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riboswitch

Riboswitches are regulatory segments of an mRNA that bind small metabolites to control gene expression. They consist of two main parts: an aptamer domain that binds a specific ligand, and an expression platform that translates the binding event into a change in gene expression. Most riboswitches are located in the 5' untranslated region of the mRNA they regulate and control genes involved in the synthesis, transport, or metabolism of the ligand.

Mechanistically, riboswitches act through conformational changes in the mRNA. In the absence of the ligand, the

Riboswitches are widespread in bacteria and archaea and have also been found in some plants and fungi.

Research into riboswitches has provided insights into RNA structure and gene regulation and has implications for

transcript
can
adopt
structures
that
allow
transcription
to
continue
or
translation
to
begin.
When
the
ligand
binds
the
aptamer,
the
RNA
folds
into
an
alternative
structure
that
typically
either
forms
a
transcription
terminator
hairpin,
causing
premature
transcription
termination,
or
sequesters
the
ribosome
binding
site,
reducing
translation.
Some
riboswitches
influence
mRNA
stability
or
splicing,
particularly
in
eukaryotes.
They
regulate
a
range
of
essential
pathways
by
sensing
metabolites
such
as
vitamins
and
nucleotides.
Well-characterized
examples
include
the
thiamine
pyrophosphate
(TPP)
riboswitch,
which
responds
to
vitamin
B1
derivatives;
the
glycine
and
lysine
riboswitches;
and
the
fluoride
riboswitch,
which
detects
fluoride
ions.
synthetic
biology
and
antimicrobial
design,
given
their
central
role
in
metabolic
regulation
and
their
reliance
on
RNA-based
control
mechanisms.