Gene/Protein
Disease
Symptom
Drug
Enzyme
Compound
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Gene/Protein
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Target Concepts:
Gene/Protein
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Query: EC:3.4.24.27 (
thermolysin
)
1,894
document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)
The amino acid sequence of the neutral zinc protease from Bacillus mesentericus strain 76 (
MCP
76) has been determined by using peptides derived from digests with trypsin, chymotrypsin, and cyanogen bromide and from cleavage with o-iodosobenzoic acid. The peptides were purified by means of gel filtration and reversed-phase high-performance liquid chromatography and analyzed by automatic sequencing. The protein contains 300 amino acid residues. It proved to be identical with the neutral protease deduced from the DNA precursor sequence of Bacillus subtilis. The residues for zinc and substrate binding are conserved, whereas the number of calcium binding sites is reduced compared to
thermolysin
. A classification of the neutral zinc protease is discussed.
...
PMID:Primary structure of a zinc protease from Bacillus mesentericus strain 76. 230 86
The proteolytic specificity of the neutral zinc proteinase from Bacillus mesentericus strain 76 (
MCP
76)/Bacillus subtilis was determined by using the alpha-chain of walrus hemoglobin as substrate. The resulting peptides were fractionated by gel filtration and than isolated by reversed-phase HPLC. The peptides were identified on the basis of their amino-acid compositions and aligned with the known sequence of the walrus alpha-chain. The proteolytic specificity of
MCP
76, deduced from the experimental cleavage pattern is compared to that of
thermolysin
. The amino-acid residues in positions P1 and P'1 on both sides of the scissible bond are considered as most important for the cleavage.
MCP
76 prefers leucine, valine, phenylalanine and threonine in position P'1 as well as lysine, threonine, leucine and alanine in position P1 and thus differs from
thermolysin
which shows no preference for threonine in P'1 and accepts numerous amino-acid residues of different type in P1.
...
PMID:Proteolytic specificity of the neutral zinc proteinase from Bacillus mesentericus strain 76 determined by digestion of an alpha-globin chain. 251 21
Increased conformational flexibility is the prevailing explanation for the high catalytic efficiency of cold-adapted enzymes at low temperatures. However, less is known about the structural determinants of flexibility. We reported two novel cold-adapted zinc metalloproteases in the
thermolysin
family, vibriolysin
MCP
-02 from a deep sea bacterium and vibriolysin E495 from an Arctic sea ice bacterium, and compared them with their mesophilic homolog, pseudolysin from a terrestrial bacterium. Their catalytic efficiencies, k(cat)/K(m) (10-40 degrees C), followed the order pseudolysin <
MCP
-02 < E495 with a ratio of approximately 1:2:4.
MCP
-02 and E495 have the same optimal temperature (T(opt), 57 degrees C, 5 degrees C lower than pseudolysin) and apparent melting temperature (T(m) = 64 degrees C, approximately 10 degrees C lower than pseudolysin). Structural analysis showed that the slightly lower stabilities resulted from a decrease in the number of salt bridges. Fluorescence quenching experiments and molecular dynamics simulations showed that the flexibilities of the proteins were pseudolysin <
MCP
-02 < E495, suggesting that optimization of flexibility is a strategy for cold adaptation. Molecular dynamics results showed that the ordinal increase in flexibility from pseudolysin to
MCP
-02 and E495, especially the increase from
MCP
-02 to E495, mainly resulted from the decrease of hydrogen-bond stability in the dynamic structure, which was due to the increase in asparagine, serine, and threonine residues. Finally, a model for the cold adaptation of
MCP
-02 and E495 was proposed. This is the first report of the optimization of hydrogen-bonding dynamics as a strategy for cold adaptation and provides new insights into the structural basis underlying conformational flexibility.
...
PMID:Cold adaptation of zinc metalloproteases in the thermolysin family from deep sea and arctic sea ice bacteria revealed by catalytic and structural properties and molecular dynamics: new insights into relationship between conformational flexibility and hydrogen bonding. 1918 63
