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nitrogenases

Nitrogenases are a family of enzymes that catalyze the reduction of atmospheric dinitrogen (N2) to ammonia (NH3), a key step in biological nitrogen fixation. In nature, nitrogen fixation provides usable nitrogen to ecosystems and supports growth of many plants and microbes. The reactions are carried out by bacteria and archaea, either free-living in soil or aquatic environments, or in symbiotic associations with plants such as legumes.

Most nitrogenases consist of two components: the MoFe protein, which carries the catalytic site for N2 reduction,

Oxygen sensitivity is a defining feature: nitrogenases rapidly inactivate in the presence of O2. In legumes,

Variants: some bacteria possess alternative nitrogenases that use vanadium (V) or iron-only (Fe-only) cofactors when molybdenum

Significance: nitrogenases are central to the global nitrogen cycle and have potential applications in sustainable agriculture

and
the
Fe
protein,
which
transfers
electrons
from
cellular
donors.
The
MoFe
protein
contains
the
FeMo-cofactor
at
its
active
site
and
the
P-cluster
that
connects
to
the
FeMo-co.
The
Fe
protein
harbors
a
[4Fe-4S]
cluster
and
is
coupled
to
flavin
adenine
dinucleotide
(FAD).
Electron
transfer
from
the
Fe
protein
to
the
MoFe
protein
is
driven
by
ATP
hydrolysis,
with
about
8
electrons
and
16
ATP
molecules
consumed
per
N2
reduced
to
two
NH3
(and
H2
is
produced
as
a
byproduct).
nodules
with
leghemoglobin
maintain
a
microaerobic
environment;
in
cyanobacteria,
heterocysts
provide
low-oxygen
conditions.
is
scarce.
These
enzymes
can
also
reduce
N2
though
with
different
efficiencies.
and
biotechnology.