Your search keyword '"Dolinoy, Dana C"' showing total 5 results

1. DNA Methylation Changes Are Associated With an Incremental Ascent to High Altitude.

Author

Childebayeva, Ainash, Childebayeva, Ainash, Harman, Taylor, Weinstein, Julien, Goodrich, Jaclyn M, Dolinoy, Dana C, Day, Trevor A, Bigham, Abigail W, Brutsaert, Tom D, Childebayeva, Ainash, Childebayeva, Ainash, Harman, Taylor, Weinstein, Julien, Goodrich, Jaclyn M, Dolinoy, Dana C, Day, Trevor A, Bigham, Abigail W, and Brutsaert, Tom D

Abstract

Genetic and nongenetic factors are involved in the individual ability to physiologically acclimatize to high-altitude hypoxia through processes that include increased heart rate and ventilation. High-altitude acclimatization is thought to have a genetic component, yet it is unclear if other factors, such as epigenetic gene regulation, are involved in acclimatization to high-altitude hypoxia in nonacclimatized individuals. We collected saliva samples from a group of healthy adults of European ancestry (n = 21) in Kathmandu (1,400 m; baseline) and three altitudes during a trek to the Everest Base Camp: Namche (3,440 m; day 3), Pheriche (4,240 m; day 7), and Gorak Shep (5,160 m; day 10). We used quantitative bisulfite pyrosequencing to determine changes in DNA methylation, a well-studied epigenetic marker, in LINE-1, EPAS1, EPO, PPARa, and RXRa. We found significantly lower DNA methylation between baseline (1,400 m) and high altitudes in LINE-1, EPO (at 4,240 m only), and RXRa. We found increased methylation in EPAS1 (at 4,240 m only) and PPARa. We also found positive associations between EPO methylation and systolic blood pressure and RXRa methylation and hemoglobin. Our results show that incremental exposure to hypoxia can affect the epigenome. Changes to the epigenome, in turn, could underlie the process of altitude acclimatization.

Published

2019

2. DNA Methylation Changes Are Associated With an Incremental Ascent to High Altitude.

Author

Childebayeva, Ainash, Childebayeva, Ainash, Harman, Taylor, Weinstein, Julien, Goodrich, Jaclyn M, Dolinoy, Dana C, Day, Trevor A, Bigham, Abigail W, Brutsaert, Tom D, Childebayeva, Ainash, Childebayeva, Ainash, Harman, Taylor, Weinstein, Julien, Goodrich, Jaclyn M, Dolinoy, Dana C, Day, Trevor A, Bigham, Abigail W, and Brutsaert, Tom D

Abstract

Genetic and nongenetic factors are involved in the individual ability to physiologically acclimatize to high-altitude hypoxia through processes that include increased heart rate and ventilation. High-altitude acclimatization is thought to have a genetic component, yet it is unclear if other factors, such as epigenetic gene regulation, are involved in acclimatization to high-altitude hypoxia in nonacclimatized individuals. We collected saliva samples from a group of healthy adults of European ancestry (n = 21) in Kathmandu (1,400 m; baseline) and three altitudes during a trek to the Everest Base Camp: Namche (3,440 m; day 3), Pheriche (4,240 m; day 7), and Gorak Shep (5,160 m; day 10). We used quantitative bisulfite pyrosequencing to determine changes in DNA methylation, a well-studied epigenetic marker, in LINE-1, EPAS1, EPO, PPARa, and RXRa. We found significantly lower DNA methylation between baseline (1,400 m) and high altitudes in LINE-1, EPO (at 4,240 m only), and RXRa. We found increased methylation in EPAS1 (at 4,240 m only) and PPARa. We also found positive associations between EPO methylation and systolic blood pressure and RXRa methylation and hemoglobin. Our results show that incremental exposure to hypoxia can affect the epigenome. Changes to the epigenome, in turn, could underlie the process of altitude acclimatization.

Published

2019

3. Small-Magnitude Effect Sizes in Epigenetic End Points are Important in Children's Environmental Health Studies: The Children's Environmental Health and Disease Prevention Research Center's Epigenetics Working Group.

Author

Breton, Carrie V, Breton, Carrie V, Marsit, Carmen J, Faustman, Elaine, Nadeau, Kari, Goodrich, Jaclyn M, Dolinoy, Dana C, Herbstman, Julie, Holland, Nina, LaSalle, Janine M, Schmidt, Rebecca, Yousefi, Paul, Perera, Frederica, Joubert, Bonnie R, Wiemels, Joseph, Taylor, Michele, Yang, Ivana V, Chen, Rui, Hew, Kinjal M, Freeland, Deborah M Hussey, Miller, Rachel, Murphy, Susan K, Breton, Carrie V, Breton, Carrie V, Marsit, Carmen J, Faustman, Elaine, Nadeau, Kari, Goodrich, Jaclyn M, Dolinoy, Dana C, Herbstman, Julie, Holland, Nina, LaSalle, Janine M, Schmidt, Rebecca, Yousefi, Paul, Perera, Frederica, Joubert, Bonnie R, Wiemels, Joseph, Taylor, Michele, Yang, Ivana V, Chen, Rui, Hew, Kinjal M, Freeland, Deborah M Hussey, Miller, Rachel, and Murphy, Susan K

Abstract

BackgroundCharacterization of the epigenome is a primary interest for children's environmental health researchers studying the environmental influences on human populations, particularly those studying the role of pregnancy and early-life exposures on later-in-life health outcomes.ObjectivesOur objective was to consider the state of the science in environmental epigenetics research and to focus on DNA methylation and the collective observations of many studies being conducted within the Children's Environmental Health and Disease Prevention Research Centers, as they relate to the Developmental Origins of Health and Disease (DOHaD) hypothesis.MethodsWe address the current laboratory and statistical tools available for epigenetic analyses, discuss methods for validation and interpretation of findings, particularly when magnitudes of effect are small, question the functional relevance of findings, and discuss the future for environmental epigenetics research.DiscussionA common finding in environmental epigenetic studies is the small-magnitude epigenetic effect sizes that result from such exposures. Although it is reasonable and necessary that we question the relevance of such small effects, we present examples in which small effects persist and have been replicated across populations and across time. We encourage a critical discourse on the interpretation of such small changes and further research on their functional relevance for children's health.ConclusionThe dynamic nature of the epigenome will require an emphasis on future longitudinal studies in which the epigenome is profiled over time, over changing environmental exposures, and over generations to better understand the multiple ways in which the epigenome may respond to environmental stimuli.

Published

2017

4. Small-Magnitude Effect Sizes in Epigenetic End Points are Important in Children's Environmental Health Studies: The Children's Environmental Health and Disease Prevention Research Center's Epigenetics Working Group.

Author

Breton, Carrie V, Breton, Carrie V, Marsit, Carmen J, Faustman, Elaine, Nadeau, Kari, Goodrich, Jaclyn M, Dolinoy, Dana C, Herbstman, Julie, Holland, Nina, LaSalle, Janine M, Schmidt, Rebecca, Yousefi, Paul, Perera, Frederica, Joubert, Bonnie R, Wiemels, Joseph, Taylor, Michele, Yang, Ivana V, Chen, Rui, Hew, Kinjal M, Freeland, Deborah M Hussey, Miller, Rachel, Murphy, Susan K, Breton, Carrie V, Breton, Carrie V, Marsit, Carmen J, Faustman, Elaine, Nadeau, Kari, Goodrich, Jaclyn M, Dolinoy, Dana C, Herbstman, Julie, Holland, Nina, LaSalle, Janine M, Schmidt, Rebecca, Yousefi, Paul, Perera, Frederica, Joubert, Bonnie R, Wiemels, Joseph, Taylor, Michele, Yang, Ivana V, Chen, Rui, Hew, Kinjal M, Freeland, Deborah M Hussey, Miller, Rachel, and Murphy, Susan K

Abstract

BackgroundCharacterization of the epigenome is a primary interest for children's environmental health researchers studying the environmental influences on human populations, particularly those studying the role of pregnancy and early-life exposures on later-in-life health outcomes.ObjectivesOur objective was to consider the state of the science in environmental epigenetics research and to focus on DNA methylation and the collective observations of many studies being conducted within the Children's Environmental Health and Disease Prevention Research Centers, as they relate to the Developmental Origins of Health and Disease (DOHaD) hypothesis.MethodsWe address the current laboratory and statistical tools available for epigenetic analyses, discuss methods for validation and interpretation of findings, particularly when magnitudes of effect are small, question the functional relevance of findings, and discuss the future for environmental epigenetics research.DiscussionA common finding in environmental epigenetic studies is the small-magnitude epigenetic effect sizes that result from such exposures. Although it is reasonable and necessary that we question the relevance of such small effects, we present examples in which small effects persist and have been replicated across populations and across time. We encourage a critical discourse on the interpretation of such small changes and further research on their functional relevance for children's health.ConclusionThe dynamic nature of the epigenome will require an emphasis on future longitudinal studies in which the epigenome is profiled over time, over changing environmental exposures, and over generations to better understand the multiple ways in which the epigenome may respond to environmental stimuli.

Published

2017

5. Concordance in hippocampal and fecal Nr3c1 methylation is moderated by maternal behavior in the mouse

Author

Liberman, Shayna A., Mashoodh, Rahia, Thompson, Robert C., Dolinoy, Dana C., Champagne, Frances A., Liberman, Shayna A., Mashoodh, Rahia, Thompson, Robert C., Dolinoy, Dana C., and Champagne, Frances A.

Abstract

Recent advances in genomic technologies now enable a reunion of molecular and evolutionary biology. Researchers investigating naturally living animal populations are thus increasingly able to capitalize upon genomic technologies to connect molecular findings with multiple levels of biological organization. Using this vertical approach in the laboratory, epigenetic gene regulation has emerged as an important mechanism integrating genotype and phenotype. To connect phenotype to population fitness, however, this same vertical approach must now be applied to naturally living populations. A major obstacle to studying epigenetics in noninvasive samples is tissue specificity of epigenetic marks. Here, using the mouse as a proof???of???principle model, we present the first known attempt to validate an epigenetic assay for use in noninvasive samples. Specifically, we compare DNA methylation of the NGFI???A (nerve growth factor???inducible protein A) binding site in the promoter of the glucocorticoid receptor ( Nr3c1 ) gene between central (hippocampal) and peripheral noninvasive (fecal) tissues in juvenile Balb/c mice that had received varying levels of postnatal maternal care. Our results indicate that while hippocampal DNA methylation profiles correspond to maternal behavior, fecal DNA methylation levels do not. Moreover, concordance in methylation levels between these tissues within individuals only emerges after accounting for the effects of postnatal maternal care. Thus, although these findings may be specific to the Nr3c1 gene, we urge caution when interpreting DNA methylation patterns from noninvasive tissues, and offer suggestions for further research in this field. A major obstacle to studying epigenetics in noninvasive samples is tissue specificity of epigenetic marks. Here, we compare DNA methylation of the NGFI???A (nerve growth factor???inducible protein A) binding site in the promoter of the glucocorticoid receptor ( Nr3c1 ) gene between central (hippocampal) a

Published

2013