Role of a high centrality residue in protein dynamics and thermal stability.
Nenhuma Miniatura disponível
Data
2021
Título da Revista
ISSN da Revista
Título de Volume
Editor
Resumo
Centralities determined from Residue Interaction Networks (RIN) in proteins have been used to predict aspects of
their structure and dynamics. Here, we correlate the Eigenvector Centrality (Ec) with the rate constant for
thermal denaturation (kden) of the HisF protein from Thermotoga maritima based on 12 single alanine substitution
mutants. The molecular basis for this correlation was further explored by studying a mutant containing a
replacement of a high Ec residue, Y182A, which displayed increased kden at 80 ◦C. The crystallographic structure
of this mutant showed few changes, mostly in two flexible loops. The 1
H-15N -HSQC showed only subtle changes
of cross peak positions for residues located near the mutation site and scattered throughout the structure.
However, the comparison of the RIN showed that Y182 is the vertex of a set of high centrality residues that
spreads throughout the HisF structure, which is lacking in the mutant. Cross-correlation displacements of Cα
calculated from a molecular dynamics simulation at different temperatures showed that the Y182A mutation
reduced the correlated movements in the HisF structure above 70 ◦C. 1
H-15N NMR chemical shift covariance
using temperature as perturbation were consistent with these results. In conclusion the increase in temperature
drives the structure of the mutant HisF-Y182A into a less connected state, richer in non-concerted motions,
located predominantly in the C-terminal half of the protein where Y182 is placed. Conversely, wild-type HisF
responds to increased temperature as a single unit. Hence the replacement of a high Ec residue alters the dis-
tribution of thermal energy through HisF structure.
Descrição
Palavras-chave
Citação
ALMEIDA, V. M. et al. Role of a high centrality residue in protein dynamics and thermal stability. Journal of Structural Biology, v. 213, artigo 107773, 2021. Disponível em: <https://www.sciencedirect.com/science/article/pii/S1047847721000782>. Acesso em: 11 out. 2022.