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fosfodiester

Fosfodiester, commonly referred to as the phosphodiester bond, is the covalent linkage that connects nucleotides within nucleic acids. In DNA and RNA, a phosphodiester bond forms between the 5' phosphate group of one nucleotide and the 3' hydroxyl group of the next, creating the sugar-phosphate backbone that runs in a 5' to 3' direction.

Chemically, a phosphodiester bond involves a phosphorus atom bound to two sugar-derived esters. The bond is

Phosphodiester bonds are relatively stable under normal cellular conditions but can be hydrolyzed by nucleases, including

The phosphodiester backbone imparts directionality to nucleic acids and is essential for the replication, transcription, and

See also: nucleic acids, nucleotides, phosphodiesterase.

formed
by
a
condensation
reaction
during
nucleotide
polymerization,
typically
driven
by
enzymes
such
as
DNA
or
RNA
polymerases
and,
in
cells,
coupled
to
the
hydrolysis
of
nucleoside
triphosphates.
The
resulting
backbone
is
highly
negatively
charged
at
physiological
pH
due
to
the
phosphate
groups.
DNases
and
RNases,
or
under
acidic
or
basic
conditions.
Cleavage
produces
fragments
with
5'
phosphate
and
3'
hydroxyl
ends,
a
property
exploited
in
processes
such
as
DNA
sequencing
and
RNA
processing.
translation
machinery
of
cells.
In
biotechnology,
synthetic
oligonucleotides
are
manufactured
with
phosphodiester
linkages,
though
these
can
be
chemically
modified
(for
example,
to
phosphorothioate
bonds)
to
improve
stability
for
therapeutic
or
diagnostic
applications.