Structural and Molecular Basis for Katanin-Mediated Severing of Glutamylated Microtubules

Authors
Shin, Sang ChulIm, Sun-KyoungJang, Eun-HaeJin, Kyeong SikHur, Eun-MiKim, Eunice EunKyeong
Issue Date
2019-01-29
Publisher
CELL PRESS
Citation
CELL REPORTS, v.26, no.5, pp.1357 - +
Abstract
Katanin was the first microtubule (MT)-severing enzyme discovered, but how katanin executes MT severing remains poorly understood. Here, we report X-ray crystal structures of the apo and ATPgS-bound states of the catalytic AAA domain of human katanin p60 at 3.0 and 2.9 angstrom resolution, respectively. Comparison of the two structures reveals conformational changes induced by ATP binding and how such changes ensure hexamer stability. Moreover, we uncover structural details of pore loops (PLs) and show that Arg283, a residue unique to katanin among MT-severing enzymes, protrudes from PL1 and lines the entry of the catalytic pore. Functional studies suggest that PL1 and Arg283 play essential roles in the recognition and remodeling of the glutamylated, C-terminal tubulin tail and regulation of axon growth. In addition, domain-swapping experiments in katanin and spastin suggest that the non-homologous N-terminal region, which contains the MT-interacting and trafficking domain and a linker, confers specificity to the severing process.
Keywords
TUBULIN POLYGLUTAMYLASE; POSTTRANSLATIONAL MODIFICATIONS; IN-VIVO; PROTEIN; SPASTIN; ATPASE; RECOGNITION; ENZYMES; SYSTEM; GROWTH; TUBULIN POLYGLUTAMYLASE; POSTTRANSLATIONAL MODIFICATIONS; IN-VIVO; PROTEIN; SPASTIN; ATPASE; RECOGNITION; ENZYMES; SYSTEM; GROWTH; AAA ATPase; axon growth; crystal structure; glutamylation; katanin; microtubule severing
ISSN
2211-1247
URI
https://pubs.kist.re.kr/handle/201004/120446
DOI
10.1016/j.celrep.2019.01.020
Appears in Collections:
KIST Article > 2019
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