Ilhem Diboun scite author profile

Transient interactions, which involve protein interactions that are formed and broken easily, are important in many aspects of cellular function. Here we describe structural and functional properties of transient interactions between globular domains and between globular domains, short peptides, and disordered regions. The importance of posttranslational modifications in transient interactions is also considered. We review techniques used in the detection of the different types of transient protein-protein interactions. We also look at the role of transient interactions within protein-protein interaction networks and consider their contribution to different aspects of these networks.

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Microarray analysis after RNA amplification can detect pronounced differences in gene expression using limma

Diboun

et al. 2006

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Background: RNA amplification is necessary for profiling gene expression from small tissue samples. Previous studies have shown that the T7 based amplification techniques are reproducible but may distort the true abundance of targets. However, the consequences of such distortions on the ability to detect biological variation in expression have not been explored sufficiently to define the true extent of usability and limitations of such amplification techniques.

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The CATH Domain Structure Database and related resources Gene3D and DHS provide comprehensive domain family information for genome analysis

Pearl

Todd²,

Sillitoe³

et al. 2004

Nucleic Acids Research

237

168

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The CATH database of protein domain structures (http://www.biochem.ucl.ac.uk/bsm/cath/) currently contains 43 229 domains classified into 1467 superfamilies and 5107 sequence families. Each structural family is expanded with sequence relatives from GenBank and completed genomes, using a variety of efficient sequence search protocols and reliable thresholds. This extended CATH protein family database contains 616 470 domain sequences classified into 23 876 sequence families. This results in the significant expansion of the CATH HMM model library to include models built from the CATH sequence relatives, giving a 10% increase in coverage for detecting remote homologues. An improved Dictionary of Homologous superfamilies (DHS) (http://www.biochem.ucl.ac.uk/bsm/dhs/) containing specific sequence, structural and functional information for each superfamily in CATH considerably assists manual validation of homologues. Information on sequence relatives in CATH superfamilies, GenBank and completed genomes is presented in the CATH associated DHS and Gene3D resources. Domain partnership information can be obtained from Gene3D (http://www.biochem.ucl.ac.uk/bsm/cath/Gene3D/). A new CATH server has been implemented (http://www.biochem.ucl.ac.uk/cgi-bin/cath/CathServer.pl) providing automatic classification of newly determined sequences and structures using a suite of rapid sequence and structure comparison methods. The statistical significance of matches is assessed and links are provided to the putative superfamily or fold group to which the query sequence or structure is assigned.

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PainNetworks: A web-based resource for the visualisation of pain-related genes in the context of their network associations

Perkins

Lees

Antunes-Martins

et al. 2013

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Hundreds of genes are proposed to contribute to nociception and pain perception. Historically, most studies of pain-related genes have examined them in isolation or alongside a handful of other genes. More recently the use of systems biology techniques has enabled us to study genes in the context of the biological pathways and networks in which they operate.Here we describe a Web-based resource, available at http://www.PainNetworks.org. It integrates interaction data from various public databases with information on known pain genes taken from several sources (eg, The Pain Genes Database) and allows the user to examine a gene (or set of genes) of interest alongside known interaction partners. This information is displayed by the resource in the form of a network.The user can enrich these networks by using data from pain-focused gene expression studies to highlight genes that change expression in a given experiment or pairs of genes showing correlated expression patterns across different experiments. Genes in the networks are annotated in several ways including biological function and drug binding.The Web site can be used to find out more about a gene of interest by looking at the function of its interaction partners. It can also be used to interpret the results of a functional genomics experiment by revealing putative novel pain-related genes that have similar expression patterns to known pain-related genes and by ranking genes according to their network connections with known pain genes.We expect this resource to grow over time and become a valuable asset to the pain community.

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CATHerine wheels () illustrating the distribution of domain structures from the PDB among the different levels in the CATH hierarchy

Frances¹,

Annabel²,

Sillitoe³

et al. 2011

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The proportion (%) of structures from the PDB that have been classified in CATH over the last two years using different sequence comparison or structure comparison methods

Frances¹,

Annabel²,

Sillitoe³

et al. 2011

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Ilhem Diboun

Transient Protein-Protein Interactions: Structural, Functional, and Network Properties

Microarray analysis after RNA amplification can detect pronounced differences in gene expression using limma

The CATH Domain Structure Database and related resources Gene3D and DHS provide comprehensive domain family information for genome analysis

PainNetworks: A web-based resource for the visualisation of pain-related genes in the context of their network associations

CATHerine wheels () illustrating the distribution of domain structures from the PDB among the different levels in the CATH hierarchy

The proportion (%) of structures from the PDB that have been classified in CATH over the last two years using different sequence comparison or structure comparison methods

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