The causes and consequences of variation in evolutionary processes acting on DNA sequences

Bofkin, Lee Nathan Marc

January 2006

No description available.

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Genome assembly and comparison using de Bruijn graphs

Zerbino, Daniel Robert

January 2009

No description available.

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Applications of combinatorial pattern discovery in computational genomics

Darzentas, Nikos

January 2006

No description available.

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Transcriptional and post-transcriptional regulation of gene expression : computational analysis of microarray studies in fungal species

Lawler, Katherine Joanne

January 2010

No description available.

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Function and evolution of regulatory elements in vertebrates

Meynert, Alison Maria

January 2010

No description available.

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Automatic functional annotation of predicted active sites : combining PDB and literature mining

Nagel, Kevin

January 2010

No description available.

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A computational study of bacterial gene regulation and adaptation on a genomic scale

Seshasayee, Aswin Sai Narain

January 2009

No description available.

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Computational analysis of protein interactions and interfaces

Kim, Wan Kyu

January 2007

No description available.

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Novel algorithms for protein interaction networks

Lappe, Michael

January 2004

No description available.

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Role and application of ontology design patterns in bio-ontologies

Aranguren, Mikel Egaña

January 2009

Knowledge Representation (KR) languages such as OWL (Web Ontology Languge), having precise semantics, offer the possibility of computationally exploiting biological knowledge, by codifying it in the axioms of bio-ontologies widely used in life sciences for knowledge management. Knowledge is, however, often represented in bio-ontologies without following rigorous principles of modelling and the resulting bio-ontologies are axiomatically lean. Therefore knowledge cannot be computationally exploited for integrity checking, hypothesis generation, consistency maintenance, integration, or rich querying. A solution that can contribute to the rigorous modelling and axiomatic richness of bio-ontologies is is the use of Ontology Design Patterns (ODPs). ODPs are thoroughly documented and efficient solutions for recurrent problems encountered when building ontologies. Therefore ODPs act as guides on how to use KR languages for creating ontology fragments that have well known advantages and side effects. In order forr ODPs to be efficiently accessed by bio-ontologists, an online catalogue of ODPs has been created, describing different ODPs using a consisistent documentation schema. Such ODPs, apart from being accessed, can be applied automatatically with the Ontology Preprocessor Language (OPPL), as OPPL makes it possible to encapsulate ODPs in scripts to be executed on OWL ontologies, making the application of ODPs replicable and flexible. The infrastructure for applying ODPs formed by the catalogue amd OPPL has been used for applying ODPs in bio-ontologies like the Cell Type Ontology. The results of such application have been evaluated to assess the applied ODPs and the chang on ontology quality.

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