Functional annotation of the mesophilic-like character of mutants in a cold-adapted enzyme by self-organising map analysis of their molecular dynamics

Domenico Fraccalvieri; Matteo Tiberti; Alessandro Pandini; Laura Bonati; Elena Papaleo

doi:10.1039/c2mb25192b

Functional annotation of the mesophilic-like character of mutants in a cold-adapted enzyme by self-organising map analysis of their molecular dynamics

Domenico Fraccalvieri, Matteo Tiberti, Alessandro Pandini, Laura Bonati, Elena Papaleo

11 Citations (Scopus)

Abstract

Multiple comparison of the Molecular Dynamics (MD) trajectories of mutants in a cold-adapted α-amylase (AHA) could be used to elucidate functional features required to restore mesophilic-like activity. Unfortunately it is challenging to identify the different dynamic behaviors and correctly relate them to functional activity by routine analysis. We here employed a previously developed and robust two-stage approach that combines Self-Organising Maps (SOMs) and hierarchical clustering to compare conformational ensembles of proteins. Moreover, we designed a novel strategy to identify the specific mutations that more efficiently convert the dynamic signature of the psychrophilic enzyme (AHA) to that of the mesophilic counterpart (PPA). The SOM trained on AHA and its variants was used to classify a PPA MD ensemble and successfully highlighted the relationships between the flexibilities of the target enzyme and of the different mutants. Moreover the local features of the mutants that mostly influence their global flexibility in a mesophilic-like direction were detected. It turns out that mutations of the cold-adapted enzyme to hydrophobic and aromatic residues are the most effective in restoring the PPA dynamic features and could guide the design of more mesophilic-like mutants. In conclusion, our strategy can efficiently extract specific dynamic signatures related to function from multiple comparisons of MD conformational ensembles. Therefore, it can be a promising tool for protein engineering.

Original language	English
Journal	Molecular BioSystems
Volume	8
Issue number	10
Pages (from-to)	2680-2691
Number of pages	12
ISSN	1742-206X
DOIs	https://doi.org/10.1039/c2mb25192b
Publication status	Published - Oct 2012
Externally published	Yes

Keywords

Algorithms
Amino Acid Sequence
Bacterial Proteins
Cluster Analysis
Cold Temperature
Models, Molecular
Molecular Conformation
Molecular Dynamics Simulation
Molecular Sequence Data
Mutation
Protein Engineering
Proteomics
Pseudoalteromonas
Thermodynamics
alpha-Amylases

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Functional annotation of the mesophilic-like character of mutants in a cold-adapted enzyme by self-organising map analysis of their molecular dynamics. / Fraccalvieri, Domenico; Tiberti, Matteo; Pandini, Alessandro et al.

In: Molecular BioSystems, Vol. 8, No. 10, 10.2012, p. 2680-2691.

Research output: Contribution to journal › Journal article › Research › peer-review

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title = "Functional annotation of the mesophilic-like character of mutants in a cold-adapted enzyme by self-organising map analysis of their molecular dynamics",

abstract = "Multiple comparison of the Molecular Dynamics (MD) trajectories of mutants in a cold-adapted α-amylase (AHA) could be used to elucidate functional features required to restore mesophilic-like activity. Unfortunately it is challenging to identify the different dynamic behaviors and correctly relate them to functional activity by routine analysis. We here employed a previously developed and robust two-stage approach that combines Self-Organising Maps (SOMs) and hierarchical clustering to compare conformational ensembles of proteins. Moreover, we designed a novel strategy to identify the specific mutations that more efficiently convert the dynamic signature of the psychrophilic enzyme (AHA) to that of the mesophilic counterpart (PPA). The SOM trained on AHA and its variants was used to classify a PPA MD ensemble and successfully highlighted the relationships between the flexibilities of the target enzyme and of the different mutants. Moreover the local features of the mutants that mostly influence their global flexibility in a mesophilic-like direction were detected. It turns out that mutations of the cold-adapted enzyme to hydrophobic and aromatic residues are the most effective in restoring the PPA dynamic features and could guide the design of more mesophilic-like mutants. In conclusion, our strategy can efficiently extract specific dynamic signatures related to function from multiple comparisons of MD conformational ensembles. Therefore, it can be a promising tool for protein engineering.",

keywords = "Algorithms, Amino Acid Sequence, Bacterial Proteins, Cluster Analysis, Cold Temperature, Models, Molecular, Molecular Conformation, Molecular Dynamics Simulation, Molecular Sequence Data, Mutation, Protein Engineering, Proteomics, Pseudoalteromonas, Thermodynamics, alpha-Amylases",

author = "Domenico Fraccalvieri and Matteo Tiberti and Alessandro Pandini and Laura Bonati and Elena Papaleo",

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T1 - Functional annotation of the mesophilic-like character of mutants in a cold-adapted enzyme by self-organising map analysis of their molecular dynamics

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AU - Tiberti, Matteo

AU - Pandini, Alessandro

AU - Bonati, Laura

AU - Papaleo, Elena

PY - 2012/10

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N2 - Multiple comparison of the Molecular Dynamics (MD) trajectories of mutants in a cold-adapted α-amylase (AHA) could be used to elucidate functional features required to restore mesophilic-like activity. Unfortunately it is challenging to identify the different dynamic behaviors and correctly relate them to functional activity by routine analysis. We here employed a previously developed and robust two-stage approach that combines Self-Organising Maps (SOMs) and hierarchical clustering to compare conformational ensembles of proteins. Moreover, we designed a novel strategy to identify the specific mutations that more efficiently convert the dynamic signature of the psychrophilic enzyme (AHA) to that of the mesophilic counterpart (PPA). The SOM trained on AHA and its variants was used to classify a PPA MD ensemble and successfully highlighted the relationships between the flexibilities of the target enzyme and of the different mutants. Moreover the local features of the mutants that mostly influence their global flexibility in a mesophilic-like direction were detected. It turns out that mutations of the cold-adapted enzyme to hydrophobic and aromatic residues are the most effective in restoring the PPA dynamic features and could guide the design of more mesophilic-like mutants. In conclusion, our strategy can efficiently extract specific dynamic signatures related to function from multiple comparisons of MD conformational ensembles. Therefore, it can be a promising tool for protein engineering.

AB - Multiple comparison of the Molecular Dynamics (MD) trajectories of mutants in a cold-adapted α-amylase (AHA) could be used to elucidate functional features required to restore mesophilic-like activity. Unfortunately it is challenging to identify the different dynamic behaviors and correctly relate them to functional activity by routine analysis. We here employed a previously developed and robust two-stage approach that combines Self-Organising Maps (SOMs) and hierarchical clustering to compare conformational ensembles of proteins. Moreover, we designed a novel strategy to identify the specific mutations that more efficiently convert the dynamic signature of the psychrophilic enzyme (AHA) to that of the mesophilic counterpart (PPA). The SOM trained on AHA and its variants was used to classify a PPA MD ensemble and successfully highlighted the relationships between the flexibilities of the target enzyme and of the different mutants. Moreover the local features of the mutants that mostly influence their global flexibility in a mesophilic-like direction were detected. It turns out that mutations of the cold-adapted enzyme to hydrophobic and aromatic residues are the most effective in restoring the PPA dynamic features and could guide the design of more mesophilic-like mutants. In conclusion, our strategy can efficiently extract specific dynamic signatures related to function from multiple comparisons of MD conformational ensembles. Therefore, it can be a promising tool for protein engineering.

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KW - Amino Acid Sequence

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KW - Cluster Analysis

KW - Cold Temperature

KW - Models, Molecular

KW - Molecular Conformation

KW - Molecular Dynamics Simulation

KW - Molecular Sequence Data

KW - Mutation

KW - Protein Engineering

KW - Proteomics

KW - Pseudoalteromonas

KW - Thermodynamics

KW - alpha-Amylases

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DO - 10.1039/c2mb25192b

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SN - 1742-206X

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JF - Molecular BioSystems

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ER -

Functional annotation of the mesophilic-like character of mutants in a cold-adapted enzyme by self-organising map analysis of their molecular dynamics

Abstract

Keywords

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