Your search keyword '"Pal, Lipika R."' showing total 16 results

1. Genome‐scale metabolic modeling reveals SARS‐CoV‐2‐induced metabolic changes and antiviral targets.

Author

Cheng, Kuoyuan, Martin‐Sancho, Laura, Pal, Lipika R, Pu, Yuan, Riva, Laura, Yin, Xin, Sinha, Sanju, Nair, Nishanth Ulhas, Chanda, Sumit K, and Ruppin, Eytan

Subjects

METABOLIC models, SARS-CoV-2, COVID-19 pandemic, DRUG repositioning, COVID-19, GENETIC testing, VIRAL genetics

Abstract

Tremendous progress has been made to control the COVID‐19 pandemic caused by the SARS‐CoV‐2 virus. However, effective therapeutic options are still rare. Drug repurposing and combination represent practical strategies to address this urgent unmet medical need. Viruses, including coronaviruses, are known to hijack host metabolism to facilitate viral proliferation, making targeting host metabolism a promising antiviral approach. Here, we describe an integrated analysis of 12 published in vitro and human patient gene expression datasets on SARS‐CoV‐2 infection using genome‐scale metabolic modeling (GEM), revealing complicated host metabolism reprogramming during SARS‐CoV‐2 infection. We next applied the GEM‐based metabolic transformation algorithm to predict anti‐SARS‐CoV‐2 targets that counteract the virus‐induced metabolic changes. We successfully validated these targets using published drug and genetic screen data and by performing an siRNA assay in Caco‐2 cells. Further generating and analyzing RNA‐sequencing data of remdesivir‐treated Vero E6 cell samples, we predicted metabolic targets acting in combination with remdesivir, an approved anti‐SARS‐CoV‐2 drug. Our study provides clinical data‐supported candidate anti‐SARS‐CoV‐2 targets for future evaluation, demonstrating host metabolism targeting as a promising antiviral strategy. SYNOPSIS: Metabolic modeling of 12 SARS‐CoV‐2 datasets identifies novel single or combinatory antiviral targets by reverting the virus‐induced host metabolic reprogramming. Meta‐analysis of SARS‐CoV‐2‐induced expression changes reveals extensive host metabolic alterations.rMTA algorithm predicted 81 single metabolic targets and 87 targets for combination with remdesivir for anti‐SARS‐CoV‐2.Selected candidate single targets were successfully validated with an immunofluorescence‐based siRNA assay in Caco‐2 cells. [ABSTRACT FROM AUTHOR]

Published

2021

2. Matching whole genomes to rare genetic disorders: Identification of potential causative variants using phenotype‐weighted knowledge in the CAGI SickKids5 clinical genomes challenge.

Author

Pal, Lipika R., Kundu, Kunal, Yin, Yizhou, and Moult, John

Abstract

Precise identification of causative variants from whole‐genome sequencing data, including both coding and noncoding variants, is challenging. The Critical Assessment of Genome Interpretation 5 SickKids clinical genome challenge provided an opportunity to assess our ability to extract such information. Participants in the challenge were required to match each of the 24 whole‐genome sequences to the correct phenotypic profile and to identify the disease class of each genome. These are all rare disease cases that have resisted genetic diagnosis in a state‐of‐the‐art pipeline. The patients have a range of eye, neurological, and connective‐tissue disorders. We used a gene‐centric approach to address this problem, assigning each gene a multiphenotype‐matching score. Mutations in the top‐scoring genes for each phenotype profile were ranked on a 6‐point scale of pathogenicity probability, resulting in an approximately equal number of top‐ranked coding and noncoding candidate variants overall. We were able to assign the correct disease class for 12 cases and the correct genome to a clinical profile for five cases. The challenge assessor found genes in three of these five cases as likely appropriate. In the postsubmission phase, after careful screening of the genes in the correct genome, we identified additional potential diagnostic variants, a high proportion of which are noncoding. [ABSTRACT FROM AUTHOR]

Published

2020

3. Reports from the fifth edition of CAGI: The Critical Assessment of Genome Interpretation.

Author

Andreoletti, Gaia, Pal, Lipika R., Moult, John, and Brenner, Steven E.

Abstract

Interpretation of genomic variation plays an essential role in the analysis of cancer and monogenic disease, and increasingly also in complex trait disease, with applications ranging from basic research to clinical decisions. Many computational impact prediction methods have been developed, yet the field lacks a clear consensus on their appropriate use and interpretation. The Critical Assessment of Genome Interpretation (CAGI, /'kā‐jē/) is a community experiment to objectively assess computational methods for predicting the phenotypic impacts of genomic variation. CAGI participants are provided genetic variants and make blind predictions of resulting phenotype. Independent assessors evaluate the predictions by comparing with experimental and clinical data. CAGI has completed five editions with the goals of establishing the state of art in genome interpretation and of encouraging new methodological developments. This special issue (https://onlinelibrary.wiley.com/toc/10981004/2019/40/9) comprises reports from CAGI, focusing on the fifth edition that culminated in a conference that took place 5 to 7 July 2018. CAGI5 was comprised of 14 challenges and engaged hundreds of participants from a dozen countries. This edition had a notable increase in splicing and expression regulatory variant challenges, while also continuing challenges on clinical genomics, as well as complex disease datasets and missense variants in diseases ranging from cancer to Pompe disease to schizophrenia. Full information about CAGI is at https://genomeinterpretation.org. [ABSTRACT FROM AUTHOR]

Published

2019

4. Assessment of predicted enzymatic activity of α‐N‐acetylglucosaminidase variants of unknown significance for CAGI 2016.

Author

Clark, Wyatt T., Kasak, Laura, Bakolitsa, Constantina, Hu, Zhiqiang, Andreoletti, Gaia, Babbi, Giulia, Bromberg, Yana, Casadio, Rita, Dunbrack, Roland, Folkman, Lukas, Ford, Colby T., Jones, David, Katsonis, Panagiotis, Kundu, Kunal, Lichtarge, Olivier, Martelli, Pier L., Mooney, Sean D., Nodzak, Conor, Pal, Lipika R., and Radivojac, Predrag

Abstract

The NAGLU challenge of the fourth edition of the Critical Assessment of Genome Interpretation experiment (CAGI4) in 2016, invited participants to predict the impact of variants of unknown significance (VUS) on the enzymatic activity of the lysosomal hydrolase α‐N‐acetylglucosaminidase (NAGLU). Deficiencies in NAGLU activity lead to a rare, monogenic, recessive lysosomal storage disorder, Sanfilippo syndrome type B (MPS type IIIB). This challenge attracted 17 submissions from 10 groups. We observed that top models were able to predict the impact of missense mutations on enzymatic activity with Pearson's correlation coefficients of up to.61. We also observed that top methods were significantly more correlated with each other than they were with observed enzymatic activity values, which we believe speaks to the importance of sequence conservation across the different methods. Improved functional predictions on the VUS will help population‐scale analysis of disease epidemiology and rare variant association analysis. [ABSTRACT FROM AUTHOR]

Published

2019

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

Author

Kasak, Laura, Hunter, Jesse M., Udani, Rupa, Bakolitsa, Constantina, Hu, Zhiqiang, Adhikari, Aashish N., Babbi, Giulia, Casadio, Rita, Gough, Julian, Guerrero, Rafael F., Jiang, Yuxiang, Joseph, Thomas, Katsonis, Panagiotis, Kotte, Sujatha, Kundu, Kunal, Lichtarge, Olivier, Martelli, Pier Luigi, Mooney, Sean D., Moult, John, and Pal, Lipika R.

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. [ABSTRACT FROM AUTHOR]

Published

2019

6. Assessment of patient clinical descriptions and pathogenic variants from gene panel sequences in the CAGI‐5 intellectual disability challenge.

Author

Carraro, Marco, Monzon, Alexander Miguel, Chiricosta, Luigi, Reggiani, Francesco, Aspromonte, Maria Cristina, Bellini, Mariagrazia, Pagel, Kymberleigh, Jiang, Yuxiang, Radivojac, Predrag, Kundu, Kunal, Pal, Lipika R., Yin, Yizhou, Limongelli, Ivan, Andreoletti, Gaia, Moult, John, Wilson, Stephen J., Katsonis, Panagiotis, Lichtarge, Olivier, Chen, Jingqi, and Wang, Yaqiong

Abstract

The Critical Assessment of Genome Interpretation‐5 intellectual disability challenge asked to use computational methods to predict patient clinical phenotypes and the causal variant(s) based on an analysis of their gene panel sequence data. Sequence data for 74 genes associated with intellectual disability (ID) and/or autism spectrum disorders (ASD) from a cohort of 150 patients with a range of neurodevelopmental manifestations (i.e. ID, autism, epilepsy, microcephaly, macrocephaly, hypotonia, ataxia) have been made available for this challenge. For each patient, predictors had to report the causative variants and which of the seven phenotypes were present. Since neurodevelopmental disorders are characterized by strong comorbidity, tested individuals often present more than one pathological condition. Considering the overall clinical manifestation of each patient, the correct phenotype has been predicted by at least one group for 93 individuals (62%). ID and ASD were the best predicted among the seven phenotypic traits. Also, causative or potentially pathogenic variants were predicted correctly by at least one group. However, the prediction of the correct causative variant seems to be insufficient to predict the correct phenotype. In some cases, the correct prediction has been supported by rare or common variants in genes different from the causative one. [ABSTRACT FROM AUTHOR]

Published

2019

7. Predicting venous thromboembolism risk from exomes in the Critical Assessment of Genome Interpretation (CAGI) challenges.

Author

McInnes, Gregory, Daneshjou, Roxana, Katsonis, Panagiostis, Lichtarge, Olivier, Srinivasan, Rajgopal, Rana, Sadhna, Radivojac, Predrag, Mooney, Sean D., Pagel, Kymberleigh A., Stamboulian, Moses, Jiang, Yuxiang, Capriotti, Emidio, Wang, Yanran, Bromberg, Yana, Bovo, Samuele, Savojardo, Castrense, Martelli, Pier Luigi, Casadio, Rita, Pal, Lipika R., and Moult, John

Abstract

Genetics play a key role in venous thromboembolism (VTE) risk, however established risk factors in European populations do not translate to individuals of African descent because of the differences in allele frequencies between populations. As part of the fifth iteration of the Critical Assessment of Genome Interpretation, participants were asked to predict VTE status in exome data from African American subjects. Participants were provided with 103 unlabeled exomes from patients treated with warfarin for non‐VTE causes or VTE and asked to predict which disease each subject had been treated for. Given the lack of training data, many participants opted to use unsupervised machine learning methods, clustering the exomes by variation in genes known to be associated with VTE. The best performing method using only VTE related genes achieved an area under the ROC curve of 0.65. Here, we discuss the range of methods used in the prediction of VTE from sequence data and explore some of the difficulties of conducting a challenge with known confounders. In addition, we show that an existing genetic risk score for VTE that was developed in European subjects works well in African Americans. [ABSTRACT FROM AUTHOR]

Published

2019

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

Author

Pejaver, Vikas, Babbi, Giulia, Casadio, Rita, Folkman, Lukas, Katsonis, Panagiotis, Kundu, Kunal, Lichtarge, Olivier, Martelli, Pier Luigi, Miller, Maximilian, Moult, John, Pal, Lipika R., Savojardo, Castrense, Yin, Yizhou, Zhou, Yaoqi, Radivojac, Predrag, and Bromberg, Yana

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, 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 nonsynonymous 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 emerging as top performers depending on the metric, it is nontrivial 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 as 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. [ABSTRACT FROM AUTHOR]

Published

2019

9. Performance of in silico tools for the evaluation of p16INK4a (CDKN2A) variants in CAGI.

Author

Carraro, Marco, Minervini, Giovanni, Giollo, Manuel, Bromberg, Yana, Capriotti, Emidio, Casadio, Rita, Dunbrack, Roland, Elefanti, Lisa, Fariselli, Pietro, Ferrari, Carlo, Gough, Julian, Katsonis, Panagiotis, Leonardi, Emanuela, Lichtarge, Olivier, Menin, Chiara, Martelli, Pier Luigi, Niroula, Abhishek, Pal, Lipika R., Repo, Susanna, and Scaini, Maria Chiara

Abstract

Correct phenotypic interpretation of variants of unknown significance for cancer-associated genes is a diagnostic challenge as genetic screenings gain in popularity in the next-generation sequencing era. The Critical Assessment of Genome Interpretation (CAGI) experiment aims to test and define the state of the art of genotype-phenotype interpretation. Here, we present the assessment of the CAGI p16INK4a challenge. Participants were asked to predict the effect on cellular proliferation of 10 variants for the p16INK4a tumor suppressor, a cyclin-dependent kinase inhibitor encoded by the CDKN2A gene. Twenty-two pathogenicity predictors were assessed with a variety of accuracy measures for reliability in a medical context. Different assessment measures were combined in an overall ranking to provide more robust results. The R scripts used for assessment are publicly available from a GitHub repository for future use in similar assessment exercises. Despite a limited test-set size, our findings show a variety of results, with some methods performing significantly better. Methods combining different strategies frequently outperform simpler approaches. The best predictor, Yang&Zhou lab, uses a machine learning method combining an empirical energy function measuring protein stability with an evolutionary conservation term. The p16INK4a challenge highlights how subtle structural effects can neutralize otherwise deleterious variants. [ABSTRACT FROM AUTHOR]

Published

2017

10. Ensemble variant interpretation methods to predict enzyme activity and assign pathogenicity in the CAGI4 NAGLU (Human N-acetyl-glucosaminidase) and UBE2I (Human SUMO-ligase) challenges.

Author

Yin, Yizhou, Kundu, Kunal, Pal, Lipika R., and Moult, John

Abstract

CAGI (Critical Assessment of Genome Interpretation) conducts community experiments to determine the state of the art in relating genotype to phenotype. Here, we report results obtained using newly developed ensemble methods to address two CAGI4 challenges: enzyme activity for population missense variants found in NAGLU (Human N-acetyl-glucosaminidase) and random missense mutations in Human UBE2I (Human SUMO E2 ligase), assayed in a high-throughput competitive yeast complementation procedure. The ensemble methods are effective, ranked second for SUMO-ligase and third for NAGLU, according to the CAGI independent assessors. However, in common with other methods used in CAGI, there are large discrepancies between predicted and experimental activities for a subset of variants. Analysis of the structural context provides some insight into these. Post-challenge analysis shows that the ensemble methods are also effective at assigning pathogenicity for the NAGLU variants. In the clinic, providing an estimate of the reliability of pathogenic assignments is the key. We have also used the NAGLU dataset to show that ensemble methods have considerable potential for this task, and are already reliable enough for use with a subset of mutations. [ABSTRACT FROM AUTHOR]

Published

2017

11. Working toward precision medicine: Predicting phenotypes from exomes in the Critical Assessment of Genome Interpretation (CAGI) challenges.

Author

Daneshjou, Roxana, Wang, Yanran, Bromberg, Yana, Bovo, Samuele, Martelli, Pier L, Babbi, Giulia, Lena, Pietro Di, Casadio, Rita, Edwards, Matthew, Gifford, David, Jones, David T, Sundaram, Laksshman, Bhat, Rajendra Rana, Li, Xiaolin, Pal, Lipika R., Kundu, Kunal, Yin, Yizhou, Moult, John, Jiang, Yuxiang, and Pejaver, Vikas

Abstract

Precision medicine aims to predict a patient's disease risk and best therapeutic options by using that individual's genetic sequencing data. The Critical Assessment of Genome Interpretation (CAGI) is a community experiment consisting of genotype-phenotype prediction challenges; participants build models, undergo assessment, and share key findings. For CAGI 4, three challenges involved using exome-sequencing data: Crohn's disease, bipolar disorder, and warfarin dosing. Previous CAGI challenges included prior versions of the Crohn's disease challenge. Here, we discuss the range of techniques used for phenotype prediction as well as the methods used for assessing predictive models. Additionally, we outline some of the difficulties associated with making predictions and evaluating them. The lessons learned from the exome challenges can be applied to both research and clinical efforts to improve phenotype prediction from genotype. In addition, these challenges serve as a vehicle for sharing clinical and research exome data in a secure manner with scientists who have a broad range of expertise, contributing to a collaborative effort to advance our understanding of genotype-phenotype relationships. [ABSTRACT FROM AUTHOR]

Published

2017

12. CAGI4 Crohn's exome challenge: Marker SNP versus exome variant models for assigning risk of Crohn disease.

Author

Pal, Lipika R., Kundu, Kunal, Yin, Yizhou, and Moult, John

Abstract

Understanding the basis of complex trait disease is a fundamental problem in human genetics. The CAGI Crohn's Exome challenges are providing insight into the adequacy of current disease models by requiring participants to identify which of a set of individuals has been diagnosed with the disease, given exome data. For the CAGI4 round, we developed a method that used the genotypes from exome sequencing data only to impute the status of genome wide association studies marker SNPs. We then used the imputed genotypes as input to several machine learning methods that had been trained to predict disease status from marker SNP information. We achieved the best performance using Naïve Bayes and with a consensus machine learning method, obtaining an area under the curve of 0.72, larger than other methods used in CAGI4. We also developed a model that incorporated the contribution from rare missense variants in the exome data, but this performed less well. Future progress is expected to come from the use of whole genome data rather than exomes. [ABSTRACT FROM AUTHOR]

Published

2017

13. CAGI4 SickKids clinical genomes challenge: A pipeline for identifying pathogenic variants.

Author

Pal, Lipika R., Kundu, Kunal, Yin, Yizhou, and Moult, John

Abstract

Compared with earlier more restricted sequencing technologies, identification of rare disease variants using whole-genome sequence has the possibility of finding all causative variants, but issues of data quality and an overwhelming level of background variants complicate the analysis. The CAGI4 SickKids clinical genome challenge provided an opportunity to assess the landscape of variants found in a difficult set of 25 unsolved rare disease cases. To address the challenge, we developed a three-stage pipeline, first carefully analyzing data quality, then classifying high-quality gene-specific variants into seven categories, and finally examining each candidate variant for compatibility with the often complex phenotypes of these patients for final prioritization. Variants consistent with the phenotypes were found in 24 out of the 25 cases, and in a number of these, there are prioritized variants in multiple genes. Data quality analysis suggests that some of the selected variants are likely incorrect calls, complicating interpretation. The data providers followed up on three suggested variants with Sanger sequencing, and in one case, a prioritized variant was confirmed as likely causative by the referring physician, providing a diagnosis in a previously intractable case. [ABSTRACT FROM AUTHOR]

Published

2017

14. Lessons from the CAGI-4 Hopkins clinical panel challenge.

Author

Chandonia, John‐Marc, Adhikari, Aashish, Carraro, Marco, Chhibber, Aparna, Cutting, Garry R., Fu, Yao, Gasparini, Alessandra, Jones, David T., Kramer, Andreas, Kundu, Kunal, Lam, Hugo Y. K., Leonardi, Emanuela, Moult, John, Pal, Lipika R., Searls, David B., Shah, Sohela, Sunyaev, Shamil, Tosatto, Silvio C. E., Yin, Yizhou, and Buckley, Bethany A.

Abstract

The CAGI-4 Hopkins clinical panel challenge was an attempt to assess state-of-the-art methods for clinical phenotype prediction from DNA sequence. Participants were provided with exonic sequences of 83 genes for 106 patients from the Johns Hopkins DNA Diagnostic Laboratory. Five groups participated in the challenge, predicting both the probability that each patient had each of the 14 possible classes of disease, as well as one or more causal variants. In cases where the Hopkins laboratory reported a variant, at least one predictor correctly identified the disease class in 36 of the 43 patients (84%). Even in cases where the Hopkins laboratory did not find a variant, at least one predictor correctly identified the class in 39 of the 63 patients (62%). Each prediction group correctly diagnosed at least one patient that was not successfully diagnosed by any other group. We discuss the causal variant predictions by different groups and their implications for further development of methods to assess variants of unknown significance. Our results suggest that clinically relevant variants may be missed when physicians order small panels targeted on a specific phenotype. We also quantify the false-positive rate of DNA-guided analysis in the absence of prior phenotypic indication. [ABSTRACT FROM AUTHOR]

Published

2017

15. Determination of disease phenotypes and pathogenic variants from exome sequence data in the CAGI 4 gene panel challenge.

Author

Kundu, Kunal, Pal, Lipika R., Yin, Yizhou, and Moult, John

Abstract

The use of gene panel sequence for diagnostic and prognostic testing is now widespread, but there are so far few objective tests of methods to interpret these data. We describe the design and implementation of a gene panel sequencing data analysis pipeline (VarP) and its assessment in a CAGI4 community experiment. The method was applied to clinical gene panel sequencing data of 106 patients, with the goal of determining which of 14 disease classes each patient has and the corresponding causative variant(s). The disease class was correctly identified for 36 cases, including 10 where the original clinical pipeline did not find causative variants. For a further seven cases, we found strong evidence of an alternative disease to that tested. Many of the potentially causative variants are missense, with no previous association with disease, and these proved the hardest to correctly assign pathogenicity or otherwise. Post analysis showed that three-dimensional structure data could have helped for up to half of these cases. Over-reliance on HGMD annotation led to a number of incorrect disease assignments. We used a largely ad hoc method to assign probabilities of pathogenicity for each variant, and there is much work still to be done in this area. [ABSTRACT FROM AUTHOR]

Published

2017

16. Back Cover, Volume 40, Issue 9.

Author

Andreoletti, Gaia, Pal, Lipika R., Moult, John, and Brenner, Steven E.

Published

2019