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ferritine

Ferritin, sometimes referred to as ferritine in some languages, is a ubiquitous intracellular protein complex that stores iron and releases it in a controlled manner. It forms a hollow nanocage capable of sequestering up to about 4,500 iron atoms as ferrihydrite. By buffering cellular iron, ferritin helps prevent iron-catalyzed oxidative damage and maintains iron homeostasis.

In vertebrates, ferritin is a 24-subunit complex composed of heavy (H) and light (L) chains. The H

Ferritin is present in most cell types, with particularly high levels in the liver, spleen, and bone

Clinically, serum ferritin measurement is a common test for assessing iron status. Low ferritin indicates iron

subunit
provides
ferroxidase
activity
that
converts
Fe2+
to
Fe3+,
initiating
mineralization;
the
L
subunit
supports
long-term
storage
and
nucleation
of
iron.
The
shell
interior
is
mineralized
with
ferrihydrite,
while
the
exterior
surface
permits
iron
exchange
through
channels.
The
relative
abundance
of
H
and
L
subunits
varies
by
tissue
and
physiological
conditions.
marrow.
Cytosolic
ferritin
is
the
main
form,
though
a
mitochondrial
ferritin
(FTMT)
exists
in
some
cells.
Serum
ferritin
largely
reflects
body
iron
stores
but
is
also
an
acute-phase
protein
that
can
rise
with
inflammation,
infection,
or
liver
disease
independent
of
iron
status.
Its
synthesis
is
regulated
by
iron
regulatory
proteins
binding
to
iron-responsive
elements
in
its
mRNA,
linking
production
to
cellular
iron
availability.
deficiency;
very
high
ferritin
can
indicate
iron
overload
or
inflammatory
states.
Because
ferritin
can
be
elevated
during
inflammation,
interpretation
often
considers
C-reactive
protein
and
other
iron
indices
such
as
transferrin
saturation.
See
also:
iron
metabolism,
ferritin
heavy
chain,
ferritin
light
chain,
ferritinophagy,
ferroptosis.