Abstract
Microtubules, which are composed of heterodimers of α-tubulin (TUA) and β-tubulin (TUB) proteins, are closely associated with cellulose microfibril deposition and play pivotal roles in plant secondary cell wall development. In the present study, we identified eight TUA and twenty TUB genes in willow (Salix arbutifolia). Quantitative real-time PCR analysis showed that the small number of TUA gene family members relative to that of TUBs was complemented by a higher transcript copy number for each TUA gene, which is essential to the maintenance of the tubulin 1:1 heterodimer assembly. In Salix, five of eight TUAs were determined to be unusual because these contained a C-terminal methionine acid, leucine acid, glutamic acid, and glutamine acid, instead of the more typical tyrosine residue, which in turn generated the hypothesis of post-translational modifications (PTMs) that included deleucylation, demethiolation, deglutamynation, and deaspartylation. These PTMs are responsible for the removal of additional amino acid residues from TUAs prior to detyrosination, which is the first step of C-terminal PTMs. The additional PTMs of the TUA gene family might be responsible for the formation of different tubulin heterodimers that may have diverse functions for the adaptation of the woody perennial growth for Salix.
Highlights
Lead to the appearance of various tubulin isoforms and classes of MTs21–27
A large number of tubulin isotypes have been isolated from different species, whereas investigations on PTMs in plant tubulin are limited
We report the cloning, sequencing, and analysis of gene structure, phylogenetic diversity, and expression patterns of eight TUA genes and twenty TUB genes in S. arbutifolia
Summary
A large number of tubulin isotypes have been isolated from different species, whereas investigations on PTMs in plant tubulin are limited. Willow (S. arbutifolia) is a fast-growing tree and is cold-resistant, rendering it an ideal material for biomass production research. The interest of using willow for biomass production is growing, thereby resulting in increased pressure on breeding high yielding and resistant clones that are adapted to different environments[28]. We report the cloning, sequencing, and analysis of gene structure, phylogenetic diversity, and expression patterns of eight TUA genes and twenty TUB genes in S. arbutifolia. We analyzed the amino acid residues at the C-terminal region of the TUA and TUB proteins, and our results have prompted us to speculate that the other PTMs are related to the new C-terminal amino acid residues in Salix
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