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protonpompen

Protonpompen are membrane-embedded protein complexes that actively transport protons (H+) across biological membranes, typically against their electrochemical gradient. By moving protons, these pumps create and maintain a proton motive force, a combination of a proton concentration gradient and a membrane potential that energizes a variety of cellular processes.

Protonpompen occur in many organisms and cellular compartments. In mitochondria and chloroplasts, protonpompen of the respiratory

Mechanistically, primary active protonpompen hydrolyze ATP to move protons across membranes. The resulting proton motive force

Clinical and practical relevance includes the use of proton pump inhibitors to treat acid-related disorders, and

and
photosynthetic
electron
transport
chains
pump
H+
across
membranes
to
generate
a
gradient
used
by
ATP
synthase
to
produce
ATP.
In
bacteria,
similar
proton
translocation
across
the
plasma
membrane
drives
energy
production.
In
plant
and
fungal
cells,
plasma
membrane
H+-ATPases
expel
protons
to
acidify
the
exterior,
supporting
nutrient
uptake
and
pH
homeostasis.
Vacuoles,
lysosomes
and
other
organelles
can
be
acidified
by
V-type
H+-ATPases,
which
regulate
vesicle
trafficking
and
organelle
function.
The
gastric
proton
pump,
H+/K+-ATPase,
secretes
acid
into
the
stomach
lumen
and
is
a
major
target
of
acid-suppressive
drugs.
can
drive
ATP
synthesis
in
chloroplasts
and
mitochondria,
or
power
secondary
transport
processes
and
other
energy-dependent
activities
in
cells.
ongoing
research
into
the
structure
and
regulation
of
these
pumps
for
therapeutic
and
biotechnological
applications.
The
concept
of
protonpompen
and
their
role
in
bioenergetics
is
closely
linked
to
the
chemiosmotic
theory
proposed
by
Peter
Mitchell
in
1961.