Dystonia-4 (DYT4)-associated TUBB4A mutants exhibit disorganized microtubule networks and inhibit neuronal process growth

Dystonia-1 (DYT1) is an autosomal dominant early-onset torsion form of dystonia, a neurological disease affecting movement. DYT1 is the prototypic hereditary dystonia and is caused by the mutation of the tor1a gene. The gene product has chaperone functions important for the control of protein foldin...

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Bibliographic Details
Published in:Biochemical and biophysical research communications 2018-01, Vol.495 (1), p.346-352
Main Authors: Watanabe, Natsumi, Itakaoka, Misa, Seki, Yoich, Morimoto, Takako, Homma, Keiichi, Miyamoto, Yuki, Yamauchi, Junji
Format: Article
Language:English
Subjects:
60 APPLIED LIFE SCIENCES
DISEASES
Dystonia-4
Microtubule
MICROTUBULES
Process growth
PROTEINS
TUBB4A
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Summary:Dystonia-1 (DYT1) is an autosomal dominant early-onset torsion form of dystonia, a neurological disease affecting movement. DYT1 is the prototypic hereditary dystonia and is caused by the mutation of the tor1a gene. The gene product has chaperone functions important for the control of protein folding and stability. Dystonia-4 (DYT4) is another autosomal dominant dystonia that is characterized by onset in the second to third decade of progressive laryngeal dysphonia. DYT4 is associated with the mutation of the tubb4a gene, although it remains to be understood how disease-associated mutation affects biochemical as well as cell biological properties of the gene product as the microtubule component (a tubulin beta subunit). Herein we demonstrate that DYT4-associated TUBB4A missense mutants (Arg2-to-Gly or Ala271-to-Thr) form disorganized tubulin networks in cells. Transfected mutants are indeed expressed in cytoplasmic regions, as observed in wild-type transfectants. However, mutant proteins do not exhibit typical radial tubulin networks. Rather, they have diminished ability to interact with tubulin alpha subunits. Processes do not form in sufficient amounts in cells of the N1E-115 neuronal cell line expressing each of these mutants as compared to parental cells. Together, DYT4-associated TUBB4A mutants themselves form aberrant tubulin networks and inhibit neuronal process growth, possibly explaining progress through the pathological states at cellular levels. •Dystonia-4-associated TUBB4A mutants (R2G) exhibit disorganized tubulin networks.•Dystonia-4-associated TUBB4A mutants (A271T) exhibit disorganized tubulin networks.•Dystonia-4-associated mutants have diminished ability to interact with alpha-type tubulins.•Dystonia-4-associated mutants show inhibited neurite growth in a neuronal cell line.
ISSN:0006-291X
1090-2104
DOI:10.1016/j.bbrc.2017.11.038