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transdifferentiation

Transdifferentiation, also called direct lineage conversion, is the process by which a mature somatic cell switches from one differentiated identity to another without passing through a pluripotent state. This contrasts with reprogramming to induced pluripotent stem cells. Transdifferentiation can occur in culture or in living tissue and is usually achieved by forcing lineage-determining transcription factors, microRNAs, or epigenetic modifiers to rewire gene networks.

Classical examples include converting B cells to macrophages via C/EBPα; and direct reprogramming of fibroblasts to

Mechanistically, transdifferentiation rewires a cell's regulatory network, often requiring chromatin remodeling and epigenetic changes to suppress

Applications include regenerative medicine and disease modeling, with ongoing research to improve fidelity, safety, and scalability.

induced
cardiomyocytes
using
GATA4,
MEF2C,
TBX5.
Neuronal
conversions
have
been
achieved
by
delivering
ASCL1,
BRN2
and
MYT1L
to
fibroblasts
to
produce
induced
neurons,
with
microRNAs
such
as
miR-124
further
enhancing
efficiency
and
maturation.
In
vivo,
astrocytes
have
been
reprogrammed
into
neurons
in
mouse
models
using
NeuroD1,
among
other
factors,
suggesting
potential
for
tissue
repair.
the
original
program
and
activate
a
new
lineage
program.
The
resulting
cells
may
be
heterogeneous
and
only
partially
mature;
efficiency
is
typically
low
and
protocol-dependent.
Challenges
include
ensuring
stable
identity,
preventing
unintended
cell
fates,
and
avoiding
genetic
or
epigenetic
abnormalities.