Your search keyword '"Belsare, Saurabh"' showing total 3 results

1. Expanding the stdpopsim species catalog, and lessons learned for realistic genome simulations.

Author

Lauterbur ME, Cavassim MIA, Gladstein AL, Gower G, Pope NS, Tsambos G, Adrion J, Belsare S, Biddanda A, Caudill V, Cury J, Echevarria I, Haller BC, Hasan AR, Huang X, Iasi LNM, Noskova E, Obsteter J, Pavinato VAC, Pearson A, Peede D, Perez MF, Rodrigues MF, Smith CCR, Spence JP, Teterina A, Tittes S, Unneberg P, Vazquez JM, Waples RK, Wohns AW, Wong Y, Baumdicker F, Cartwright RA, Gorjanc G, Gutenkunst RN, Kelleher J, Kern AD, Ragsdale AP, Ralph PL, Schrider DR, and Gronau I

Subjects

Computer Simulation, Genetics, Population, Genomics, Software, Genome

Abstract

Simulation is a key tool in population genetics for both methods development and empirical research, but producing simulations that recapitulate the main features of genomic datasets remains a major obstacle. Today, more realistic simulations are possible thanks to large increases in the quantity and quality of available genetic data, and the sophistication of inference and simulation software. However, implementing these simulations still requires substantial time and specialized knowledge. These challenges are especially pronounced for simulating genomes for species that are not well-studied, since it is not always clear what information is required to produce simulations with a level of realism sufficient to confidently answer a given question. The community-developed framework stdpopsim seeks to lower this barrier by facilitating the simulation of complex population genetic models using up-to-date information. The initial version of stdpopsim focused on establishing this framework using six well-characterized model species (Adrion et al., 2020). Here, we report on major improvements made in the new release of stdpopsim (version 0.2), which includes a significant expansion of the species catalog and substantial additions to simulation capabilities. Features added to improve the realism of the simulated genomes include non-crossover recombination and provision of species-specific genomic annotations. Through community-driven efforts, we expanded the number of species in the catalog more than threefold and broadened coverage across the tree of life. During the process of expanding the catalog, we have identified common sticking points and developed the best practices for setting up genome-scale simulations. We describe the input data required for generating a realistic simulation, suggest good practices for obtaining the relevant information from the literature, and discuss common pitfalls and major considerations. These improvements to stdpopsim aim to further promote the use of realistic whole-genome population genetic simulations, especially in non-model organisms, making them available, transparent, and accessible to everyone., Competing Interests: ML, MC, GG, NP, GT, SB, VC, JC, IE, BH, AH, XH, LI, EN, JO, VP, AP, DP, MP, MR, CS, JS, AT, ST, PU, JV, RW, AW, YW, FB, RC, GG, RG, JK, AK, AR, PR, DS, IG No competing interests declared, AG is an employee of Embark Veterinary, Inc. The author declares that no other competing interests exist, JA is an employee of Ancestry DNA. The author declares that no other competing interests exist, AB is an employee of 54Gene, Inc. The author declares that no other competing interests exist, (© 2023, Lauterbur et al.)

Published

2023

2. Expanding the stdpopsim species catalog, and lessons learned for realistic genome simulations

Author

Lauterbur, M Elise, Cavassim, Maria Izabel A, Gladstein, Ariella L, Gower, Graham, Pope, Nathaniel S, Tsambos, Georgia, Adrion, Jeffrey, Belsare, Saurabh, Biddanda, Arjun, Caudill, Victoria, Cury, Jean, Echevarria, Ignacio, Haller, Benjamin C, Hasan, Ahmed R, Huang, Xin, Iasi, Leonardo Nicola Martin, Noskova, Ekaterina, Obsteter, Jana, Pavinato, Vitor Antonio Correa, Pearson, Alice, Peede, David, Perez, Manolo F, Rodrigues, Murillo F, Smith, Chris CR, Spence, Jeffrey P, Teterina, Anastasia, Tittes, Silas, Unneberg, Per, Vazquez, Juan Manuel, Waples, Ryan K, Wohns, Anthony Wilder, Wong, Yan, Baumdicker, Franz, Cartwright, Reed A, Gorjanc, Gregor, Gutenkunst, Ryan N, Kelleher, Jerome, Kern, Andrew D, Ragsdale, Aaron P, Ralph, Peter L, Schrider, Daniel R, and Gronau, Ilan

Subjects

Genetics, Biotechnology, Human Genome, Generic health relevance, Software, Computer Simulation, Genome, Genetics, Population, Genomics, population genetics, simulations, open source, None, genetics, genomics, none, Biochemistry and Cell Biology

Abstract

Simulation is a key tool in population genetics for both methods development and empirical research, but producing simulations that recapitulate the main features of genomic datasets remains a major obstacle. Today, more realistic simulations are possible thanks to large increases in the quantity and quality of available genetic data, and the sophistication of inference and simulation software. However, implementing these simulations still requires substantial time and specialized knowledge. These challenges are especially pronounced for simulating genomes for species that are not well-studied, since it is not always clear what information is required to produce simulations with a level of realism sufficient to confidently answer a given question. The community-developed framework stdpopsim seeks to lower this barrier by facilitating the simulation of complex population genetic models using up-to-date information. The initial version of stdpopsim focused on establishing this framework using six well-characterized model species (Adrion et al., 2020). Here, we report on major improvements made in the new release of stdpopsim (version 0.2), which includes a significant expansion of the species catalog and substantial additions to simulation capabilities. Features added to improve the realism of the simulated genomes include non-crossover recombination and provision of species-specific genomic annotations. Through community-driven efforts, we expanded the number of species in the catalog more than threefold and broadened coverage across the tree of life. During the process of expanding the catalog, we have identified common sticking points and developed the best practices for setting up genome-scale simulations. We describe the input data required for generating a realistic simulation, suggest good practices for obtaining the relevant information from the literature, and discuss common pitfalls and major considerations. These improvements to stdpopsim aim to further promote the use of realistic whole-genome population genetic simulations, especially in non-model organisms, making them available, transparent, and accessible to everyone.

Published

2023

3. Evaluating the quality of the 1000 genomes project data

Author

Belsare, Saurabh, Levy-Sakin, Michal, Mostovoy, Yulia, Durinck, Steffen, Chaudhuri, Subhra, Xiao, Ming, Peterson, Andrew S, Kwok, Pui-Yan, Seshagiri, Somasekar, and Wall, Jeffrey D

Subjects

Biotechnology, Human Genome, Genetics, Gene Frequency, Genome, Human, Haplotypes, High-Throughput Nucleotide Sequencing, Human Genome Project, Humans, Polymorphism, Single Nucleotide, Racial Groups, Scientific Experimental Error, genomes, Phasing, Imputation, Biological Sciences, Information and Computing Sciences, Medical and Health Sciences, Bioinformatics

Abstract

BackgroundData from the 1000 Genomes project is quite often used as a reference for human genomic analysis. However, its accuracy needs to be assessed to understand the quality of predictions made using this reference. We present here an assessment of the genotyping, phasing, and imputation accuracy data in the 1000 Genomes project. We compare the phased haplotype calls from the 1000 Genomes project to experimentally phased haplotypes for 28 of the same individuals sequenced using the 10X Genomics platform.ResultsWe observe that phasing and imputation for rare variants are unreliable, which likely reflects the limited sample size of the 1000 Genomes project data. Further, it appears that using a population specific reference panel does not improve the accuracy of imputation over using the entire 1000 Genomes data set as a reference panel. We also note that the error rates and trends depend on the choice of definition of error, and hence any error reporting needs to take these definitions into account.ConclusionsThe quality of the 1000 Genomes data needs to be considered while using this database for further studies. This work presents an analysis that can be used for these assessments.

Published

2019