Your search keyword '"Gutteridge, Alex"' showing total 5 results

1. Effective Function Annotation through Catalytic Residue Conservation

Author

George, Richard A., Spriggs, Ruth V., Bartlett, Gail J., Gutteridge, Alex, MacArthur, Malcolm W., Porter, Craig T., Al-Lazikani, Bissan, Thornton, Janet M., and Swindells, Mark B.

Published

2005

2. Benchmarking network propagation methods for disease gene identification.

Author

Picart-Armada, Sergio, Barrett, Steven J., Willé, David R., Perera-Lluna, Alexandre, Gutteridge, Alex, and Dessailly, Benoit H.

Subjects

BIOLOGICAL networks, GENE regulatory networks, SEED treatment, PROTEIN-protein interactions, GENES, MACHINE learning

Abstract

In-silico identification of potential target genes for disease is an essential aspect of drug target discovery. Recent studies suggest that successful targets can be found through by leveraging genetic, genomic and protein interaction information. Here, we systematically tested the ability of 12 varied algorithms, based on network propagation, to identify genes that have been targeted by any drug, on gene-disease data from 22 common non-cancerous diseases in OpenTargets. We considered two biological networks, six performance metrics and compared two types of input gene-disease association scores. The impact of the design factors in performance was quantified through additive explanatory models. Standard cross-validation led to over-optimistic performance estimates due to the presence of protein complexes. In order to obtain realistic estimates, we introduced two novel protein complex-aware cross-validation schemes. When seeding biological networks with known drug targets, machine learning and diffusion-based methods found around 2-4 true targets within the top 20 suggestions. Seeding the networks with genes associated to disease by genetics decreased performance below 1 true hit on average. The use of a larger network, although noisier, improved overall performance. We conclude that diffusion-based prioritisers and machine learning applied to diffusion-based features are suited for drug discovery in practice and improve over simpler neighbour-voting methods. We also demonstrate the large impact of choosing an adequate validation strategy and the definition of seed disease genes. [ABSTRACT FROM AUTHOR]

Published

2019

3. Novel Pancreatic Endocrine Maturation Pathways Identified by Genomic Profiling and Causal Reasoning.

Author

Gutteridge, Alex, Rukstalis, J. Michael, Ziemek, Daniel, Tié, Mark, Ji, Lin, Ramos-Zayas, Rebeca, Nardone, Nancy A., Norquay, Lisa D., Brenner, Martin B., Tang, Kim, McNeish, John D., and Rowntree, Rebecca K.

Subjects

*EMBRYONIC stem cells, *ISLANDS of Langerhans, *MICRORNA, *GENE expression, *CELL differentiation, *PROGENITOR cells, *DEVELOPMENTAL biology

Abstract

We have used a previously unavailable model of pancreatic development, derived in vitro from human embryonic stem cells, to capture a time-course of gene, miRNA and histone modification levels in pancreatic endocrine cells. We investigated whether it is possible to better understand, and hence control, the biological pathways leading to pancreatic endocrine formation by analysing this information and combining it with the available scientific literature to generate models using a casual reasoning approach. We show that the embryonic stem cell differentiation protocol is highly reproducible in producing endocrine precursor cells and generates cells that recapitulate many aspects of human embryonic pancreas development, including maturation into functional endocrine cells when transplanted into recipient animals. The availability of whole genome gene and miRNA expression data from the early stages of human pancreatic development will be of great benefit to those in the fields of developmental biology and diabetes research. Our causal reasoning algorithm suggested the involvement of novel gene networks, such as NEUROG3/E2F1/KDM5B and SOCS3/STAT3/IL-6, in endocrine cell development We experimentally investigated the role of the top-ranked prediction by showing that addition of exogenous IL-6 could affect the expression of the endocrine progenitor genes NEUROG3 and NKX2.2. [ABSTRACT FROM AUTHOR]

Published

2013

4. Understanding nature's catalytic toolkit

Author

Gutteridge, Alex and Thornton, Janet M.

Subjects

*ENZYMES, *CATALYSTS, *ENZYME activation, *CATALYSIS, *GENOMICS

Abstract

Enzymes catalyse numerous reactions in nature, often causing spectacular accelerations in the catalysis rate. One aspect of understanding how enzymes achieve these feats is to explore how they use the limited set of residue side chains that form their ‘catalytic toolkit’. Combinations of different residues form ‘catalytic units’ that are found repeatedly in different unrelated enzymes. Most catalytic units facilitate rapid catalysis in the enzyme active site either by providing charged groups to polarize substrates and to stabilize transition states, or by modifying the pK a values of other residues to provide more effective acids and bases. Given recent efforts to design novel enzymes, the rise of structural genomics and subsequent efforts to predict the function of enzymes from their structure, these units provide a simple framework to describe how nature uses the tools at her disposal, and might help to improve techniques for designing and predicting enzyme function. [Copyright &y& Elsevier]

Published

2005

5. Using A Neural Network and Spatial Clustering to Predict the Location of Active Sites in Enzymes

Author

Gutteridge, Alex, Bartlett, Gail J., and Thornton, Janet M.

Subjects

*PROTEINS, *GENOMICS

Abstract

Structural genomics projects aim to provide a sharp increase in the number of structures of functionally unannotated, and largely unstudied, proteins. Algorithms and tools capable of deriving information about the nature, and location, of functional sites within a structure are increasingly useful therefore. Here, a neural network is trained to identify the catalytic residues found in enzymes, based on an analysis of the structure and sequence. The neural network output, and spatial clustering of the highly scoring residues are then used to predict the location of the active site.A comparison of the performance of differently trained neural networks is presented that shows how information from sequence and structure come together to improve the prediction accuracy of the network. Spatial clustering of the network results provides a reliable way of finding likely active sites. In over 69% of the test cases the active site is correctly predicted, and a further 25% are partially correctly predicted. The failures are generally due to the poor quality of the automatically generated sequence alignments.We also present predictions identifying the active site, and potential functional residues in five recently solved enzyme structures, not used in developing the method. The method correctly identifies the putative active site in each case. In most cases the likely functional residues are identified correctly, as well as some potentially novel functional groups. [Copyright &y& Elsevier]

Published

2003