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Flexibility of cold- and heat-adapted subtilisin-like serine proteinases evaluated with fluorescence quenching and molecular dynamics

The subtilisin-like serine proteinases, VPR, from a psychrotrophic Vibrio species and aqualysin I (AQUI) from the thermophile Thermus aquaticus, are structural homologues, but differ significantly with respect to stability and catalytic properties. It has been postulated that the higher catalytic ac...

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Published in:Biochimica et biophysica acta 2014-04, Vol.1844 (4), p.705-712
Main Authors: Sigtryggsdóttir, Ásta Rós, Papaleo, Elena, Thorbjarnardóttir, Sigríður H., Kristjánsson, Magnús M.
Format: Article
Language:English
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Summary:The subtilisin-like serine proteinases, VPR, from a psychrotrophic Vibrio species and aqualysin I (AQUI) from the thermophile Thermus aquaticus, are structural homologues, but differ significantly with respect to stability and catalytic properties. It has been postulated that the higher catalytic activity of cold adapted enzymes when compared to homologues from thermophiles, reflects their higher molecular flexibility. To assess a potential difference in molecular flexibility between the two homologous proteinases, we have measured their Trp fluorescence quenching by acrylamide at different temperatures. We also investigated protein dynamics of VPR and AQUI at an atomic level by molecular dynamics simulations. VPR contains four Trp residues, three of which are at corresponding sites in the structure of AQUI. To aid in the comparison, a Tyr at the fourth corresponding site in AQUI was mutated to Trp (Y191W). A lower quenching effect of acrylamide on the intrinsic fluorescence of the thermophilic AQUI_Y191W was observed at all temperatures measured (10–55°C), suggesting that it possesses a more rigid structure than VPR. The MD analysis (Cα rmsf profiles) showed that even though VPR and AQUI have similar flexibility profiles, the cold adapted VPR displays higher flexibility in most regions of the protein structure. Some of these regions contain or are in proximity to some of the Trp residues (Trp6, Trp114 and Trp208) in the proteins. Thus, we observe an overall agreement between the fluorescence quenching data and the flexibility profiles obtained from the MD simulations to different flexibilities of specific regions in the proteins. •The Trp fluorescence quenching effect was lower for the thermophilic subtilase, AQUI.•MD show that the cold adapted VPR is more flexible in most regions of its structure.•Agreement was observed between fluorescence data and flexibility profiles by MD.•The cold adapted VPR has more localized flexibility than its thermophilic counterpart.•Results are in line with hypotheses on the role of flexibility in temperature adaptation.
ISSN:1570-9639
0006-3002
1878-1454
DOI:10.1016/j.bbapap.2014.02.009