
- Names of Substances
- Microtubule-Associated Proteins MeSH
- tau Proteins * MeSH
- Proteins MeSH
- Tubulin MeSH
Tau is an intrinsically disordered microtubule-associated protein (MAP) implicated in neurodegenerative disease. On microtubules, tau molecules segregate into two kinetically distinct phases, consisting of either independently diffusing molecules or interacting molecules that form cohesive 'envelopes' around microtubules. Envelopes differentially regulate lattice accessibility for other MAPs, but the mechanism of envelope formation remains unclear. Here we find that tau envelopes form cooperatively, locally altering the spacing of tubulin dimers within the microtubule lattice. Envelope formation compacted the underlying lattice, whereas lattice extension induced tau envelope disassembly. Investigating other members of the tau family, we find that MAP2 similarly forms envelopes governed by lattice spacing, whereas MAP4 cannot. Envelopes differentially biased motor protein movement, suggesting that tau family members could spatially divide the microtubule surface into functionally distinct regions. We conclude that the interdependent allostery between lattice spacing and cooperative envelope formation provides the molecular basis for spatial regulation of microtubule-based processes by tau and MAP2.
Department of Cell Biology Faculty of Science Charles University Prague Czech Republic
Department of Molecular and Cellular Biology University of California at Berkeley Berkeley CA USA
Department of Molecular and Cellular Biology University of California Davis Davis CA USA
Institute of Biotechnology Czech Academy of Sciences BIOCEV Prague West Czech Republic
Structural Studies Division MRC Laboratory of Molecular Biology Cambridge UK
See more in PubMed
Alushin GM et al. High-Resolution Microtubule Structures Reveal the Structural Transitions in αβ-Tubulin upon GTP Hydrolysis. Cell 157, 1117–1129 (2014). PubMed PMC
Hyman AA, Salser S, Drechsel DN, Unwin N & Mitchison TJ Role of GTP hydrolysis in microtubule dynamics: information from a slowly hydrolyzable analogue, GMPCPP. Mol. Biol. Cell 3, 1155–1167 (1992). PubMed PMC
Díaz JF, Barasoain I & Andreu JM Fast Kinetics of Taxol Binding to Microtubules: Effects of Solution Variables and Microtubule-associated proteins. J. Biol. Chem 278, 8407–8419 (2003). PubMed
Peet DR, Burroughs NJ & Cross RA Kinesin expands and stabilizes the GDP-microtubule lattice. Nat. Nanotechnol 13, 386–391 (2018). PubMed PMC
Zhang R, LaFrance B & Nogales E Separating the effects of nucleotide and EB binding on microtubule structure. Proc. Natl. Acad. Sci 115, E6191–E6200 (2018). PubMed PMC
Shima T et al. Kinesin-binding–triggered conformation switching of microtubules contributes to polarized transport. J. Cell Biol 217, 4164–4183 (2018). PubMed PMC
Maurer SP, Bieling P, Cope J, Hoenger A & Surrey T GTPγS microtubules mimic the growing microtubule end structure recognized by end-binding proteins (EBs). Proc. Natl. Acad. Sci 108, 3988–3993 (2011). PubMed PMC
Zanic M, Stear JH, Hyman AA & Howard J EB1 Recognizes the Nucleotide State of Tubulin in the Microtubule Lattice. PLoS One 4, e7585 (2009). PubMed PMC
Tan R et al. Microtubules gate tau condensation to spatially regulate microtubule functions. Nat. Cell Biol 21, 1078–1085 (2019). PubMed PMC
Castle BT, McKibben KM, Rhoades E & Odde DJ Tau Avoids the GTP Cap at Growing Microtubule Plus-Ends. iScience 23, 101782 (2020). PubMed PMC
Guedes-Dias P et al. Kinesin-3 Responds to Local Microtubule Dynamics to Target Synaptic Cargo Delivery to the Presynapse. Curr. Biol 29, 268–282 (2019). PubMed PMC
Dehmelt L & Halpain S The MAP2/Tau family of microtubule-associated proteins. Genome Biol. 6, 1–10 (2005). PubMed PMC
Sündermann F, Fernandez M & Morgan R An evolutionary roadmap to the microtubule-associated protein MAP Tau. BMC Genomics 17, (2016). PubMed PMC
Götz J, Halliday G & Nisbet RM Molecular Pathogenesis of the Tauopathies. Annu. Rev. Pathol. Mech. Dis 14, 239–261 (2019). PubMed
Li L, Zhang Q, Lei X, Huang Y & Hu J MAP4 as a New Candidate in Cardiovascular Disease. Front. Physiol 11, 1044 (2020). PubMed PMC
Monroy BY et al. A Combinatorial MAP Code Dictates Polarized Microtubule Transport. Dev. Cell 53, 60–72 (2020). PubMed PMC
Seitz A et al. Single-molecule investigation of the interference between kinesin, tau and MAP2c. EMBO J. 21, 4896–4905 (2002). PubMed PMC
Semenova I et al. Regulation of microtubule-based transport by MAP4. Mol. Biol. Cell 25, 3119–3132 (2014). PubMed PMC
Samora CP et al. MAP4 and CLASP1 operate as a safety mechanism to maintain a stable spindle position in mitosis. Nat. Cell Biol 13, 1040–1050 (2011). PubMed
Karasmanis EP et al. Polarity of Neuronal Membrane Traffic Requires Sorting of Kinesin Motor Cargo during Entry into Dendrites by a Microtubule-Associated Septin. Dev. Cell 46, 204–218.e7 (2018). PubMed PMC
Bulinski JC, McGraw TE, Gruber D, Lan Nguyen H & Sheetz MP Overexpression of MAP4 inhibits organelle motility and trafficking in vivo. J. Cell Sci 110, 3055–3064 (1997). PubMed
Hernández-Vega A et al. Local Nucleation of Microtubule Bundles through Tubulin Concentration into a Condensed Tau Phase. Cell Rep. 20, 2304–2312 (2017). PubMed PMC
Zhang X et al. The proline-rich domain promotes Tau liquid-liquid phase separation in cells. J. Cell Biol 219, e202006054 (2020). PubMed PMC
Zhang X et al. RNA stores tau reversibly in complex coacervates. PLOS Biol. 15, e2002183 (2017). PubMed PMC
Iqbal K, Liu F & Gong C-X Tau and neurodegenerative disease: the story so far. Nat. Rev. Neurol 12, 15–27 (2016). PubMed
Dixit R, Ross JL, Goldman YE & Holzbaur ELF Differential regulation of dynein and kinesin motor proteins by tau. Science (80-. ). 319, 1086–1089 (2008). PubMed PMC
McVicker DP, Hoeprich GJ, Thompson AR & Berger CL Tau interconverts between diffusive and stable populations on the microtubule surface in an isoform and lattice specific manner. Cytoskeleton 71, 184–194 (2014). PubMed PMC
Siahaan V et al. Kinetically distinct phases of tau on microtubules regulate kinesin motors and severing enzymes. Nat. Cell Biol 21, 1086–1092 (2019). PubMed
Chaudhary AR, Berger F, Berger CL & Hendricks AG Tau directs intracellular trafficking by regulating the forces exerted by kinesin and dynein teams. Traffic 19, 111–121 (2018). PubMed PMC
Diaz JF & Andreu JM Assembly of purified GDP-tubulin into microtubules induced by taxol and taxotere: Reversibility, ligand stoichiometry, and competition. Biochemistry 32, 2747–2755 (1993). PubMed
Kar S, Fan J, Smith MJ, Goedert M & Amos LA Repeat motifs of tau bind to the insides of microtubules in the absence of taxol. EMBO J. 22, 70–77 (2003). PubMed PMC
Lin Y et al. Toxic PR Poly-Dipeptides Encoded by the C9orf72 Repeat Expansion Target LC Domain Polymers. Cell 167, 789–802.e12 (2016). PubMed PMC
Samsonov A, Yu J-Z, Rasenick M & Popov SV Tau interaction with microtubules in vivo. J. Cell Sci 117, 6129–6141 (2004). PubMed
Balabanian L, Berger CL & Hendricks AG Acetylated Microtubules Are Preferentially Bundled Leading to Enhanced Kinesin-1 Motility. Biophys. J 113, 1551–1560 (2017). PubMed PMC
Ettinger A, van Haren J, Ribeiro SA & Wittmann T Doublecortin Is Excluded from Growing Microtubule Ends and Recognizes the GDP-Microtubule Lattice. Curr. Biol 26, 1549–1555 (2016). PubMed PMC
McKenney RJ, Huynh W, Vale RD & Sirajuddin M Tyrosination of α-tubulin controls the initiation of processive dynein–dynactin motility. EMBO J. 35, 1175–1185 (2016). PubMed PMC
Lam AJ et al. A highly conserved 310 helix within the kinesin motor domain is critical for kinesin function and human health. Sci. Adv 7, (2021). PubMed PMC
Budaitis BG et al. Pathogenic mutations in the kinesin-3 motor KIF1A diminish force generation and movement through allosteric mechanisms. J. Cell Biol 220, (2021). PubMed PMC
Chiba K et al. Disease-associated mutations hyperactivate KIF1A motility and anterograde axonal transport of synaptic vesicle precursors. Proc. Natl. Acad. Sci 116, 18429–18434 (2019). PubMed PMC
Boyle L et al. Genotype and defects in microtubule-based motility correlate with clinical severity in KIF1A-associated neurological disorder. Hum. Genet. Genomics Adv 2, 100026 (2021). PubMed PMC
Kellogg EH et al. Near-atomic model of microtubule-tau interactions. Science (80-. ). 360, 1242–1246 (2018). PubMed PMC
Wijeratne SS, Fiorenza SA, Subramanian R & Betterton MD Motor guidance by long-range communication through the microtubule highway. bioRxiv (2020) doi:10.1101/2020.12.23.424221. PubMed DOI PMC
Kim T & Rice LM Long-range, through-lattice coupling improves predictions of microtubule catastrophe. Mol. Biol. Cell 30, 1451–1462 (2019). PubMed PMC
Shigematsu H et al. Structural insight into microtubule stabilization and kinesin inhibition by Tau family MAPs. J. Cell Biol 217, 4155–4163 (2018). PubMed PMC
Gu Y, Oyama F & Ihara Y Tau is widely expressed in rat tissues. J. Neurochem 67, 1235–1244 (1996). PubMed
Shults NV et al. Tau Protein in Lung Smooth Muscle Cells. J. Respir 1, 30–39 (2020).
Howes SC et al. Structural differences between yeast and mammalian microtubules revealed by cryo-EM. J. Cell Biol 216, 2669–2677 (2017). PubMed PMC
Chaaban S et al. The Structure and Dynamics of C. elegans Tubulin Reveals the Mechanistic Basis of Microtubule Growth. Dev. Cell 47, 191–204 (2018). PubMed
Triclin S et al. Self-repair protects microtubules from destruction by molecular motors. Nat. Mater 20, 883–891 (2021). PubMed PMC
Soppina V & Verhey KJ The family-specific K-loop influences the microtubule on-rate but not the superprocessivity of kinesin-3 motors. Mol. Biol. Cell 25, 2161–2170 (2014). PubMed PMC
Henrichs V et al. Mitochondria-adaptor TRAK1 promotes kinesin-1 driven transport in crowded environments. Nat. Commun. 2020 111 11, 1–13 (2020). PubMed PMC
Gell C et al. Purification of Tubulin from Porcine Brain. Methods Mol. Biol 777, 15–28 (2011). PubMed
Tan R, Foster PJ, Needleman DJ & McKenney RJ Cooperative Accumulation of Dynein-Dynactin at Microtubule Minus-Ends Drives Microtubule Network Reorganization. Dev. Cell 44, 233–247 (2018). PubMed PMC
McKenney RJ, Huynh W, Tanenbaum ME, Bhabha G & Vale RD Activation of cytoplasmic dynein motility by dynactin-cargo adapter complexes. Science 345, 337–41 (2014). PubMed PMC
Zheng SQ et al. MotionCor2: anisotropic correction of beam-induced motion for improved cryo-electron microscopy. Nat. Methods 14, 331–332 (2017). PubMed PMC
Zivanov J et al. New tools for automated high-resolution cryo-EM structure determination in RELION-3. Elife 7, e42166 (2018). PubMed PMC
Schindelin J et al. Fiji: an open-source platform for biological-image analysis. Nat. Methods 9, 676–682 (2012). PubMed PMC
Chrétien D, Kenney JM, Fuller SD & Wade RH Determination of microtubule polarity by cryo-electron microscopy. Structure 4, 1031–1040 (1996). PubMed
MAP9/MAPH-9 supports axonemal microtubule doublets and modulates motor movement
Tubulin polyglutamylation differentially regulates microtubule-interacting proteins
