Your search keyword '"Mark P Keller"' showing total 6 results

1. Genetic Drivers of Pancreatic Islet Function

Author

Brian S. Yandell, Matthew Vincent, Christina Kendziorski, Mary E. Rabaglia, Kathryn L. Schueler, Rhonda Bacher, Petr Simecek, Donnie S. Stapleton, Mark P. Keller, Sadie Allen, Aimee Teo Broman, Karl W. Broman, Daniel M. Gatti, Gary A. Churchill, and Alan D. Attie

Subjects

0301 basic medicine, Somatostatin-Secreting Cells, Genotype, Quantitative Trait Loci, Population, Web Browser, Investigations, Quantitative trait locus, Biology, Diabetes Mellitus, Experimental, Islets of Langerhans, Mice, 03 medical and health sciences, Quantitative Trait, Heritable, Genetics, Animals, Humans, Gene Regulatory Networks, Pancreatic islet function, education, Association mapping, Gene, Alleles, Genetic Association Studies, education.field_of_study, Gene Expression Profiling, Computational Biology, Phenotype, 030104 developmental biology, Diabetes Mellitus, Type 2, Gene Expression Regulation, Haplotypes, Glucagon-Secreting Cells, Expression quantitative trait loci, PDX1, Transcriptome, Genome-Wide Association Study

Abstract

The majority of gene loci that have been associated with type 2 diabetes play a role in pancreatic islet function. To evaluate the role of islet gene expression in the etiology of diabetes, we sensitized a genetically diverse mouse population with a Western diet high in fat (45% kcal) and sucrose (34%) and carried out genome-wide association mapping of diabetes-related phenotypes. We quantified mRNA abundance in the islets and identified 18,820 expression QTL. We applied mediation analysis to identify candidate causal driver genes at loci that affect the abundance of numerous transcripts. These include two genes previously associated with monogenic diabetes (PDX1 and HNF4A), as well as three genes with nominal association with diabetes-related traits in humans (FAM83E, IL6ST, and SAT2). We grouped transcripts into gene modules and mapped regulatory loci for modules enriched with transcripts specific for α-cells, and another specific for δ-cells. However, no single module enriched for β-cell-specific transcripts, suggesting heterogeneity of gene expression patterns within the β-cell population. A module enriched in transcripts associated with branched-chain amino acid metabolism was the most strongly correlated with physiological traits that reflect insulin resistance. Although the mice in this study were not overtly diabetic, the analysis of pancreatic islet gene expression under dietary-induced stress enabled us to identify correlated variation in groups of genes that are functionally linked to diabetes-associated physiological traits. Our analysis suggests an expected degree of concordance between diabetes-associated loci in the mouse and those found in human populations, and demonstrates how the mouse can provide evidence to support nominal associations found in human genome-wide association mapping.

Published

2018

2. The Dissection of Expression Quantitative Trait Locus Hotspots

Author

Karl W. Broman, Aimee Teo Broman, Alan D. Attie, Christina Kendziorski, Brian S. Yandell, Jianan Tian, and Mark P. Keller

Subjects

FOS: Computer and information sciences, 0301 basic medicine, Quantitative Trait Loci, Gene Expression, Locus (genetics), Investigations, Quantitative trait locus, Biology, Statistics - Applications, Mice, 03 medical and health sciences, Quantitative Trait, Heritable, 0302 clinical medicine, Gene expression, Genetics, Animals, Computer Simulation, Inbreeding, Applications (stat.AP), Quantitative Biology - Genomics, Crosses, Genetic, Dominance (genetics), Recombination, Genetic, Genomics (q-bio.GN), Models, Genetic, Chromosome Mapping, Phenotype, 030104 developmental biology, FOS: Biological sciences, Multivariate Analysis, Expression quantitative trait loci, Trait, Lod Score, 030217 neurology & neurosurgery

Abstract

Studies of the genetic loci that contribute to variation in gene expression frequently identify loci with broad effect on gene expression: expression quantitative trait locus (eQTL) hotspots. We describe a set of exploratory graphical methods as well as a formal likelihood-based test for assessing whether a given hotspot is due to one or multiple polymorphisms. We first look at the pattern of effects of the locus on the expression traits that map to the locus: the direction of the effects, as well as the degree of dominance. A second technique is to focus on the individuals that exhibit no recombination event in the region, apply dimensionality reduction (such as with linear discriminant analysis) and compare the phenotype distribution in the non-recombinants to that in the recombinant individuals: If the recombinant individuals display a different expression pattern than the non-recombinants, this indicates the presence of multiple causal polymorphisms. In the formal likelihood-based test, we compare a two-locus model, with each expression trait affected by one or the other locus, to a single-locus model. We apply our methods to a large mouse intercross with gene expression microarray data on six tissues., 40 pages, 6 figures, 3 supplemental figures, and a separate PDF file (FileS1.pdf) with an additional 35 pages of figures; made small changes to text on pages 26-31 in response to reviewers' comments; corrected a number of typographical errors and added acknowledgment of an additional grant

Published

2016

3. Genetic Architectures of Quantitative Variation in RNA Editing Pathways

Author

Petr Simecek, Daniel M. Gatti, Narayanan Raghupathy, Alan D. Attie, Jeffrey H. Chuang, Mark P. Keller, Tongjun Gu, Gary A. Churchill, Ivan Dotu, Karen L. Svenson, Anuj Srivastava, Elizabeth M Snyder, and Robert E. Braun

Subjects

Male, 0301 basic medicine, Multifactorial Inheritance, MULTIPARENTAL POPULATIONS, Apolipoprotein B, APOBEC-1 Deaminase, Quantitative Trait Loci, Population, Biology, Genome, Nucleic acid secondary structure, Mice, 03 medical and health sciences, Cytidine Deaminase, Genetics, Animals, education, education.field_of_study, Gene Expression Profiling, APOBEC1, Chromosome Mapping, Genetic Variation, RNA, 030104 developmental biology, RNA editing, biology.protein, Female, RNA Editing

Abstract

RNA editing refers to post-transcriptional processes that alter the base sequence of RNA. Recently, hundreds of new RNA editing targets have been reported. However, the mechanisms that determine the specificity and degree of editing are not well understood. We examined quantitative variation of site-specific editing in a genetically diverse multiparent population, Diversity Outbred mice, and mapped polymorphic loci that alter editing ratios globally for C-to-U editing and at specific sites for A-to-I editing. An allelic series in the C-to-U editing enzyme Apobec1 influences the editing efficiency of Apob and 58 additional C-to-U editing targets. We identified 49 A-to-I editing sites with polymorphisms in the edited transcript that alter editing efficiency. In contrast to the shared genetic control of C-to-U editing, most of the variable A-to-I editing sites were determined by local nucleotide polymorphisms in proximity to the editing site in the RNA secondary structure. Our results indicate that RNA editing is a quantitative trait subject to genetic variation and that evolutionary constraints have given rise to distinct genetic architectures in the two canonical types of RNA editing.

Published

2015

4. Statistical Methods for Latent Class Quantitative Trait Loci Mapping

Author

Shuyun Ye, Alan D. Attie, Rhonda Bacher, Christina Kendziorski, and Mark P. Keller

Subjects

0301 basic medicine, QTL mapping, obesity, Population, Quantitative Trait Loci, Feature selection, Quantitative trait locus, Biology, Investigations, complex traits, 03 medical and health sciences, Mice, Family-based QTL mapping, Inclusive composite interval mapping, Genetic model, Genetics, Animals, latent class regression, stepwise regression, education, education.field_of_study, type II diabetes, Models, Statistical, Models, Genetic, Chromosome Mapping, Range (mathematics), 030104 developmental biology, Diabetes Mellitus, Type 2, Identification (biology), Statistical Genetics and Genomics

Abstract

Identifying the genetic basis of complex traits is an important problem with the potential to impact a broad range of biological endeavors. A number of effective statistical methods are available for quantitative trait loci (QTL) mapping that allow for the efficient identification of multiple, potentially interacting, loci under a variety of experimental conditions. Although proven useful in hundreds of studies, the majority of these methods assumes a single model common to each subject, which may reduce power and accuracy when genetically distinct subclasses exist. To address this, we have developed an approach to enable latent class QTL mapping. The approach combines latent class regression with stepwise variable selection and traditional QTL mapping to estimate the number of subclasses in a population, and to identify the genetic model that best describes each subclass. Simulations demonstrate good performance of the method when latent classes are present as well as when they are not, with accurate estimation of QTL. Application of the method to case studies of obesity and diabetes in mouse gives insight into the genetic basis of related complex traits.

Published

2017

5. RNA-Seq Alignment to Individualized Genomes Improves Transcript Abundance Estimates in Multiparent Populations

Author

Narayanan Raghupathy, Daniel M. Gatti, Steven C. Munger, Alan D. Attie, Joel H. Graber, Mark P. Keller, Gary A. Churchill, Kwangbom Choi, Douglas Hinerfeld, Karen L. Svenson, Elissa J. Chesler, Matthew A. Hibbs, and Allen K. Simons

Subjects

QTL mapping, mixed models, MPP, Male, Diversity Outbred (DO), high-density genotyping, Quantitative Trait Loci, RNA-Seq, Biology, Quantitative trait locus, Genome, haplotype reconstruction, Transcriptome, Mice, 03 medical and health sciences, 0302 clinical medicine, Multiparental Populations, Genetics, Animals, Diversity Outbred mice, Alignment-free sequence analysis, 030304 developmental biology, Sequence (medicine), Linkage (software), 0303 health sciences, Sequence Analysis, RNA, expression QTL, Female, RNA-seq, Multiparent Advanced Generation Inter-Cross (MAGIC), Sequence Alignment, Software, 030217 neurology & neurosurgery, Reference genome

Abstract

Massively parallel RNA sequencing (RNA-seq) has yielded a wealth of new insights into transcriptional regulation. A first step in the analysis of RNA-seq data is the alignment of short sequence reads to a common reference genome or transcriptome. Genetic variants that distinguish individual genomes from the reference sequence can cause reads to be misaligned, resulting in biased estimates of transcript abundance. Fine-tuning of read alignment algorithms does not correct this problem. We have developed Seqnature software to construct individualized diploid genomes and transcriptomes for multiparent populations and have implemented a complete analysis pipeline that incorporates other existing software tools. We demonstrate in simulated and real data sets that alignment to individualized transcriptomes increases read mapping accuracy, improves estimation of transcript abundance, and enables the direct estimation of allele-specific expression. Moreover, when applied to expression QTL mapping we find that our individualized alignment strategy corrects false-positive linkage signals and unmasks hidden associations. We recommend the use of individualized diploid genomes over reference sequence alignment for all applications of high-throughput sequencing technology in genetically diverse populations.

Published

2014

6. Modeling Causality for Pairs of Phenotypes in System Genetics

Author

Elias Chaibub Neto, Bin Zhang, Brian S. Yandell, Jun Zhu, Mark P. Keller, Alan D. Attie, and Aimee Teo Broman

Subjects

model selection, causality, systems genetics, Quantitative Trait Loci, Gene regulatory network, Inference, Biology, Investigations, 01 natural sciences, 010104 statistics & probability, 03 medical and health sciences, Genome and Systems Biology, Yeasts, Genetics, Feature (machine learning), Computer Simulation, False Positive Reactions, Gene Regulatory Networks, 0101 mathematics, hypothesis tests, Selection (genetic algorithm), 030304 developmental biology, Probability, Regulation of gene expression, 0303 health sciences, Models, Genetic, Mechanism (biology), Model selection, Causality, Phenotype, Gene Expression Regulation, Gene Deletion

Abstract

Current efforts in systems genetics have focused on the development of statistical approaches that aim to disentangle causal relationships among molecular phenotypes in segregating populations. Reverse engineering of transcriptional networks plays a key role in the understanding of gene regulation. However, transcriptional regulation is only one possible mechanism, as methylation, phosphorylation, direct protein–protein interaction, transcription factor binding, etc., can also contribute to gene regulation. These additional modes of regulation can be interpreted as unobserved variables in the transcriptional gene network and can potentially affect its reconstruction accuracy. We develop tests of causal direction for a pair of phenotypes that may be embedded in a more complicated but unobserved network by extending Vuong’s selection tests for misspecified models. Our tests provide a significance level, which is unavailable for the widely used AIC and BIC criteria. We evaluate the performance of our tests against the AIC, BIC, and a recently published causality inference test in simulation studies. We compare the precision of causal calls using biologically validated causal relationships extracted from a database of 247 knockout experiments in yeast. Our model selection tests are more precise, showing greatly reduced false-positive rates compared to the alternative approaches. In practice, this is a useful feature since follow-up studies tend to be time consuming and expensive and, hence, it is important for the experimentalist to have causal predictions with low false-positive rates.

Published

2013