2009
DOI: 10.1007/978-1-59745-427-8_11
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Functional Genomics and Structural Biology in the Definition of Gene Function

Abstract: By mid-2007, the three-dimensional (3D) structures of some 45,000 proteins have been solved, over a period where the linear structures of millions of genes have been defined. Technical challenges associated with X-ray crystallography are being overcome and high-throughput methods both for crystallization of proteins and for solving their 3D structures are under development. The question arises as to how structural biology can be integrated with and adds value to functional genomics programs. Structural biology… Show more

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Cited by 17 publications
(11 citation statements)
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“…Protein structure determines protein function [18,72,73]. Therefore, the 3D structure of a protein provides vital information as to how a protein functions [73].…”
Section: Molecular Structure Of Plant Hkt Transportersmentioning
confidence: 99%
See 1 more Smart Citation
“…Protein structure determines protein function [18,72,73]. Therefore, the 3D structure of a protein provides vital information as to how a protein functions [73].…”
Section: Molecular Structure Of Plant Hkt Transportersmentioning
confidence: 99%
“…In the absence of experimentally determined structure, it is possible to infer structural data from comparisons with known structures or from computational predictions, such as comparative (homology) modelling [16,72]. These methods are limited by the availability of appropriate templates.…”
Section: Molecular Structure Of Plant Hkt Transportersmentioning
confidence: 99%
“…So we need to constantly remind ourselves about this when attempting to bridge the gap! In the rest of the article, I will discuss the information that is potentially derivable from genome sequence alone in the foreseeable future, which will need to be integrated, when attempting to understand the whole picture, with information derivable based on other experimental data such as (a) microarray gene expression data [76][77] for inference of the transcription subsystem and associated regulatory subsystem in a cell, (b) tiling arrays [78][79] for identification of cis regulatory elements of operons, (c) ChIP on chip data [80] for identification of interaction partners between transcription regulators and their cis regulatory elements, (d) proteomic data measuring the presence and the quantities of proteins under specific conditions typically collected using mass spectrometry techniques [81][82] , (e) metabolomic data measuring the metabolites as the results of metabolic reactions and their quantities using mass spectrometry or nuclear magnetic resonance (NMR) techniques [83][84] , (f) protein interaction data generated using techniques like yeast two-hybrid arrays [85] or pull-down approaches [86][87] , (g) protein and complex structures generated using X-ray crystallography [88][89] , NMR or electronic cryo-microscopy techniques [90][91] , which can provide detailed information such as how a protein executes a particular reaction, and (h) imaging data for tracing the movements of bio-molecules inside a cell, as well as information derived through systems level modeling and simulational studies as outlined earlier.…”
Section: Information Potentially Derivable That Can Help To Bridge Thmentioning
confidence: 99%
“…Currently, the functions of about 50% of genes on plant genomes can be predicted from sequence similarities with proteins from other organisms. However, the evidence for function is usually circumstantial or inferred from a third source and in most cases direct biochemical evidence for function is not available (Hrmova & Fincher 2009 ). In many cases the identities of the genes and their annotated function are simply incorrect (Brown & Sj ö lander 2006 ).…”
Section: Biochemistry and The D Efi Nition Of G Ene F Unctionmentioning
confidence: 99%