Structural properties of the truncated and wild types of Taka-amylase: A molecular dynamics simulation and docking study
نویسنده:
, , , , , , , , , , , ,سال
: 2013
چکیده: In this work, structures of the native (Amyl-C) and truncated Taka amylase were compared by
molecular modeling methods. Using in silico enzyme engineering approach, 50 (Amyl-S1) and
100 (Amyl-S2) amino acids were eliminated from Amyl-C to produce the truncated forms.
Analysis of the tertiary structures showed that three essential domains of the enzyme including
super 8 , the barrel region, and the large cleft remained native in Amyl-
S1 and Amyl-S2. Secondary structures of Met112-Val118, Gly202-His211, Gln230-Asp233,
Phe292-Asp297 residues in Amyl-C, Amyl-S1, and Amyl-S2 remained unchanged. These
domains are necessary for catalytic function of alpha-amylase superfamily. Flexibility analysis of
the three forms was examined and it is obtained that by truncation, the flexibility of the Cterminal
domain was increased. This shows that C-terminal domain is essential for the stability
of the structure which is in agreement with experimental observations. However, Glu156, Gln
162, Gly234, Val 245, Asn260, Ser264, Asp 297 of Amyl-C had higher flexibility than those in
truncated enzymes. Maltoriose, Maltotetraose, Maltopentaose, Maltohexaose and maltoheptaose
as five substrates were docked to the three enzyme forms. Binding affinity of maltoheptaose was
higher in Amyl-C and Amyl-S1and lower in Amyl-S2 than that of Maltoriose. In all forms the
substrates were associated with three residues of the catalytic triad.
molecular modeling methods. Using in silico enzyme engineering approach, 50 (Amyl-S1) and
100 (Amyl-S2) amino acids were eliminated from Amyl-C to produce the truncated forms.
Analysis of the tertiary structures showed that three essential domains of the enzyme including
super 8 , the barrel region, and the large cleft remained native in Amyl-
S1 and Amyl-S2. Secondary structures of Met112-Val118, Gly202-His211, Gln230-Asp233,
Phe292-Asp297 residues in Amyl-C, Amyl-S1, and Amyl-S2 remained unchanged. These
domains are necessary for catalytic function of alpha-amylase superfamily. Flexibility analysis of
the three forms was examined and it is obtained that by truncation, the flexibility of the Cterminal
domain was increased. This shows that C-terminal domain is essential for the stability
of the structure which is in agreement with experimental observations. However, Glu156, Gln
162, Gly234, Val 245, Asn260, Ser264, Asp 297 of Amyl-C had higher flexibility than those in
truncated enzymes. Maltoriose, Maltotetraose, Maltopentaose, Maltohexaose and maltoheptaose
as five substrates were docked to the three enzyme forms. Binding affinity of maltoheptaose was
higher in Amyl-C and Amyl-S1and lower in Amyl-S2 than that of Maltoriose. In all forms the
substrates were associated with three residues of the catalytic triad.
کلیدواژه(گان): protein engineering,truncated amylase,Gromacs,C-terminal
کالکشن
:
-
آمار بازدید
Structural properties of the truncated and wild types of Taka-amylase: A molecular dynamics simulation and docking study
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| contributor author | محمدرضا حسین دخت | en |
| contributor author | Mohammad Reza Bozorgmehr | en |
| contributor author | حسین اشتیاق حسینی | en |
| contributor author | راضیه جلال | en |
| contributor author | احمد آسوده | en |
| contributor author | Mahin Saberi | en |
| contributor author | Zeinab Haratipour | en |
| contributor author | حسن منهمی | en |
| contributor author | Mohammad Reza Housaindokht | fa |
| contributor author | Hossein Eshtiagh Hosseini | fa |
| contributor author | Razieh Jalal | fa |
| contributor author | Ahmad Asoodeh | fa |
| contributor author | Hassan Monhemi | fa |
| date accessioned | 2020-06-06T13:12:58Z | |
| date available | 2020-06-06T13:12:58Z | |
| date issued | 2013 | |
| identifier uri | http://libsearch.um.ac.ir:80/fum/handle/fum/3346209 | |
| description abstract | In this work, structures of the native (Amyl-C) and truncated Taka amylase were compared by molecular modeling methods. Using in silico enzyme engineering approach, 50 (Amyl-S1) and 100 (Amyl-S2) amino acids were eliminated from Amyl-C to produce the truncated forms. Analysis of the tertiary structures showed that three essential domains of the enzyme including super 8 , the barrel region, and the large cleft remained native in Amyl- S1 and Amyl-S2. Secondary structures of Met112-Val118, Gly202-His211, Gln230-Asp233, Phe292-Asp297 residues in Amyl-C, Amyl-S1, and Amyl-S2 remained unchanged. These domains are necessary for catalytic function of alpha-amylase superfamily. Flexibility analysis of the three forms was examined and it is obtained that by truncation, the flexibility of the Cterminal domain was increased. This shows that C-terminal domain is essential for the stability of the structure which is in agreement with experimental observations. However, Glu156, Gln 162, Gly234, Val 245, Asn260, Ser264, Asp 297 of Amyl-C had higher flexibility than those in truncated enzymes. Maltoriose, Maltotetraose, Maltopentaose, Maltohexaose and maltoheptaose as five substrates were docked to the three enzyme forms. Binding affinity of maltoheptaose was higher in Amyl-C and Amyl-S1and lower in Amyl-S2 than that of Maltoriose. In all forms the substrates were associated with three residues of the catalytic triad. | en |
| language | English | |
| title | Structural properties of the truncated and wild types of Taka-amylase: A molecular dynamics simulation and docking study | en |
| type | Journal Paper | |
| contenttype | External Fulltext | |
| subject keywords | protein engineering | en |
| subject keywords | truncated amylase | en |
| subject keywords | Gromacs | en |
| subject keywords | C-terminal | en |
| journal title | Journal of Molecular Catalysis B: Enzymatic | fa |
| pages | 36-40 | |
| journal volume | 95 | |
| journal issue | 0 | |
| identifier link | https://profdoc.um.ac.ir/paper-abstract-1034702.html | |
| identifier articleid | 1034702 |