Environmental Influences on the Epigenome Lecture 7-8 PDF

Summary

This lecture outlines environmental influences on the epigenome, focusing on key epigenetic regulators such as histone modifications, DNA methylation, and non-coding RNA expression. It also discusses post-translational modifications and their impact on protein functionality.

Full Transcript

Environmental
Influences on
the Epigenome
Lecture 9 & 10
Dr. Hadil Alahdal
Outline
 Introduction
The Epigenome: An Overview Epigenetic machinery
influences gene expression [messenger RNA (mRNA)] and
subsequent protein expression levels but does not alter
primary DNA sequence.
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Epigenetic regulation allows for an immediate organism-
level adaptation to the environment.
Three major epigenetic regulators have been described,
including:
1. Histone modifications,
2. Cytosine phosphate-guanine (CpG) DNA methylation,
3. Noncoding RNA expression.
 Translation
How can change
be introduced at DNA RNA Protein
Add another variation to Proteome
post-translation
level? Proteins way more than genes
This regulation happens through many prosses, for examples:

What are Post Methylation
Acetylation
Translation Phosphorylation

modifications? Glycosylation

This can help in:
Protein folding, stability, localization to cell compartment, function,
activation, interaction etc
 The diversity and complexity of proteins
Post-translational modifications tools
They are chemical modifications that
play a key role in functional proteomics

They regulate activity, localization, and
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interaction with other cellular molecules
such as proteins, nucleic acids, lipids,
and cofactors.

Source: Spoel, S, Journal of Experimental Botany, Vol. 69, No. 19 pp.
4499–4503, 2018
 PTMs increase proteome diversity

Human genome – 21,000 - 22,000 genes,
proteins in the human proteome – over 1
million.
Single genes encode multiple proteins
through the following mechanisms:
1. Genomic recombination,
2. transcription initiation at alternative
promoters,
3. differential transcription
termination,
4. alternative splicing of the transcript.
PTMs further increase the complexity from Source: https://www.thermofisher.com/kz/en/home/life-science/protein-biology/protein-biology-
the level of the genome to the proteome. learning-center/protein-biology-resource-library/pierce-protein-methods/overview-post-
translational-modification.html
Epigenetics
Epigenetics is the study of heritable changes in
gene function that cannot be attributed to
changes to the DNA sequences.
These heritable changes are brought about by
transcriptional processes and post-
transcriptional regulators.
 Epigenetics
Epigenetic mechanisms known to have profound effects on
controlling gene expression include:
DNA methylation - biochemical addition of methyl groups
(CH3) to cytosines in cytosine-phosphate-guanosine (CpG)
dinucleotides that inhibit transcription factors binding to
promoters.
Chromatin remodeling (histone methylation,
acetylation/deacetylation) involves changes to the complex of
histones and DNA packed within the nucleus. The structure of
chromatin affects the accessibility of the chromatin and
transcriptional activities inside a cell.
microRNAs small non-protein coding RNA molecules found in
plants, animals, and some viruses control the target gene
expression post-transcriptionally.
1-DNA methylation
DNA methylation
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Question
How do post-translational modifications like methylation and
phosphorylation impact protein functionality?
 Immediately after DNA replication, each daughter double helix will
DNA contain one methylated DNA strand - inherited from the parent double
helix - and one unmethylated, newly synthesized strand. The maintenance
methyltransferase interacts with these hybrid double helices and
methylation methylates only those CG sequences that are base-paired with a CG
sequence that is already methylated.
is
maintained
 2-Chromatin remodeling-Histone methylation

Histone methylation and
demethylation influence the
availability of DNA for transcription.
Amino acid residues can be conjugated
to a single methyl group or multiple
methyl groups to increase the effects
of modification.

Source: https://cnx.org/contents/5cz8bfb2@11/Eukaryotic-Epigenetic-Gene-Regulation
Acetylation
Acetylation, or the transfer of an acetyl group to nitrogen, occurs in almost all
eukaryotic proteins through both irreversible and reversible mechanisms.
N-terminal acetylation requires the cleavage of the N-terminal methionine by
methionine aminopeptidase (MAP) before replacing the amino acid with an
acetyl group from acetyl-CoA by N-acetyltransferase (NAT) enzymes.
This type of acetylation is co-translational, in that N-terminus is acetylated on
growing polypeptide chains that are still attached to the ribosome. While 80 to
90% of eukaryotic proteins are acetylated in this manner, the exact biological
significance is still unclear.
 3-Chromatin remodeling-Histone
acetylation
Acetylation at the ε-NH2 of lysine (termed lysine
acetylation) on histone N-termini
The histone acetylation and deacetylation is of particular
interest due to its role in gene regulation.
Acetylation occurs on the lysine residue of histone
proteins at the N-terminal tail of lysine and is
facilitated by the enzymes - histone acetylases
(HATs), or histone deacetylases (HDACs).
A single lysine alteration on histones significantly
impacts cellular homeostasis including transcription
factors, molecular chaperones, and cellular
metabolism.
Histone acetylation by the HATs and HDACs has a
well-established link to aging and various
neurological and cardiovascular diseases

Source: https://cnx.org/contents/5cz8bfb2@11/Eukaryotic-Epigenetic-Gene-
Regulation
 Question
What are the three major epigenetic regulators, and how do they
influence gene expression?
3- microRNAs
2-microRNA-directed
destruction of mRNA
Each precursor miRNA transcript is processed to form
a double-stranded intermediate, which is further
processed to form a mature, single-stranded miRNA.
The mature miRNA assembles with a set of proteins
into a complex called RISC, which then searches for
mRNAs that have a nucleotide sequence
complementary to its bound miRNA.
Depending on how extensive the region of
complementarity is, the target mRNA is either rapidly
degraded by a nuclease within the RISC (shown on
the left) or transferred to an area of the cytoplasm
where other nucleases destroy it (shown on the right).
 miRNAs are important epigenetic regulators of gene and protein expression.
miRNAs play a role in developmental processes
miRNAs and miRNAs are susceptible to exposure to environmental chemicals.
environment miRNAs for example are involved in the pathogenesis of pregnancy-related
diseases.
 Question
How does DNA methylation affect gene expression, and what
role does the enzyme DNMT play in this process?
Summary: Epigenetics and the environment
Epigenetics and the environment
Large-scale alterations of processes governing methylation,
due to environmental exposure, nutritional status, or disease,
are associated with global losses or gains of methylation
particularly in early development
Global loss of methylation is generally associated with
genomic instability and is a common phenotype of aging and
cancer
Conversely, gains in global levels of methylation, specifically
in the placenta, have been associated with developmental
defects, including Down syndrome and gestational diabetes
Global measures of methylation are assessed using
technologies such as LINE1, liquid chromatography–mass
spectrometry (LC/MS), and Alu methylation
 Current technologies enable the assessment of site-specific
methylation, in addition to global methylation.
Results of these studies have provided key insights into
disease development and susceptibility due to potentially
causal marks.

Gene-Specific For example, in the mouse study that examined the effects
of environmental contaminants and nutritional
Methylation supplementation on methylation profiles, found that
methylation of the mouse coat color gene, as well as nine
other CpG loci, are linked to adult health and disease
susceptibility.
gene-specific alterations in methylation patterning have
been linked to environmental exposures, especially those
that occur during the prenatal period.
 Gene-Specific Methylation in
human
The study by Heijmans et al. was the first in a human population
to show that alteration of methylation at a single gene locus
resulted in changes to disease susceptibility and adult outcomes.
The researchers investigated the impacts of prenatal exposure to
famine during the Dutch Hunger Winter on insulin growth factor
2 (IGF2) methylation.
This methylation was associated with lowered birth weight and a
predisposition to obesity and adverse metabolic health outcomes
later in life.
These data suggest that alterations to DNA methylation that occur
during the prenatal window result in later-life disease, supporting
the underlying developmental origins of health and disease
hypothesis.
Transcription factors triggered by environmental
exposure influence site-specific methylation
(a) Activation of transcription factors in response to an
environmental contaminant as a mechanism of cellular
defense/adaptation. The binding of the transcription factor
may inhibit DNA methyltransferase (DNMT) from accessing
the DNA for methylation of a particular gene, resulting in
gene-specific hypomethylation.
(b) Repression of transcription factors in response to an
environmental contaminant. The lack of the transcription
factor binding may allow DNMT access to particular
genomic locations, resulting in gene-specific
hypermethylation.
TF, transcription factor; TSS, transcription start site.
 Question
What are some environmental factors that can lead to changes in
DNA methylation?
Some ENVIRONMENTAL TRIGGERS FOR
DNA METHYLATION ALTERATIONS
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1-Aflatoxin B1
 2-Air pollution
Air pollutants encompass a range of environmental exposures, including particulate matter
(PM), ozone, nitrogen oxides, sulfur oxides, carbon monoxide, diesel exhaust fumes, and
toxic chemicals like benzene.
Epigenome studies are showing associations between exposure to air pollution and
changes in DNA methylation levels.
Specific pollutants like PM and ozone composition influence gene-specific methylation
patterns.
PM exposure, is associated with alterations in DNA methylation of specific genes related
to blood pressure regulation, inflammation, and other biological processes.
Traffic-related air pollution can influence methylation at the tet methylcytosine
dioxygenase 1 (TET1) gene, affecting gene expression.
Prenatal exposure to air pollution affects methylation patterns differently depending on the
timing of exposure during pregnancy.
Specific genes related to immune response, metabolism, and vascular development are
affected by prenatal air pollution exposure.
DNA methylation alterations in peripheral blood related to air pollution is more sever
during the prenatal period and childhood.
 3-Arsenic
1. Arsenic exposure affects hundreds of millions of people worldwide.
2. Associated with altered methylation patterns in adults and infants,
resulting in hypomethylation and hypermethylation.
3. Recent research indicates that the effects of arsenic on DNA
methylation may vary by sex, with positive associations in males and
negative associations in females.
4. Several studies have examined gene-specific DNA methylation
changes in adults and infants exposed to arsenic, with most findings
indicating hypermethylation.
5. Some specific genes have been associated with health outcomes
related to arsenic exposure, such as lower birth weight, cancer, and
diabetes.
6. The literature suggests that arsenic-associated methylation may
contribute to genomic instability and the development of arsenic-
related diseases, both in cases of prenatal and chronic exposure.
 4-Bisphenol-A
1. BPA is a public health concern due to its widespread exposure and unclear
health effects.
2. Research indicates that BPA induces hypomethylation in women and young
girls, but its effects on males are unclear.
3. Fetal exposure to BPA is associated with nonmonotonic changes in DNA
methylation in the liver.
4. BPA alters methylation patterns in various tissues, including the placenta, fetal
liver, and fetal kidney.
5. Specific genes affected by BPA include the small nucleolar RNA (SNORD)
complex, sulfotransferase family 2A member 1 (SULT2A1), and catechol-O-
methyltransferase (COMT).
6. BPA can induce hypomethylation of CpG targets on the X chromosome and
affect methylation related to immune function, transport activity, and metabolism.
 5-Tobacco smoke
1. Tobacco smoke is a known carcinogen and is associated with
cardiovascular disease and chronic respiratory conditions.
2. Tobacco smoke exposure can lead to genomic instability and
dysregulation of the epigenome.
3. Both in utero and adult exposures to tobacco smoke have been
linked to global hypomethylation.
4. Tobacco smoke exposure also impacts genes related to cancer, cell
cycle, metabolism, fetal growth restriction, development, and more.
5. Common genes affected by prenatal tobacco smoke exposure
include Contactin-associated protein-like 2 (CNTNAP2), cytochrome
P450, family 1, member A1 (CYP1A1), and myosin IG (MYO1G).
6. DNA methylation patterns affected by tobacco smoke exposure
remain stable over time.
6-Nutritional Factors
1. Early-life and prenatal nutrition can impact developmental programming and later-
life health outcomes.
2. nutrient donors like methionine, folate, betaine, and choline are linked to
alterations in DNA methylation patterns, increasing global methylation levels and
deficiency causing hypomethylation.
3. Folate, an essential nutrient for fetal development, is associated with global
methylation measures in infants, children, and adults.
4. The relationship between methylation and methyl donors is significant during the
third trimester of pregnancy.
5. Paternal intake of methyl donor nutrients influences global methylation in
offspring and affects infant metabolism and growth.
6. Specific loci in the genome, are influenced by nutritional factors and are linked to
later-life health issues such as obesity and diabetes.
7. Good nutrition can moderate the effects of environmental contaminant exposure.
8. Micronutrients like vitamin B family members, homocysteine, choline, vitamin
B12, vitamin D, and selenium, are critical for methylation status.
 Question
What are the major gaps in epigenetics research, and how might
addressing these improve our understanding of gene regulation?
 Future directions
Four Major Gaps:
1. Environmental Mixtures:
Nutritional assessment and the assessment of multiple contaminants are necessary to
advance the field.
2. Sex-Specific Effects:
Differences in methylation patterns between males and females can affect health
outcomes and should be considered in future studies.
3. Tissue Specificity:
While blood-based methylation is often used as a biomarker for disease, it is
important to study specific target tissues and examine tissue-specific changes in
methylation marks.
4. Stability and Functional Consequences:
Limited research has assessed the stability of methylation over time and its
functional consequences. Longitudinal studies with measures of methylation and
gene expression are needed to address this gap.
 Conclusion
There is a dynamic relationship
between environmental influences
and the epigenome, through
exposure-associated DNA
methylation
This field of research has important
implications for understanding the
impact of our environment on health
and may lead to innovative strategies
for disease prevention and
personalized medicine.
References
https://www.annualreviews.org/doi/pdf/10.1146/annurev-publhealth-
040617-014629
https://www.sciencedirect.com/science/article/pii/S2214750020303644
https://www.frontiersin.org/articles/10.3389/fgene.2021.664717/full
https://www.sciencedirect.com/science/article/abs/pii/S002432051830
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