Your search keyword '"Pal L.R."' showing total 5 results

1. Tumor and blood B-cell abundance outperforms established immune checkpoint blockade response prediction signatures in head and neck cancer

Author

Chang, T.-G., Spathis, A., Schäffer, A.A., Gavrielatou, N., Kuo, F., Jia, D., Mukherjee, S., Sievers, C., Economopoulou, P., Anastasiou, M., Moutafi, M., Pal, L.R., Vos, J., Lee, A.S., Lam, S., Zhao, K., Jiang, P., Allen, C.T., Foukas, P., Gomatou, G., Altan-Bonnet, G., Morris, L.G.T., Psyrri, A., and Ruppin, E.

Published

2024

2. CAGI SickKids challenges: Assessment of phenotype and variant predictions derived from clinical and genomic data of children with undiagnosed diseases

Author

Zhiqiang Hu, Jesse M. Hunter, Olivier Lichtarge, Sean D. Mooney, Aashish N. Adhikari, Steven E. Brenner, Rita Casadio, Yizhou Yin, Lipika R. Pal, Uma Sunderam, Panagiotis Katsonis, Predrag Radivojac, Thomas Joseph, Giulia Babbi, Naveen Sivadasan, Constantina Bakolitsa, Vangala G. Saipradeep, Laura Kasak, John Moult, Julian Gough, M. Stephen Meyn, Pier Luigi Martelli, Jennifer Poitras, Rupa A Udani, Jan Zaucha, Rafael F. Guerrero, Yuxiang Jiang, Aditya Rao, Sujatha Kotte, Kunal Kundu, Kasak L., Hunter J.M., Udani R., Bakolitsa C., Hu Z., Adhikari A.N., Babbi G., Casadio R., Gough J., Guerrero R.F., Jiang Y., Joseph T., Katsonis P., Kotte S., Kundu K., Lichtarge O., Martelli P.L., Mooney S.D., Moult J., Pal L.R., Poitras J., Radivojac P., Rao A., Sivadasan N., Sunderam U., Saipradeep V.G., Yin Y., Zaucha J., Brenner S.E., and Meyn M.S.

Subjects

Male, Adolescent, In silico, Genomic data, Computational biology, Biology, Undiagnosed Diseases, Genome, Article, 03 medical and health sciences, Databases, Genetic, SickKid, pediatric rare disease, Genetics, Humans, Computer Simulation, Genetic Predisposition to Disease, Child, Gene, Genetics (clinical), 030304 developmental biology, Disease gene, 0303 health sciences, Whole Genome Sequencing, variant interpretation, 030305 genetics & heredity, Computational Biology, Genetic Variation, Pathogenicity, Phenotype, ddc, phenotype prediction, Child, Preschool, New disease, CAGI, Female, whole-genome sequencing data

Abstract

Whole-genome sequencing (WGS) holds great potential as a diagnostic test. However, the majority of patients currently undergoing WGS lack a molecular diagnosis, largely due to the vast number of undiscovered disease genes and our inability to assess the pathogenicity of most genomic variants. The CAGI SickKids challenges attempted to address this knowledge gap by assessing state-of-the-art methods for clinical phenotype prediction from genomes. CAGI4 and CAGI5 participants were provided with WGS data and clinical descriptions of 25 and 24 undiagnosed patients from the SickKids Genome Clinic Project, respectively. Predictors were asked to identify primary and secondary causal variants. In addition, for CAGI5, groups had to match each genome to one of three disorder categories (neurologic, ophthalmologic, and connective), and separately to each patient. The performance of matching genomes to categories was no better than random but two groups performed significantly better than chance in matching genomes to patients. Two of the ten variants proposed by two groups in CAGI4 were deemed to be diagnostic, and several proposed pathogenic variants in CAGI5 are good candidates for phenotype expansion. We discuss implications for improving in silico assessment of genomic variants and identifying new disease genes.

Published

2019

3. Assessing the performance of in-silico methods for predicting the pathogenicity of variants in the gene CHEK2, among Hispanic females with breast cancer

Author

Rita Casadio, Panagiotis Katsonis, Susan L. Neuhausen, Alin Voskanian, Predrag Radivojac, Yao Yu, Steven E. Brenner, Yue Cao, Yana Bromberg, Yuanfei Sun, Erin Young, Giulia Babbi, Elad Ziv, Castrense Savojardo, Maricel G. Kann, Max Miller, Yanran Wang, Olivier Lichtarge, Aditi Garg, Pier Luigi Martelli, Yang Shen, Emidio Capriotti, Debnath Pal, Gaia Andreoletti, Sean V. Tavtigian, Sean D. Mooney, Vikas Pejaver, Lipika R. Pal, Chad D. Huff, Voskanian A., Katsonis P., Lichtarge O., Pejaver V., Radivojac P., Mooney S.D., Capriotti E., Bromberg Y., Wang Y., Miller M., Martelli P.L., Savojardo C., Babbi G., Casadio R., Cao Y., Sun Y., Shen Y., Garg A., Pal D., Yu Y., Huff C.D., Tavtigian S.V., Young E., Neuhausen S.L., Ziv E., Pal L.R., Andreoletti G., Brenner S.E., and Kann M.G.

Subjects

Adult, In silico, Breast Neoplasms, Computational biology, Disease, Biology, Genome, Polymorphism, Single Nucleotide, Article, Odds, 03 medical and health sciences, breast cancer, Breast cancer, SNV, Exome Sequencing, Genetics, medicine, Humans, Computer Simulation, Genetic Predisposition to Disease, CHEK2, Genetics (clinical), 030304 developmental biology, Aged, 0303 health sciences, 030305 genetics & heredity, Computational Biology, Hispanic or Latino, Hispanic women, Middle Aged, medicine.disease, Precision medicine, United States, Checkpoint Kinase 2, Case-Control Studies, Linear Models, CAGI, Identification (biology), Female

Abstract

The availability of disease-specific genomic data is critical for developing new computational methods that predict the pathogenicity of human variants and advance the field of precision medicine. However, the lack of gold standards to properly train and benchmark such methods is one of the greatest challenges in the field. In response to this challenge, the scientific community is invited to participate in the Critical Assessment for Genome Interpretation (CAGI), where unpublished disease variants are available for classification by in silico methods. As part of the CAGI-5 challenge, we evaluated the performance of 18 submissions and three additional methods in predicting the pathogenicity of single nucleotide variants (SNVs) in checkpoint kinase 2 (CHEK2) for cases of breast cancer in Hispanic females. As part of the assessment, the efficacy of the analysis method and the setup of the challenge were also considered. The results indicated that though the challenge could benefit from additional participant data, the combined generalized linear model analysis and odds of pathogenicity analysis provided a framework to evaluate the methods submitted for SNV pathogenicity identification and for comparison to other available methods. The outcome of this challenge and the approaches used can help guide further advancements in identifying SNV-disease relationships.

Published

2019

4. Assessment of methods for predicting the effects of PTEN and TPMT protein variants

Author

Lukas Folkman, Kunal Kundu, Yaoqi Zhou, Rita Casadio, Olivier Lichtarge, Yana Bromberg, Giulia Babbi, Yizhou Yin, Lipika R. Pal, Panagiotis Katsonis, Castrense Savojardo, Predrag Radivojac, Maximilian Miller, John Moult, Pier Luigi Martelli, Vikas Pejaver, Pejaver V., Babbi G., Casadio R., Folkman L., Katsonis P., Kundu K., Lichtarge O., Martelli P.L., Miller M., Moult J., Pal L.R., Savojardo C., Yin Y., Zhou Y., Radivojac P., and Bromberg Y.

Subjects

Nonsynonymous substitution, VAMP-seq, Computational biology, Article, Stability change, 03 medical and health sciences, Genetics, PTEN, Humans, thiopurine S-methyl transferase, TPMT, Genetics (clinical), 030304 developmental biology, 0303 health sciences, Thiopurine methyltransferase, biology, Protein Stability, 030305 genetics & heredity, PTEN Phosphohydrolase, Computational Biology, High-Throughput Nucleotide Sequencing, Methyltransferases, variant stability profiling, Mutation, biology.protein, Molecular mechanism, CAGI, Critical assessment, Experimental methods, phosphatase and tensin homolog, PTEN

Abstract

Thermodynamic stability is a fundamental property shared by all proteins. Changes in stability due to mutation are a widespread molecular mechanism in genetic diseases. Methods for the prediction of mutation-induced stability change have typically been developed and evaluated on incomplete and/or biased data sets. As part of the Critical Assessment of Genome Interpretation (CAGI), we explored the utility of high-throughput variant stability profiling (VSP) assay data as an alternative for the assessment of computational methods and evaluated state-of-the-art predictors against over 7,000 non-synonymous variants from two proteins. We found that predictions were modestly correlated with actual experimental values. Predictors fared better when evaluated as classifiers of extreme stability effects. While different methods emerged as top-performers depending on the metric, it is non-trivial to draw conclusions on their adoption or improvement. Our analyses revealed that only 16% of all variants in VSP assays could be confidently defined as stability-affecting. Furthermore, it is unclear to what extent VSP abundance scores were reasonable proxies for the stability-related quantities that participating methods were designed to predict. Overall, our observations underscore the need for clearly defined objectives when developing and using both computational and experimental methods in the context of measuring variant impact.

Published

2019

5. Assessing computational predictions of the phenotypic effect of cystathionine-beta-synthase variants

Author

Ayodeji Olatubosun, Dago F Dimster-Denk, Zhiqiang Hu, Pier Luigi Martelli, Mauno Vihinen, Olivier Lichtarge, Frederic Rousseau, Iddo Friedberg, Castrense Savojardo, Sean D. Mooney, Emanuela Leonardi, Greet De Baets, Manuel Giollo, Jouni Väliaho, Yana Bromberg, Rachel Karchin, Chen Cao, Janita Thusberg, Changhua Yu, Susanna Repo, Rita Casadio, David L. Masica, Laura Kasak, Emidio Capriotti, Jasper Rine, Gaurav Pandey, Silvio C. E. Tosatto, John Moult, Lipika R. Pal, Steven E. Brenner, Predrag Radivojac, Panagiotis Katsonis, Joost Schymkowitz, Joost Van Durme, Constantina Bakolitsa, Kasak L., Bakolitsa C., Hu Z., Yu C., Rine J., Dimster-Denk D.F., Pandey G., De Baets G., Bromberg Y., Cao C., Capriotti E., Casadio R., Van Durme J., Giollo M., Karchin R., Katsonis P., Leonardi E., Lichtarge O., Martelli P.L., Masica D., Mooney S.D., Olatubosun A., Radivojac P., Rousseau F., Pal L.R., Savojardo C., Schymkowitz J., Thusberg J., Tosatto S.C.E., Vihinen M., Valiaho J., Repo S., Moult J., Brenner S.E., and Friedberg I.

Subjects

Homocysteine, IMPACT, ved/biology.organism_classification_rank.species, Transsulfuration pathway, chemistry.chemical_compound, 2.1 Biological and endogenous factors, Single amino acid, Aetiology, Precision Medicine, Genetics (clinical), Genetics & Heredity, PROTEIN FUNCTION, 0303 health sciences, biology, 030305 genetics & heredity, CAGI challenge, SNAP, Phenotype, machine learning, Networking and Information Technology R&D (NITRD), phenotype prediction, critical assessment, Life Sciences & Biomedicine, cystathionine-beta-synthase, ENZYME, Clinical Sciences, Cystathionine beta-Synthase, Homocystinuria, Computational biology, single amino acid substitution, CLASSIFICATION, Article, 03 medical and health sciences, Cystathionine, Genetics, medicine, Humans, Model organism, 030304 developmental biology, SERVER, TOOLS, Science & Technology, MUTATIONS, business.industry, ved/biology, Computational Biology, medicine.disease, Cystathionine beta synthase, Good Health and Well Being, chemistry, Amino Acid Substitution, biology.protein, Generic health relevance, Personalized medicine, business, PATHOGENICITY

Abstract

Accurate prediction of the impact of genomic variation on phenotype is a major goal of computational biology and an important contributor to personalized medicine. Computational predictions can lead to a better understanding of the mechanisms underlying genetic diseases, including cancer, but their adoption requires thorough and unbiased assessment. Cystathionine-beta-synthase (CBS) is an enzyme that catalyzes the first step of the transsulfuration pathway, from homocysteine to cystathionine, and in which variations are associated with human hyperhomocysteinemia and homocystinuria. We have created a computational challenge under the CAGI framework to evaluate how well different methods can predict the phenotypic effect(s) of CBS single amino acid substitutions using a blinded experimental data set. CAGI participants were asked to predict yeast growth based on the identity of the mutations. The performance of the methods was evaluated using several metrics. The CBS challenge highlighted the difficulty of predicting the phenotype of an ex vivo system in a model organism when classification models were trained on human disease data. We also discuss the variations in difficulty of prediction for known benign and deleterious variants, as well as identify methodological and experimental constraints with lessons to be learned for future challenges. ispartof: HUMAN MUTATION vol:40 issue:9 pages:1530-1545 ispartof: location:United States status: published

Published

2019