9F3B image
Entry Detail
PDB ID:
9F3B
EMDB ID:
Title:
Undecorated 13pf E254Q microtubule from recombinant human tubulin
Biological Source:
Source Organism:
Host Organism:
PDB Version:
Deposition Date:
2024-04-25
Release Date:
2025-03-19
Method Details:
Experimental Method:
Resolution:
3.60 Å
Aggregation State:
HELICAL ARRAY
Reconstruction Method:
SINGLE PARTICLE
Macromolecular Entities
Polymer Type:polypeptide(L)
Description:Detyrosinated tubulin alpha-1B chain
Chain IDs:A, C (auth: G), E (auth: C), G (auth: I), I (auth: E), K
Chain Length:453
Number of Molecules:6
Biological Source:Homo sapiens
Polymer Type:polypeptide(L)
Description:Tubulin beta-3 chain
Chain IDs:B, D (auth: N), F (auth: D), H (auth: P), J (auth: F), L (auth: R)
Chain Length:456
Number of Molecules:6
Biological Source:Homo sapiens
Primary Citation
Hydrolysis-deficient mosaic microtubules as faithful mimics of the GTP cap.
Nat Commun 16 2396 2396 (2025)
PMID: 40064882 DOI: 10.1038/s41467-025-57555-6

Abstact

A critical feature of microtubules is their GTP cap, a stabilizing GTP-tubulin rich region at growing microtubule ends. Microtubules polymerized in the presence of GTP analogs or from GTP hydrolysis-deficient tubulin mutants have been used as GTP-cap mimics for structural and biochemical studies. However, these analogs and mutants generate microtubules with diverse biochemical properties and lattice structures, leaving it unclear what is the most faithful GTP mimic and hence the structure of the GTP cap. Here, we generate a hydrolysis-deficient human tubulin mutant, αE254Q, with the smallest possible modification. We show that αE254Q-microtubules are stable, but still exhibit mild mutation-induced growth abnormalities. However, mixing two GTP hydrolysis-deficient tubulin mutants, αE254Q and αE254N, at an optimized ratio eliminates growth and lattice abnormalities, indicating that these 'mosaic microtubules' are faithful GTP cap mimics. Their cryo-electron microscopy structure reveals that longitudinal lattice expansion, but not protofilament twist, is the primary structural feature distinguishing the GTP-tubulin containing cap from the GDP-tubulin containing microtubule shaft. However, alterations in protofilament twist may be transiently needed to allow lattice compaction and GTP hydrolysis. Together, our results provide insights into the structural origin of GTP cap stability, the pathway of GTP hydrolysis and hence microtubule dynamic instability.

Legend

Protein

Chemical

Disease

Primary Citation of related structures