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nata

NatA is a major protein N-terminal acetyltransferase complex in eukaryotes that catalyzes the N-terminal acetylation of nascent polypeptides as they emerge from the ribosome. In humans, the core complex comprises the catalytic subunit NAA10 and the auxiliary subunit NAA15; in other organisms, such as yeast, the equivalent complex is known as Ard1–Nat1. NatA associates with ribosomes and acts co-translationally to modify a large portion of newly synthesized proteins.

The activity of NatA depends on the initiator methionine being removed from many substrates. After methionine

NatA function is regulated through interactions with other proteins. The NatA complex can associate with chaperone-like

Biological significance and disease associations include effects on protein stability, localization, and interactions, with implications for

aminopeptidase
cleavage,
NatA
preferentially
acetylates
N-termini
that
begin
with
small,
uncharged
residues,
including
Ser,
Ala,
Thr,
Val,
Gly,
and
Cys.
This
specificity
distinguishes
NatA
from
other
N-terminal
acetyltransferases
that
target
different
N-terminal
sequences.
NatA’s
substrate
range
contributes
to
broad
effects
on
protein
function
and
fate.
factors
such
as
HYPK,
which
can
modulate
activity,
and
it
may
interact
with
additional
subunits
or
factors
in
various
organisms
to
influence
substrate
scope
and
efficiency.
In
some
contexts,
auxiliary
enzymes
can
extend
or
alter
the
acetylation
pattern
of
NatA
substrates.
development
and
signaling
pathways.
Mutations
in
NAA10
or
NAA15
have
been
linked
to
developmental
disorders;
notably,
certain
NAA10
variants
cause
Ogden
syndrome,
a
severe
X-linked
condition.
NatA’s
activity
and
regulation
are
active
areas
of
research
due
to
their
widespread
influence
on
the
proteome.