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Nutriepigenetics and cardiovascular disease.

Current opinion in clinical nutrition and metabolic care
July 1, 2018
Anastasia Z Kalea et al. (3 authors)
Journal ArticleResearch Support, N.I.H., ExtramuralResearch Support, Non-U.S. Gov'tReviewHuman StudyMolecular Study
Study Details

Study Goal

The researchers aimed to explore how a high-fat diet influences epigenetic alterations linked to cardiovascular disease and the potential of dietary interventions to counteract these effects.

Results Summary

The study found that a high-fat diet can negatively impact DNA methylation, histone modifications, and contribute to cardiovascular risk factors like inflammation and oxidative stress. It also suggested that certain bioactive compounds and dietary patterns, such as the Mediterranean diet, may mitigate these effects.

Population

Not specified (general discussion of mechanisms in cell culture, animal models, and human studies).

Effective Dosage

Not specified

Duration

Not specified

Interactions

None mentioned

Extracted Claims (19)
InterventionDirectionEndpointPopulationDosageImpactClaim #
surplus of macronutrients such as in a high-fat diet
neutral
activity of DNA methyltransferases and histone-modifying enzymes
-
-
can affect
#1
surplus of macronutrients such as in a high-fat diet
neutral
foetal growth
-
-
can affect
#2
surplus of macronutrients such as in a high-fat diet
neutral
glucose/lipid metabolism
-
-
can affect
#3
surplus of macronutrients such as in a high-fat diet
neutral
oxidative stress
-
-
can affect
#4
surplus of macronutrients such as in a high-fat diet
neutral
inflammation
-
-
can affect
#5
surplus of macronutrients such as in a high-fat diet
neutral
atherosclerosis
-
-
can affect
#6
deficiencies of specific nutrients such as folate and other B-vitamins
neutral
activity of DNA methyltransferases and histone-modifying enzymes
-
-
can affect
#7
deficiencies of specific nutrients such as folate and other B-vitamins
neutral
foetal growth
-
-
can affect
#8
deficiencies of specific nutrients such as folate and other B-vitamins
neutral
glucose/lipid metabolism
-
-
can affect
#9
deficiencies of specific nutrients such as folate and other B-vitamins
neutral
oxidative stress
-
-
can affect
#10
deficiencies of specific nutrients such as folate and other B-vitamins
neutral
inflammation
-
-
can affect
#11
deficiencies of specific nutrients such as folate and other B-vitamins
neutral
atherosclerosis
-
-
can affect
#12
polyphenols (resveratrol, curcumin)
increase
deacetylases Sirtuins (SIRTs)
-
-
may activate
#13
polyphenols (resveratrol, curcumin)
increase
histone deacetylases or acetyltransferases
-
-
may activate
#14
polyphenols (resveratrol, curcumin)
increase
response of inflammatory mediators
-
-
may activate
#15
epigallocatechin
increase
deacetylases Sirtuins (SIRTs)
-
-
may activate
#16
epigallocatechin
increase
histone deacetylases or acetyltransferases
-
-
may activate
#17
epigallocatechin
increase
response of inflammatory mediators
-
-
may activate
#18
Adherence to cardioprotective dietary patterns, such as the Mediterranean diet (MedDiet)
neutral
genes related to inflammation and immuno-competence
-
-
has been associated with altered methylation and expression
#19
Abstract

PURPOSE OF REVIEW: We present a current perspective of epigenetic alterations that can lead to cardiovascular disease (CVD) and the potential of dietary factors to counteract their actions. In addition, we discuss the challenges and opportunities of dietary treatments as epigenetic modifiers for disease prevention and therapy. RECENT FINDINGS: Recent epigenome-wide association studies along with candidate gene approaches and functional studies in cell culture and animal models have delineated mechanisms through which nutrients, food compounds and dietary patterns may affect the epigenome. Several risk factors for CVD, including adiposity, inflammation and oxidative stress, have been associated with changes in histone acetylation, lower global DNA methylation levels and shorter telomere length. A surplus of macronutrients such as in a high-fat diet or deficiencies of specific nutrients such as folate and other B-vitamins can affect the activity of DNA methyltransferases and histone-modifying enzymes, affecting foetal growth, glucose/lipid metabolism, oxidative stress, inflammation and atherosclerosis. Bioactive compounds such as polyphenols (resveratrol, curcumin) or epigallocatechin may activate deacetylases Sirtuins (SIRTs), histone deacetylases or acetyltransferases and in turn the response of inflammatory mediators. Adherence to cardioprotective dietary patterns, such as the Mediterranean diet (MedDiet), has been associated with altered methylation and expression of genes related to inflammation and immuno-competence. SUMMARY: The mechanisms through which nutrients and dietary patterns may alter the cardiovascular epigenome remain elusive. The research challenge is to determine which of these nutriepigenetic effects are reversible, so that novel findings translate into effective dietary interventions to prevent CVD or its progression.

Medical Subject Headings (MeSH)
AcetylationAnimalsCardiovascular DiseasesDNA MethylationDietEpigenesis, GeneticGroup III Histone DeacetylasesHistonesHumansInflammationNutritional StatusPolyphenolsProtein Processing, Post-Translational
Study Links
Quality Scores
SafetyNot Assessed
Efficacy30/10
Quality75/10
Citation Metrics
Total Citations33
Citations/Year4.7
Relative Citation Ratio1.51
NIH Percentile65.4%
Research Impact Scores
APT Score0.50
Weight Score1.06
Normalized Score0.47
Related Supplements
Nutriepigenetics and cardiovascular disease. | Panacea Index