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stemness

Stemness describes the collection of traits that enable a cell to behave as a stem cell. Central to stemness are self-renewal, the capacity to undergo numerous cycles of cell division while maintaining an undifferentiated state, and potency, the ability to generate multiple cell lineages or tissue types. In development and tissue homeostasis, stemness allows stem cells to replenish lost cells and contribute to organ formation.

Molecularly, stemness is associated with a transcriptional network that includes master regulators such as OCT4 (POU5F1),

Assessment typically relies on functional tests of self-renewal and multipotency, such as serial transplantation or colony/sphere

Stemness is not an intrinsic, immutable property. It is context-dependent and influenced by the stem cell niche,

Because stemness reflects a spectrum of capabilities rather than a binary state, its assessment is subject

SOX2,
and
NANOG
in
many
systems,
along
with
tissue-specific
factors.
Epigenetic
features
such
as
open
chromatin
at
stemness
genes
and
often
bivalent
histone
marks
prime
cells
for
differentiation.
Stemness
is
also
linked
to
metabolic
and
cell-cycle
features
that
support
long-term
self-renewal.
formation
assays,
in
addition
to
profiling
surface
markers
and
transcriptional
signatures.
Markers
vary
by
tissue;
for
example,
hematopoietic
stem
cells
express
CD34
and
RUNX1,
while
neural
and
epithelial
stem
cells
have
distinct
profiles.
In
cancer,
subpopulations
with
stemness
traits—cancer
stem
cells—are
proposed
to
drive
tumor
growth,
metastasis,
and
drug
resistance.
signaling
pathways
including
WNT,
Notch,
Hedgehog,
FGF,
and
TGF-β,
and
cellular
metabolism.
The
concept
also
encompasses
the
ability
of
differentiated
cells
to
reacquire
stem-like
features
through
reprogramming
or
dedifferentiation,
which
underpins
induced
pluripotent
stem
cell
technology.
to
methodological
differences
and
biological
variability.
Nevertheless,
understanding
stemness
is
central
to
development,
regenerative
medicine,
and
oncology.