The Structural and Functional Identity of the Protein Kinase Superfamily

The human protein kinase superfamily consists of over 500 members that individually control specific aspects of cell behavior and collectively control the complete range of cellular processes. That such a large group of proteins is able to uniquely diversify and establish individual identities while...

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Main Author: Knight, James D R
Language:en
Published: 2011
Subjects:
Online Access:http://hdl.handle.net/10393/20232
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spelling ndltd-LACETR-oai-collectionscanada.gc.ca-OOU.-en#10393-202322013-01-11T13:33:11ZThe Structural and Functional Identity of the Protein Kinase SuperfamilyKnight, James D Rkinasecell behaviourcatalytic domainprotein structural alignmentmolecular biologysubstrate bindingThe human protein kinase superfamily consists of over 500 members that individually control specific aspects of cell behavior and collectively control the complete range of cellular processes. That such a large group of proteins is able to uniquely diversify and establish individual identities while retaining common enzymatic function and significant sequence/structural conservation is remarkable. The means by which this is achieved is poorly understood, and we have begun to examine the issue by performing a comparative analysis of the catalytic domain of protein kinases. A novel approach for protein structural alignment has revealed a high degree of similarity found across the kinase superfamily, with variability confined largely to a single region thought to be involved in substrate binding. The similarity detected is not limited to amino acids, but includes a group of conserved water molecules that play important structural roles in stabilizing critical residues and the fold of the kinase domain. The development of a novel technique for identifying kinase substrates on a large scale directly from cell lysate has revealed that substrate specificity is not what discriminates the closely related p38α and β mitogen-activated protein kinases. Instead cellular localization appears to be their distinguishing characteristic, at least during myoblast differentiation. Together these results highlight the extent of conservation, as well as the minimal variability, that is found in the catalytic domain of all protein kinase superfamily members, and that while distantly related kinases may be distinguished by substrate specificity, closely related kinases are likely to be distinguished by other factors. Although these results focus on representative members of the kinase superfamily, they give insight as to how all protein kinases likely diversified and established unique non-redundant identities. In addition, the novel techniques developed and presented here for structural alignment and substrate discovery offer new tools for studying molecular biology and cell signaling.2011-09-22T15:37:05Z2011-09-22T15:37:05Z20112011-09-22http://hdl.handle.net/10393/20232en
collection NDLTD
language en
sources NDLTD
topic kinase
cell behaviour
catalytic domain
protein structural alignment
molecular biology
substrate binding
spellingShingle kinase
cell behaviour
catalytic domain
protein structural alignment
molecular biology
substrate binding
Knight, James D R
The Structural and Functional Identity of the Protein Kinase Superfamily
description The human protein kinase superfamily consists of over 500 members that individually control specific aspects of cell behavior and collectively control the complete range of cellular processes. That such a large group of proteins is able to uniquely diversify and establish individual identities while retaining common enzymatic function and significant sequence/structural conservation is remarkable. The means by which this is achieved is poorly understood, and we have begun to examine the issue by performing a comparative analysis of the catalytic domain of protein kinases. A novel approach for protein structural alignment has revealed a high degree of similarity found across the kinase superfamily, with variability confined largely to a single region thought to be involved in substrate binding. The similarity detected is not limited to amino acids, but includes a group of conserved water molecules that play important structural roles in stabilizing critical residues and the fold of the kinase domain. The development of a novel technique for identifying kinase substrates on a large scale directly from cell lysate has revealed that substrate specificity is not what discriminates the closely related p38α and β mitogen-activated protein kinases. Instead cellular localization appears to be their distinguishing characteristic, at least during myoblast differentiation. Together these results highlight the extent of conservation, as well as the minimal variability, that is found in the catalytic domain of all protein kinase superfamily members, and that while distantly related kinases may be distinguished by substrate specificity, closely related kinases are likely to be distinguished by other factors. Although these results focus on representative members of the kinase superfamily, they give insight as to how all protein kinases likely diversified and established unique non-redundant identities. In addition, the novel techniques developed and presented here for structural alignment and substrate discovery offer new tools for studying molecular biology and cell signaling.
author Knight, James D R
author_facet Knight, James D R
author_sort Knight, James D R
title The Structural and Functional Identity of the Protein Kinase Superfamily
title_short The Structural and Functional Identity of the Protein Kinase Superfamily
title_full The Structural and Functional Identity of the Protein Kinase Superfamily
title_fullStr The Structural and Functional Identity of the Protein Kinase Superfamily
title_full_unstemmed The Structural and Functional Identity of the Protein Kinase Superfamily
title_sort structural and functional identity of the protein kinase superfamily
publishDate 2011
url http://hdl.handle.net/10393/20232
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