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epigenom

The epigenome (often written epigenom in some languages) refers to the complete set of chemical modifications to the genome and to the associated chromatin structure that regulate gene expression without changing the DNA sequence. It determines how genetic information is read in a given cell or tissue and is essential for development, differentiation, and cellular identity.

Key components of the epigenome include DNA methylation, histone post-translational modifications (such as methylation and acetylation),

Epigenetic states are established during development and can be maintained through cell divisions by maintenance enzymes

Study of the epigenome employs a range of techniques, including bisulfite sequencing for DNA methylation, ChIP-sequencing

Biological and medical relevance is broad: epigenetic mechanisms underpin development, imprinting, X-chromosome inactivation, aging, and cancer,

chromatin
remodeling,
regulatory
non-coding
RNAs,
and
higher-order
three-dimensional
genome
organization.
These
layers
work
together
to
control
when,
where,
and
how
genes
are
expressed,
and
they
are
dynamic
across
development
and
in
response
to
environmental
cues.
and
chromatin-binding
proteins.
Some
epigenetic
marks
can
be
altered
or
reset
in
response
to
stimuli
or
during
germline
reprogramming,
leading
to
changes
in
gene
expression
patterns.
While
most
epigenetic
information
is
cell-type
specific,
some
aspects
can
be
inherited
across
generations
in
limited
contexts.
for
histone
marks,
ATAC-seq
for
chromatin
accessibility,
and
Hi-C
for
3D
genome
architecture.
Epigenome-wide
association
studies
(EWAS)
examine
links
between
epigenetic
patterns
and
traits
or
diseases.
and
are
targets
for
therapies
such
as
DNA
methyltransferase
and
histone
deacetylase
inhibitors,
as
well
as
emerging
epigenome-editing
approaches.