Abstract
Vasohibins regulate angiogenesis, tumor growth, metastasis and neuronal differentiation. They form a complex with small vasohibin-binding protein (SVBP) and show tubulin tyrosine carboxypeptidase activity. Recent crystal structure determinations of vasohibin-SVBP complexes have provided a molecular basis for complex formation, substrate binding and catalytic activity. However, the regulatory mechanism and dynamics of the complex remain elusive. Here, the crystal structure of the VASH1-SVBP complex and a molecular-dynamics simulation study are reported. The overall structure of the complex was similar to previously reported structures. Importantly, however, the structure revealed a domain-swapped heterotetramer that was formed between twofold symmetry-related molecules. This heterotetramerization was stabilized by the mutual exchange of ten conserved N-terminal residues from the VASH1 structural core, which was intramolecular in other structures. Interestingly, a comparison of this region with previously reported structures revealed that the patterns of hydrogen bonding and hydrophobic interactions vary. In the molecular-dynamics simulations, differences were found between the heterotetramer and heterodimer, where the fluctuation of the N-terminal region in the heterotetramer was suppressed. Thus, heterotetramer formation and flexibility of the N-terminal region may be important for enzyme activity and regulation.
Highlights
Vasohibin was first discovered as a factor involved in angiogenesis and is widely conserved among vertebrate species
X-ray crystal structures of VASH1–small vasohibin-binding protein (SVBP) complexes (PDB entries 6j7b and 6ocf and the heterotetramer solved in this study; Liao et al, 2019; Li et al, 2019) were used for MD simulations
For each VASH1–SVBP complex, three independent MD simulations were performed with different random seeds for the Langevin thermostat
Summary
Vasohibin was first discovered as a factor involved in angiogenesis and is widely conserved among vertebrate species. Vasohibins and SVBP have recently been found to be involved in the development of neurons and normal basement-membrane formation in the renal corpuscles (Pagnamenta et al, 2019; reviewed in Tanabe et al, 2018). In this pathway, vasohibin participates in the post-translational modification of tubulin, which is known to control neuron differentiation. Vasohibin participates in the post-translational modification of tubulin, which is known to control neuron differentiation Both the VASH1–SVBP and VASH2–SVBP complexes function as a tubulin carboxypeptidase to cleave the terminal tyrosine residue, and the difference between the two paralogs remains elusive. We performed molecular-dynamics (MD) simulations of the heterotetramer and heterodimer in order to compare their conformational flexibility
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