Your search keyword '"Cilia, E."' showing total 3 results

1. Predicting virus mutations through statistical relational learning.

Author

Cilia E, Teso S, Ammendola S, Lenaerts T, and Passerini A

Subjects

Amino Acid Sequence, Artificial Intelligence, HIV drug effects, HIV enzymology, HIV Infections drug therapy, HIV Reverse Transcriptase chemistry, HIV Reverse Transcriptase metabolism, Humans, Models, Biological, Models, Statistical, Molecular Sequence Data, Nucleosides chemistry, Nucleosides pharmacology, Reverse Transcriptase Inhibitors chemistry, Algorithms, Drug Resistance, Viral, HIV genetics, HIV Infections virology, Models, Genetic, Mutation, Reverse Transcriptase Inhibitors pharmacology

Abstract

Background: Viruses are typically characterized by high mutation rates, which allow them to quickly develop drug-resistant mutations. Mining relevant rules from mutation data can be extremely useful to understand the virus adaptation mechanism and to design drugs that effectively counter potentially resistant mutants., Results: We propose a simple statistical relational learning approach for mutant prediction where the input consists of mutation data with drug-resistance information, either as sets of mutations conferring resistance to a certain drug, or as sets of mutants with information on their susceptibility to the drug. The algorithm learns a set of relational rules characterizing drug-resistance and uses them to generate a set of potentially resistant mutants. Learning a weighted combination of rules allows to attach generated mutants with a resistance score as predicted by the statistical relational model and select only the highest scoring ones., Conclusions: Promising results were obtained in generating resistant mutations for both nucleoside and non-nucleoside HIV reverse transcriptase inhibitors. The approach can be generalized quite easily to learning mutants characterized by more complex rules correlating multiple mutations.

Published

2014

2. Argot2: a large scale function prediction tool relying on semantic similarity of weighted Gene Ontology terms.

Author

Falda M, Toppo S, Pescarolo A, Lavezzo E, Di Camillo B, Facchinetti A, Cilia E, Velasco R, and Fontana P

Subjects

Databases, Genetic, Genome, Plant, High-Throughput Nucleotide Sequencing, Markov Chains, Proteins genetics, Semantics, Vocabulary, Controlled, Algorithms, Malus genetics, Molecular Sequence Annotation methods, Vitis genetics

Abstract

Background: Predicting protein function has become increasingly demanding in the era of next generation sequencing technology. The task to assign a curator-reviewed function to every single sequence is impracticable. Bioinformatics tools, easy to use and able to provide automatic and reliable annotations at a genomic scale, are necessary and urgent. In this scenario, the Gene Ontology has provided the means to standardize the annotation classification with a structured vocabulary which can be easily exploited by computational methods., Results: Argot2 is a web-based function prediction tool able to annotate nucleic or protein sequences from small datasets up to entire genomes. It accepts as input a list of sequences in FASTA format, which are processed using BLAST and HMMER searches vs UniProKB and Pfam databases respectively; these sequences are then annotated with GO terms retrieved from the UniProtKB-GOA database and the terms are weighted using the e-values from BLAST and HMMER. The weighted GO terms are processed according to both their semantic similarity relations described by the Gene Ontology and their associated score. The algorithm is based on the original idea developed in a previous tool called Argot. The entire engine has been completely rewritten to improve both accuracy and computational efficiency, thus allowing for the annotation of complete genomes., Conclusions: The revised algorithm has been already employed and successfully tested during in-house genome projects of grape and apple, and has proven to have a high precision and recall in all our benchmark conditions. It has also been successfully compared with Blast2GO, one of the methods most commonly employed for sequence annotation. The server is freely accessible at http://www.medcomp.medicina.unipd.it/Argot2.

Published

2012

3. Automatic prediction of catalytic residues by modeling residue structural neighborhood.

Author

Cilia E and Passerini A

Subjects

Catalysis, Databases, Protein, Models, Theoretical, Protein Folding, Catalytic Domain, Protein Conformation, Proteins chemistry

Abstract

Background: Prediction of catalytic residues is a major step in characterizing the function of enzymes. In its simpler formulation, the problem can be cast into a binary classification task at the residue level, by predicting whether the residue is directly involved in the catalytic process. The task is quite hard also when structural information is available, due to the rather wide range of roles a functional residue can play and to the large imbalance between the number of catalytic and non-catalytic residues., Results: We developed an effective representation of structural information by modeling spherical regions around candidate residues, and extracting statistics on the properties of their content such as physico-chemical properties, atomic density, flexibility, presence of water molecules. We trained an SVM classifier combining our features with sequence-based information and previously developed 3D features, and compared its performance with the most recent state-of-the-art approaches on different benchmark datasets. We further analyzed the discriminant power of the information provided by the presence of heterogens in the residue neighborhood., Conclusions: Our structure-based method achieves consistent improvements on all tested datasets over both sequence-based and structure-based state-of-the-art approaches. Structural neighborhood information is shown to be responsible for such results, and predicting the presence of nearby heterogens seems to be a promising direction for further improvements.

Published

2010