Hydrophobic interactions between the secondary structures on the molecular surface reinforce the alkaline stability of serine protease

Yuki Oguchi; Hiroshi Maeda; Keietsu Abe; Tasuku Nakajima; Takafumi Uchida; Youhei Yamagata

doi:10.1007/s10529-006-9100-0

Hydrophobic interactions between the secondary structures on the molecular surface reinforce the alkaline stability of serine protease

Yuki Oguchi, Hiroshi Maeda, Keietsu Abe, Tasuku Nakajima, Takafumi Uchida, Youhei Yamagata

AGR - Agricultural Chemistry

Tohoku University

Research output: Contribution to journal › Article › peer-review

6 Citations (Scopus)

Abstract

We employed random mutagenesis to determine the region of the initial unfolding of hyper-alkaline-sensitive subtilisin, ALP I, that precedes the denaturation of the entire protein under highly alkaline conditions. This region comprises two α-helices and a calcium-binding loop. Stabilization of the region caused the stabilization of the entire protein at a high alkaline pH 12. The alkaline stability of this region was most effectively improved by hydrophobic interactions, followed by ionic interactions with Arg residues. The effect of mutations on the improvement was different with regard to the alkaline stability and thermostability. This indicated that different strategies were necessary to improve the alkaline stability and thermostability of the protein.

Original language	English
Pages (from-to)	1383-1391
Number of pages	9
Journal	Biotechnology Letters
Volume	28
Issue number	17
DOIs	https://doi.org/10.1007/s10529-006-9100-0
Publication status	Published - 2006 Sept

Keywords

Alkaline stability
Hydrophobic interaction
Protein structure
Secondary structures
Subtilisin

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10.1007/s10529-006-9100-0

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abstract = "We employed random mutagenesis to determine the region of the initial unfolding of hyper-alkaline-sensitive subtilisin, ALP I, that precedes the denaturation of the entire protein under highly alkaline conditions. This region comprises two α-helices and a calcium-binding loop. Stabilization of the region caused the stabilization of the entire protein at a high alkaline pH 12. The alkaline stability of this region was most effectively improved by hydrophobic interactions, followed by ionic interactions with Arg residues. The effect of mutations on the improvement was different with regard to the alkaline stability and thermostability. This indicated that different strategies were necessary to improve the alkaline stability and thermostability of the protein.",

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T1 - Hydrophobic interactions between the secondary structures on the molecular surface reinforce the alkaline stability of serine protease

AU - Oguchi, Yuki

AU - Maeda, Hiroshi

AU - Abe, Keietsu

AU - Nakajima, Tasuku

AU - Uchida, Takafumi

AU - Yamagata, Youhei

PY - 2006/9

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AB - We employed random mutagenesis to determine the region of the initial unfolding of hyper-alkaline-sensitive subtilisin, ALP I, that precedes the denaturation of the entire protein under highly alkaline conditions. This region comprises two α-helices and a calcium-binding loop. Stabilization of the region caused the stabilization of the entire protein at a high alkaline pH 12. The alkaline stability of this region was most effectively improved by hydrophobic interactions, followed by ionic interactions with Arg residues. The effect of mutations on the improvement was different with regard to the alkaline stability and thermostability. This indicated that different strategies were necessary to improve the alkaline stability and thermostability of the protein.

KW - Alkaline stability

KW - Hydrophobic interaction

KW - Protein structure

KW - Secondary structures

KW - Subtilisin

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Hydrophobic interactions between the secondary structures on the molecular surface reinforce the alkaline stability of serine protease

Abstract

Keywords

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