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nitrogenase

Nitrogenase is an enzyme complex that catalyzes the conversion of atmospheric nitrogen (N2) to ammonia (NH3), a form usable for biosynthesis. This biological nitrogen fixation is carried out by certain bacteria and archaea, including free-living diazotrophs and symbiotic partners such as rhizobia in legume roots. The reaction is energetically demanding and highly oxygen-sensitive.

Most well-studied nitrogenases are the molybdenum (Mo) nitrogenases, which consist of two component proteins: dinitrogenase (the

Mechanistically, electrons are donated from an electron donor to the Fe protein, which transfers them to the

In addition to Mo-dependent nitrogenases, some organisms possess alternative nitrogenases containing vanadium (V) or iron only

Nitrogenase is highly sensitive to oxygen, which inhibits its activity. Diazotrophs employ various strategies, such as

MoFe
protein)
and
dinitrogenase
reductase
(the
Fe
protein).
The
MoFe
protein
is
a
heterotetramer
containing
the
active
site
FeMo-cofactor,
a
complex
metal
cluster
where
N2
binding
and
reduction
occur.
The
Fe
protein
is
a
homodimer
that
contains
a
[4Fe-4S]
cluster
and
provides
electrons
to
the
MoFe
protein
in
an
ATP-dependent
manner.
MoFe
protein
with
the
consumption
of
ATP.
The
overall
electron
flow
reduces
N2
at
the
FeMo-cofactor
to
NH3,
with
H2
produced
as
a
by-product.
The
overall
stoichiometry
is
N2
+
8
H+
+
8
e-
+
16
ATP
→
2
NH3
+
H2
+
16
ADP
+
16
Pi,
reflecting
the
energy-intensive
nature
of
the
process.
(Fe-only)
cofactors
(vnf
and
anf
gene
clusters).
These
variants
operate
under
Mo
limitation
and
have
different
metal
cofactors
and
somewhat
different
properties
but
accomplish
the
same
overall
goal
of
reducing
N2
to
NH3.
microaerobic
conditions
or
specialized
cell
types,
to
protect
the
enzyme
during
nitrogen
fixation.