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fosfatas

Fosfatas (phosphatases) are enzymes that catalyze the hydrolysis of phosphate esters, releasing inorganic phosphate. By removing phosphate groups, they regulate phosphorylation-dependent signaling and metabolism across organisms, including bacteria, plants, and animals. Fosfatas can be intracellular, membrane-associated, or secreted, and several lysosomal and extracellular forms exist.

Phosphatases are commonly categorized by their pH optima into acid phosphatases and alkaline phosphatases. Alkaline phosphatases

Mechanism and regulation: Many phosphatases require metal cofactors (such as Mg2+ or Zn2+) and use catalytic

Clinical and laboratory relevance: Phosphatase activity is routinely measured using substrates such as p-nitrophenyl phosphate in

function
best
in
neutral
to
alkaline
environments
and
participate
in
mineralization
and
bone
turnover
(for
example,
tissue-nonspecific
alkaline
phosphatase).
Acid
phosphatases
operate
optimally
in
acidic
environments,
such
as
lysosomes,
and
include
enzymes
involved
in
intracellular
turnover
and
degradation.
Protein
phosphatases
comprise
major
families
such
as
serine/threonine
phosphatases
(PP1,
PP2A,
PP2B/calcineurin)
and
protein
tyrosine
phosphatases
(PTPs);
other
families
include
metal-dependent
phosphatases
and
dual-specificity
phosphatases.
residues
like
serine,
cysteine,
or
aspartate.
Enzyme
activity
is
tightly
controlled
by
regulatory
subunits,
inhibitors,
post-translational
modifications,
and
cellular
localization,
enabling
precise
modulation
of
signaling
networks.
clinical
labs.
Alkaline
phosphatase
isoenzymes
help
distinguish
liver
from
bone
disease,
and
elevated
ALP
levels
can
indicate
bone
growth,
cholestasis,
or
liver
pathology.
Prostatic
acid
phosphatase
was
historically
used
as
a
cancer
marker,
though
its
use
has
declined.
Abnormal
phosphatase
activity
is
associated
with
metabolic
disorders,
cancer,
and
neurodegenerative
diseases.