Your search keyword '"de Vega, Wilfred C."' showing total 11 results

1. Maternal high-fat diet induces sex-specific changes to glucocorticoid and inflammatory signaling in response to corticosterone and lipopolysaccharide challenge in adult rat offspring

Author

Wijenayake, Sanoji, Rahman, Mouly F., Lum, Christine M. W., De Vega, Wilfred C., Sasaki, Aya, and McGowan, Patrick O.

Published

2020

2. Epigenetic impacts of stress priming of the neuroinflammatory response to sarin surrogate in mice: a model of Gulf War illness

Author

Ashbrook, David G., Hing, Benjamin, Michalovicz, Lindsay T., Kelly, Kimberly A., Miller, Julie V., de Vega, Wilfred C., Miller, Diane B., Broderick, Gordon, O’Callaghan, James P., and McGowan, Patrick O.

Published

2018

3. Biological embedding in mental health: an epigenomic perspective

Author

Sasaki, Aya, de Vega, Wilfred C., and McGowan, Patrick O.

Subjects

Mental health -- Genetic aspects, Human genetics -- Research, Epigenetic inheritance -- Observations, Biological sciences

Abstract

Human epidemiological studies and studies of animal models provide many examples by which early life experiences influence health in a long-term manner, a concept known as biological embedding. Such experiences can have profound impacts during periods of high plasticity in prenatal and early postnatal life. Epigenetic mechanisms influence gene function in the absence of changes in gene sequence. In contrast to the relative stability of gene sequences, epigenetic mechanisms appear, at least to some extent, responsive to environmental signals. To date, a few examples appear to clearly link early social experiences to epigenetic changes in pathways relevant for mental health in adulthood. Our recent work using high-throughput epigenomic techniques points to large-scale changes in gene pathways in addition to candidate genes involved in the response to psychosocial stress and neuroplasticity. Elucidation of which pathways are epigenetically labile under what conditions will enable a more complete understanding of how the epigenome can mediate environmental interactions with the genome that are relevant for mental health. In this mini-review, we provide examples of nascent research into the influence of early life experience on mental health outcomes, discuss evidence of epigenetic mechanisms that may underlie these effects, and describe challenges for research in this area. Key words: epigenetics, DNA methylation, early life adversity, psychiatric disorders, animal models. Des etudes epidemiologiques realisees chez l'humain et des etudes portant sur des modeles animaux fournissent plusieurs exemples dans lesquels des experiences vecues tot dans la vie influencent la sante a long terme, un concept connu sous l'appellation de<>. De telles experiences peuvent avoir de profonds impacts durant les periodes de haute plasticite lors de la vie prenatale et tot apres la naissance. Les mecanismes epigenetiques influencent la fonction des genes en absence de changements dans leur sequence. A la difference de la relative stabilite des sequences geniques, les mecanismes epigenetiques semblent, du moins dans une certaine mesure, repondre aux signaux environnementaux. Jusqu'a present, quelques exemples semblent lier clairement des experiences sociales vecues precocement a des changements epigenetiques dans des sentiers pertinents a la sante mentale a l'age adulte. Nos recents travaux realises a l'aide de techniques epigenomiques a haut debit indiquent la presence de changements a grande echelle dans des sentiers geniques en plus des genes candidats impliques dans la reponse au stress psychosocial et la neuroplasticite. De savoir quels sont les sentiers labiles au plan epigenetique et sous quelles conditions ils le sont nous permettra de mieux comprendre comment l'epigenome peut intervenir dans les interactions de l'environnement avec le genome, qui sont pertinentes a la sante mentale. Dans cette mini-revue, nous donnons des exemples de la recherche emergente portant sur les experiences vecues tot dans la vie et leurs consequences sur la sante mentale, nous discutons des donnees qui revelent que des mecanismes epigenetiques peuvent sous-tendre ces effets, et nous decrivons les defis que pose la recherche dans ce domaine. [Traduit par la Redaction] Mots-cles: epigenetique, methylation d'ADN, epreuves vecues dans l'enfance, maladies psychiatriques, modeles animaux., Biological embedding and mental health The concept of biological embedding has gained substantial traction as a framework for understanding the roots of complex multifactorial phenomena in health and disease (McGowan [...]

Published

2013

4. DNA methylation profiles in adults born at extremely low birth weight.

Author

Mathewson, Karen J., McGowan, Patrick O., de Vega, Wilfred C., Van Lieshout, Ryan J., Morrison, Katherine M., Saigal, Saroj, and Schmidt, Louis A.

Subjects

VERY low birth weight, WEIGHT in infancy, DNA methylation, BIRTH weight, PREMATURE labor, METABOLIC regulation

Abstract

Effects of stresses associated with extremely preterm birth may be biologically "recorded" in the genomes of individuals born preterm via changes in DNA methylation (DNAm) patterns. Genome-wide DNAm profiles were examined in buccal epithelial cells from 45 adults born at extremely low birth weight (ELBW; ≤1000 g) in the oldest known cohort of prospectively followed ELBW survivors (Mage = 32.35 years, 17 male), and 47 normal birth weight (NBW; ≥2500 g) control adults (Mage = 32.43 years, 20 male). Sex differences in DNAm profiles were found in both birth weight groups, but they were greatly enhanced in the ELBW group (77,895 loci) versus the NBW group (3,424 loci), suggesting synergistic effects of extreme prenatal adversity and sex on adult DNAm profiles. In men, DNAm profiles differed by birth weight group at 1,354 loci on 694 unique genes. Only two loci on two genes distinguished between ELBW and NBW women. Gene ontology (GO) and network analyses indicated that loci differentiating between ELBW and NBW men were abundant in genes within biological pathways related to neuronal development, synaptic transportation, metabolic regulation, and cellular regulation. Findings suggest increased sensitivity of males to long-term epigenetic effects of extremely preterm birth. Group differences are discussed in relation to particular gene functions. [ABSTRACT FROM AUTHOR]

Published

2022

5. Cumulative risks predict epigenetic age in adult survivors of extremely low birth weight.

Author

Mathewson, Karen J., McGowan, Patrick O., de Vega, Wilfred C., Morrison, Katherine M., Saigal, Saroj, Van Lieshout, Ryan J., and Schmidt, Louis A.

Abstract

Long‐term sequelae of extremely low birth weight (ELBW; ≤1000 g) may contribute to accelerated biological aging. This hypothesis was examined by analyzing a range of risk factors with a molecular age marker in adults born at ELBW or normal birth weight (NBW; ≥2500 g). DNAm age—the weighted average of DNA methylation at 353 cytosine–phosphate–guanine (CpG) sites from across the genome—was derived from a sample of 45 ELBW (Mage = 32.35 years) and 47 NBW control (Mage = 32.44 years) adults, using the Illumina 850k BeadChip Array. At two assessments undertaken 9 years apart (at 23 and 32 years), cumulative risks were summed from six domains with potential to affect physiological and psychological health: resting respiratory sinus arrhythmia, blood pressure, basal cortisol, grip strength, body mass index, and self‐esteem. At age 32 years, cumulative risks were differentially associated with epigenetic age in ELBW survivors (interaction, p < 0.01). For each additional risk factor they possessed, ELBW survivors (B = 1.43) were biologically 2.16 years older than NBW adults (B = –0.73), by the fourth decade of life. Developmental change, epigenetic maintenance, and intervention targets are discussed. [ABSTRACT FROM AUTHOR]

Published

2021

6. Extremely Low Birth Weight and Accelerated Biological Aging.

Author

Van Lieshout, Ryan J., McGowan, Patrick O., de Vega, Wilfred C., Savoy, Calan D., Morrison, Katherine M., Saigal, Saroj, Mathewson, Karen J., and Schmidt, Louis A.

Published

2021

7. Genome-epigenome interactions associated with Myalgic Encephalomyelitis/Chronic Fatigue Syndrome.

Author

Herrera, Santiago, de Vega, Wilfred C., Ashbrook, David, Vernon, Suzanne D., and McGowan, Patrick O.

Published

2018

8. Integration of DNA methylation & health scores identifies subtypes in myalgic encephalomyelitis/chronic fatigue syndrome.

Author

de Vega, Wilfred C., Erdman, Lauren, Vernon, Suzanne D., Goldenberg, Anna, and McGowan, Patrick O.

Published

2018

9. The epigenetic landscape of myalgic encephalomyelitis/chronic fatigue syndrome: deciphering complex phenotypes.

Author

de Vega, Wilfred C and McGowan, Patrick O

Published

2017

10. Epigenetic modifications and glucocorticoid sensitivity in Myalgic Encephalomyelitis/Chronic Fatigue Syndrome (ME/CFS).

Author

de Vega, Wilfred C., Herrera, Santiago, Vernon, Suzanne D., and McGowan, Patrick O.

Subjects

*ADRENOCORTICAL hormones, *EPIGENETICS, *GLUCOCORTICOIDS, *CHRONIC fatigue syndrome

Abstract

Background: Myalgic Encephalomyelitis/Chronic Fatigue Syndrome (ME/CFS) is a debilitating idiopathic disease characterized by unexplained fatigue that fails to resolve with sufficient rest. Diagnosis is based on a list of symptoms and exclusion of other fatigue-related health conditions. Despite a heterogeneous patient population, immune and hypothalamic-pituitary-adrenal (HPA) axis function differences, such as enhanced negative feedback to glucocorticoids, are recurring findings in ME/CFS studies. Epigenetic modifications, such as CpG methylation, are known to regulate long-term phenotypic differences and previous work by our group found DNA methylome differences in ME/CFS, however the relationship between DNA methylome modifications, clinical and functional characteristics associated with ME/CFS has not been examined. Methods: We examined the DNA methylome in peripheral blood mononuclear cells (PBMCs) of a larger cohort of female ME/CFS patients using the Illumina HumanMethylation450 BeadChip Array. In parallel to the DNA methylome analysis, we investigated in vitro glucocorticoid sensitivity differences by stimulating PBMCs with phytohaemagglutinin and suppressed growth with dexamethasone. We explored DNA methylation differences using bisulfite pyrosequencing and statistical permutation. Linear regression was implemented to discover epigenomic regions associated with self-reported quality of life and network analysis of gene ontology terms to biologically contextualize results. Results: We detected 12,608 differentially methylated sites between ME/CFS patients and healthy controls predominantly localized to cellular metabolism genes, some of which were also related to self-reported quality of life health scores. Among ME/CFS patients, glucocorticoid sensitivity was associated with differential methylation at 13 loci. Conclusions: Our results indicate DNA methylation modifications in cellular metabolism in ME/CFS despite a heterogeneous patient population, implicating these processes in immune and HPA axis dysfunction in ME/ CFS. Modifications to epigenetic loci associated with differences in glucocorticoid sensitivity may be important as biomarkers for future clinical testing. Overall, these findings align with recent ME/CFS work that point towards impairment in cellular energy production in this patient population. [ABSTRACT FROM AUTHOR]

Published

2017

11. DNA Methylation Modifications Associated with Chronic Fatigue Syndrome.

Author

de Vega, Wilfred C., Vernon, Suzanne D., and McGowan, Patrick O.

Subjects

*DNA methylation, *CHRONIC fatigue syndrome, *COMPUTATIONAL biology, *EPIGENETICS, *LYMPHOCYTES, *BLOOD cells

Abstract

Chronic Fatigue Syndrome (CFS), also known as myalgic encephalomyelitis, is a complex multifactorial disease that is characterized by the persistent presence of fatigue and other particular symptoms for a minimum of 6 months. Symptoms fail to dissipate after sufficient rest and have major effects on the daily functioning of CFS sufferers. CFS is a multi-system disease with a heterogeneous patient population showing a wide variety of functional disabilities and its biological basis remains poorly understood. Stable alterations in gene function in the immune system have been reported in several studies of CFS. Epigenetic modifications have been implicated in long-term effects on gene function, however, to our knowledge, genome-wide epigenetic modifications associated with CFS have not been explored. We examined the DNA methylome in peripheral blood mononuclear cells isolated from CFS patients and healthy controls using the Illumina HumanMethylation450 BeadChip array, controlling for invariant probes and probes overlapping polymorphic sequences. Gene ontology (GO) and network analysis of differentially methylated genes was performed to determine potential biological pathways showing changes in DNA methylation in CFS. We found an increased abundance of differentially methylated genes related to the immune response, cellular metabolism, and kinase activity. Genes associated with immune cell regulation, the largest coordinated enrichment of differentially methylated pathways, showed hypomethylation within promoters and other gene regulatory elements in CFS. These data are consistent with evidence of multisystem dysregulation in CFS and implicate the involvement of DNA modifications in CFS pathology. [ABSTRACT FROM AUTHOR]

Published

2014