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demethylases

Demethylases are enzymes that remove methyl groups from substrates such as nucleic acids and proteins, thereby altering their function and regulation. They participate in epigenetic control, RNA processing, and metabolic signaling by reversing methylation marks that accumulate on DNA, histones, and RNA.

Histone demethylases fall into two main families. The LSD1/2 family (KDM1A/B) is FAD-dependent and can remove

DNA demethylation involves TET enzymes that oxidize 5-methylcytosine to 5-hydroxymethylcytosine and further oxidation products, with subsequent

RNA demethylases, such as FTO and ALKBH5, erase methyl marks from RNA nucleotides, notably N6-methyladenosine (m6A).

Implications: Demethylases are key players in development, stem-cell biology, and cancer. Abnormal activity can contribute to

mono-
and
di-methyl
groups
from
certain
lysine
residues
on
histones
(for
example
H3K4me1/2
or
H3K9me1/2).
The
JmjC-domain
demethylases
(KDM2–KDM7)
are
Fe(II)/α-ketoglutarate-dependent
dioxygenases
that
hydroxylate
methylated
lysines,
enabling
demethylation
across
multiple
histone
marks.
These
enzymes
regulate
gene
expression,
development,
differentiation,
and
DNA
repair.
base-excision
repair
replacing
modified
cytosines
by
unmethylated
cytosine.
Though
not
a
direct
removal
of
a
methyl
group,
this
pathway
achieves
active
DNA
demethylation
and
requires
Fe(II)
and
α-ketoglutarate.
This
epitranscriptomic
regulation
affects
mRNA
stability,
splicing,
and
translation,
linking
RNA
methylation
status
to
gene
expression
outcomes.
oncogenesis
and
neurological
disorders.
Researchers
use
chemical
inhibitors
and
genetic
tools
to
study
demethylase
function;
some
inhibitors
have
been
explored
for
potential
therapeutic
applications.