Using the gene ontology to enrich biological pathways

Antonio Sanfilippo; Bob Baddeley; Nathaniel Beagley; Jason McDermott; Roderick Riensche; Ronald Taylor; Banu Gopalan

doi:10.1504/IJCBDD.2009.030114

Using the gene ontology to enrich biological pathways

Antonio Sanfilippo^*, Bob Baddeley, Nathaniel Beagley, Jason McDermott, Roderick Riensche, Ronald Taylor, Banu Gopalan

^*Corresponding author for this work

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

10 Citations (Scopus)

Abstract

Most current approaches to automatic pathway generation are based on a reverse engineering approach in which pathway plausibility is solely derived from gene expression data and not independently validated. Alternative approaches use prior biological knowledge to validate automatically inferred pathways, but the prior knowledge is usually not sufficiently tuned to the pathology of focus. We present a novel pathway generation approach that combines insights from the reverse engineering and knowledge-based approaches to increase the biological plausibility of automatically generated regulatory networks and describe an application of this approach to transcriptional data from a mouse model of neuroprotection during stroke.

Original language	English
Pages (from-to)	221-235
Number of pages	15
Journal	International Journal of Computational Biology and Drug Design
Volume	2
Issue number	3
DOIs	https://doi.org/10.1504/IJCBDD.2009.030114
Publication status	Published - Dec 2009
Externally published	Yes

Keywords

Automatic pathway generation
Biological pathways
GO
Gene ontology
Gene similarity
Neuroprotection
Stroke

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10.1504/IJCBDD.2009.030114

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title = "Using the gene ontology to enrich biological pathways",

abstract = "Most current approaches to automatic pathway generation are based on a reverse engineering approach in which pathway plausibility is solely derived from gene expression data and not independently validated. Alternative approaches use prior biological knowledge to validate automatically inferred pathways, but the prior knowledge is usually not sufficiently tuned to the pathology of focus. We present a novel pathway generation approach that combines insights from the reverse engineering and knowledge-based approaches to increase the biological plausibility of automatically generated regulatory networks and describe an application of this approach to transcriptional data from a mouse model of neuroprotection during stroke.",

keywords = "Automatic pathway generation, Biological pathways, GO, Gene ontology, Gene similarity, Neuroprotection, Stroke",

author = "Antonio Sanfilippo and Bob Baddeley and Nathaniel Beagley and Jason McDermott and Roderick Riensche and Ronald Taylor and Banu Gopalan",

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T1 - Using the gene ontology to enrich biological pathways

AU - Sanfilippo, Antonio

AU - Baddeley, Bob

AU - Beagley, Nathaniel

AU - McDermott, Jason

AU - Riensche, Roderick

AU - Taylor, Ronald

AU - Gopalan, Banu

PY - 2009/12

Y1 - 2009/12

N2 - Most current approaches to automatic pathway generation are based on a reverse engineering approach in which pathway plausibility is solely derived from gene expression data and not independently validated. Alternative approaches use prior biological knowledge to validate automatically inferred pathways, but the prior knowledge is usually not sufficiently tuned to the pathology of focus. We present a novel pathway generation approach that combines insights from the reverse engineering and knowledge-based approaches to increase the biological plausibility of automatically generated regulatory networks and describe an application of this approach to transcriptional data from a mouse model of neuroprotection during stroke.

AB - Most current approaches to automatic pathway generation are based on a reverse engineering approach in which pathway plausibility is solely derived from gene expression data and not independently validated. Alternative approaches use prior biological knowledge to validate automatically inferred pathways, but the prior knowledge is usually not sufficiently tuned to the pathology of focus. We present a novel pathway generation approach that combines insights from the reverse engineering and knowledge-based approaches to increase the biological plausibility of automatically generated regulatory networks and describe an application of this approach to transcriptional data from a mouse model of neuroprotection during stroke.

KW - Automatic pathway generation

KW - Biological pathways

KW - GO

KW - Gene ontology

KW - Gene similarity

KW - Neuroprotection

KW - Stroke

UR - https://www.scopus.com/pages/publications/77953665625

U2 - 10.1504/IJCBDD.2009.030114

DO - 10.1504/IJCBDD.2009.030114

M3 - Review article

C2 - 20090161

AN - SCOPUS:77953665625

SN - 1756-0756

VL - 2

SP - 221

EP - 235

JO - International Journal of Computational Biology and Drug Design

JF - International Journal of Computational Biology and Drug Design

IS - 3

ER -

Using the gene ontology to enrich biological pathways

Abstract

Keywords

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