Your search keyword '"McGarr TC"' showing total 6 results

1. Unique properties of a subset of human pluripotent stem cells with high capacity for self-renewal

Author

Lau, KX, Mason, EA, Kie, J, De Souza, DP, Kloehn, J, Tull, D, McConville, MJ, Keniry, A, Beck, T, Blewitt, ME, Ritchie, ME, Naik, SH, Zalcenstein, D, Korn, O, Su, S, Romero, IG, Spruce, C, Baker, CL, McGarr, TC, Wells, CA, Pera, MF, Lau, KX, Mason, EA, Kie, J, De Souza, DP, Kloehn, J, Tull, D, McConville, MJ, Keniry, A, Beck, T, Blewitt, ME, Ritchie, ME, Naik, SH, Zalcenstein, D, Korn, O, Su, S, Romero, IG, Spruce, C, Baker, CL, McGarr, TC, Wells, CA, and Pera, MF

Abstract

Archetypal human pluripotent stem cells (hPSC) are widely considered to be equivalent in developmental status to mouse epiblast stem cells, which correspond to pluripotent cells at a late post-implantation stage of embryogenesis. Heterogeneity within hPSC cultures complicates this interspecies comparison. Here we show that a subpopulation of archetypal hPSC enriched for high self-renewal capacity (ESR) has distinct properties relative to the bulk of the population, including a cell cycle with a very low G1 fraction and a metabolomic profile that reflects a combination of oxidative phosphorylation and glycolysis. ESR cells are pluripotent and capable of differentiation into primordial germ cell-like cells. Global DNA methylation levels in the ESR subpopulation are lower than those in mouse epiblast stem cells. Chromatin accessibility analysis revealed a unique set of open chromatin sites in ESR cells. RNA-seq at the subpopulation and single cell levels shows that, unlike mouse epiblast stem cells, the ESR subset of hPSC displays no lineage priming, and that it can be clearly distinguished from gastrulating and extraembryonic cell populations in the primate embryo. ESR hPSC correspond to an earlier stage of post-implantation development than mouse epiblast stem cells.

Published

2020

2. Physiological and genetic analysis of multiple sodium channel variants in a model of genetic absence epilepsy

Author

Oliva, MK, McGarr, TC, Beyer, BJ, Gazina, E, Kaplan, DI, Cordeiro, L, Thomas, E, Dib-Hajj, SD, Waxman, SG, Frankel, WN, Petrou, S, Oliva, MK, McGarr, TC, Beyer, BJ, Gazina, E, Kaplan, DI, Cordeiro, L, Thomas, E, Dib-Hajj, SD, Waxman, SG, Frankel, WN, and Petrou, S

Abstract

In excitatory neurons, SCN2A (NaV1.2) and SCN8A (NaV1.6) sodium channels are enriched at the axon initial segment. NaV1.6 is implicated in several mouse models of absence epilepsy, including a missense mutation identified in a chemical mutagenesis screen (Scn8a(V929F)). Here, we confirmed the prior suggestion that Scn8a(V929F) exhibits a striking genetic background-dependent difference in phenotypic severity, observing that spike-wave discharge (SWD) incidence and severity are significantly diminished when Scn8a(V929F) is fully placed onto the C57BL/6J strain compared with C3H. Examination of sequence differences in NaV subunits between these two inbred strains suggested NaV1.2(V752F) as a potential source of this modifier effect. Recognising that the spatial co-localisation of the NaV channels at the axon initial segment (AIS) provides a plausible mechanism for functional interaction, we tested this idea by undertaking biophysical characterisation of the variant NaV channels and by computer modelling. NaV1.2(V752F) functional analysis revealed an overall gain-of-function and for NaV1.6(V929F) revealed an overall loss-of-function. A biophysically realistic computer model was used to test the idea that interaction between these variant channels at the AIS contributes to the strain background effect. Surprisingly this modelling showed that neuronal excitability is dominated by the properties of NaV1.2(V752F) due to "functional silencing" of NaV1.6(V929F) suggesting that these variants do not directly interact. Consequent genetic mapping of the major strain modifier to Chr 7, and not Chr 2 where Scn2a maps, supported this biophysical prediction. While a NaV1.6(V929F) loss of function clearly underlies absence seizures in this mouse model, the strain background effect is apparently not due to an otherwise tempting Scn2a variant, highlighting the value of combining physiology and genetics to inform and direct each other when interrogating genetic complex traits such as a

Published

2014

3. Unique properties of a subset of human pluripotent stem cells with high capacity for self-renewal.

Author

Lau KX, Mason EA, Kie J, De Souza DP, Kloehn J, Tull D, McConville MJ, Keniry A, Beck T, Blewitt ME, Ritchie ME, Naik SH, Zalcenstein D, Korn O, Su S, Romero IG, Spruce C, Baker CL, McGarr TC, Wells CA, and Pera MF

Subjects

Animals, Cell Differentiation, Chromatin metabolism, DNA Methylation, Epigenome, Flow Cytometry, Fluorescent Antibody Technique, Indirect, G1 Phase, Germ Layers metabolism, Glycolysis, Humans, MAP Kinase Signaling System, Metabolomics, Mice, Mitochondria metabolism, Oxidative Phosphorylation, RNA-Seq, Signal Transduction, Embryonic Stem Cells cytology, Germ Layers cytology, Pluripotent Stem Cells cytology

Abstract

Archetypal human pluripotent stem cells (hPSC) are widely considered to be equivalent in developmental status to mouse epiblast stem cells, which correspond to pluripotent cells at a late post-implantation stage of embryogenesis. Heterogeneity within hPSC cultures complicates this interspecies comparison. Here we show that a subpopulation of archetypal hPSC enriched for high self-renewal capacity (ESR) has distinct properties relative to the bulk of the population, including a cell cycle with a very low G1 fraction and a metabolomic profile that reflects a combination of oxidative phosphorylation and glycolysis. ESR cells are pluripotent and capable of differentiation into primordial germ cell-like cells. Global DNA methylation levels in the ESR subpopulation are lower than those in mouse epiblast stem cells. Chromatin accessibility analysis revealed a unique set of open chromatin sites in ESR cells. RNA-seq at the subpopulation and single cell levels shows that, unlike mouse epiblast stem cells, the ESR subset of hPSC displays no lineage priming, and that it can be clearly distinguished from gastrulating and extraembryonic cell populations in the primate embryo. ESR hPSC correspond to an earlier stage of post-implantation development than mouse epiblast stem cells.

Published

2020

4. A genetic interaction network model of a complex neurological disease.

Author

Tyler AL, McGarr TC, Beyer BJ, Frankel WN, and Carter GW

Subjects

Animals, Disease Models, Animal, Humans, Mice, Phenotype, Quantitative Trait Loci, Epilepsy, Absence genetics, Epistasis, Genetic, Gene Regulatory Networks, Models, Genetic

Abstract

Absence epilepsy (AE) is a complex, heritable disease characterized by a brief disruption of normal behavior and accompanying spike-wave discharges (SWD) on the electroencephalogram. Only a handful of genes has been definitively associated with AE in humans and rodent models. Most studies suggest that genetic interactions play a large role in the etiology and severity of AE, but mapping and understanding their architecture remains a challenge, requiring new computational approaches. Here we use combined analysis of pleiotropy and epistasis (CAPE) to detect and interpret genetic interactions in a meta-population derived from three C3H × B6J strain crosses, each of which is fixed for a different SWD-causing mutation. Although each mutation causes SWD through a different molecular mechanism, the phenotypes caused by each mutation are exacerbated on the C3H genetic background compared with B6J, suggesting common modifiers. By combining information across two phenotypic measures - SWD duration and frequency - CAPE showed a large, directed genetic network consisting of suppressive and enhancing interactions between loci on 10 chromosomes. These results illustrate the power of CAPE in identifying novel modifier loci and interactions in a complex neurological disease, toward a more comprehensive view of its underlying genetic architecture., (© 2014 The Authors. Genes, Brain and Behavior published by International Behavioural and Neural Genetics Society and John Wiley & Sons Ltd.)

Published

2014

5. Unraveling genetic modifiers in the gria4 mouse model of absence epilepsy.

Author

Frankel WN, Mahaffey CL, McGarr TC, Beyer BJ, and Letts VA

Subjects

Alleles, Animals, Chromosome Mapping, Disease Models, Animal, Epilepsy, Absence pathology, Humans, Mice, Phenotype, Retroelements genetics, Seizures pathology, Epilepsy, Absence genetics, Neoplasm Proteins genetics, Receptors, AMPA genetics, Seizures genetics

Abstract

Absence epilepsy (AE) is a common type of genetic generalized epilepsy (GGE), particularly in children. AE and GGE are complex genetic diseases with few causal variants identified to date. Gria4 deficient mice provide a model of AE, one for which the common laboratory inbred strain C3H/HeJ (HeJ) harbors a natural IAP retrotransposon insertion in Gria4 that reduces its expression 8-fold. Between C3H and non-seizing strains such as C57BL/6, genetic modifiers alter disease severity. Even C3H substrains have surprising variation in the duration and incidence of spike-wave discharges (SWD), the characteristic electroencephalographic feature of absence seizures. Here we discovered extensive IAP retrotransposition in the C3H substrain, and identified a HeJ-private IAP in the Pcnxl2 gene, which encodes a putative multi-transmembrane protein of unknown function, resulting in decreased expression. By creating new Pcnxl2 frameshift alleles using TALEN mutagenesis, we show that Pcnxl2 deficiency is responsible for mitigating the seizure phenotype - making Pcnxl2 the first known modifier gene for absence seizures in any species. This finding gave us a handle on genetic complexity between strains, directing us to use another C3H substrain to map additional modifiers including validation of a Chr 15 locus that profoundly affects the severity of SWD episodes. Together these new findings expand our knowledge of how natural variation modulates seizures, and highlights the feasibility of characterizing and validating modifiers in mouse strains and substrains in the post-genome sequence era.

Published

2014

6. Physiological and genetic analysis of multiple sodium channel variants in a model of genetic absence epilepsy.

Author

Oliva MK, McGarr TC, Beyer BJ, Gazina E, Kaplan DI, Cordeiro L, Thomas E, Dib-Hajj SD, Waxman SG, Frankel WN, and Petrou S

Subjects

Animals, Axons physiology, Disease Models, Animal, Mice, Mice, Inbred C3H, Mice, Inbred C57BL, Mice, Mutant Strains, Models, Neurological, Brain physiopathology, Epilepsy, Absence genetics, Epilepsy, Absence physiopathology, NAV1.2 Voltage-Gated Sodium Channel genetics, NAV1.2 Voltage-Gated Sodium Channel metabolism, NAV1.6 Voltage-Gated Sodium Channel genetics, NAV1.6 Voltage-Gated Sodium Channel metabolism

Abstract

In excitatory neurons, SCN2A (NaV1.2) and SCN8A (NaV1.6) sodium channels are enriched at the axon initial segment. NaV1.6 is implicated in several mouse models of absence epilepsy, including a missense mutation identified in a chemical mutagenesis screen (Scn8a(V929F)). Here, we confirmed the prior suggestion that Scn8a(V929F) exhibits a striking genetic background-dependent difference in phenotypic severity, observing that spike-wave discharge (SWD) incidence and severity are significantly diminished when Scn8a(V929F) is fully placed onto the C57BL/6J strain compared with C3H. Examination of sequence differences in NaV subunits between these two inbred strains suggested NaV1.2(V752F) as a potential source of this modifier effect. Recognising that the spatial co-localisation of the NaV channels at the axon initial segment (AIS) provides a plausible mechanism for functional interaction, we tested this idea by undertaking biophysical characterisation of the variant NaV channels and by computer modelling. NaV1.2(V752F) functional analysis revealed an overall gain-of-function and for NaV1.6(V929F) revealed an overall loss-of-function. A biophysically realistic computer model was used to test the idea that interaction between these variant channels at the AIS contributes to the strain background effect. Surprisingly this modelling showed that neuronal excitability is dominated by the properties of NaV1.2(V752F) due to "functional silencing" of NaV1.6(V929F) suggesting that these variants do not directly interact. Consequent genetic mapping of the major strain modifier to Chr 7, and not Chr 2 where Scn2a maps, supported this biophysical prediction. While a NaV1.6(V929F) loss of function clearly underlies absence seizures in this mouse model, the strain background effect is apparently not due to an otherwise tempting Scn2a variant, highlighting the value of combining physiology and genetics to inform and direct each other when interrogating genetic complex traits such as absence epilepsy., (Crown Copyright © 2014. Published by Elsevier Inc. All rights reserved.)

Published

2014