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crosssubstrate

Crosssubstrate is a term used in several scientific disciplines to describe interactions among substrates that share a processing system, such as an enzyme, transporter, or catalytic surface, whereby the presence, concentration, or metabolism of one substrate influences the fate of another. It encompasses phenomena including substrate competition, cross-reactivity, and metabolic cross-talk, where multiple substrates can affect each other’s conversion rates, binding, or transport.

In enzymology and biochemistry, crosssubstrate effects arise when an enzyme exhibits substrate promiscuity, accepting more than

Mechanisms commonly associated with crosssubstrate phenomena include competitive binding, allosteric modulation, product inhibition, and transporter-level competition.

Understanding crosssubstrate effects is important for optimizing biocatalysis, fermentation, and sensor design, as well as for

one
chemically
related
substrate,
or
when
substrates
compete
for
the
same
active
site
or
cofactor.
In
metabolic
engineering
and
microbiology,
transporters
and
regulatory
networks
can
create
cross-substrate
inhibition
or
synergy,
altering
uptake
rates
and
flux
through
pathways
when
cells
are
exposed
to
mixed
carbon
or
nitrogen
sources.
In
materials
science
and
catalysis,
shared
surfaces
or
catalysts
may
process
different
substrates,
leading
to
cross-substrate
poisoning,
cooperative
effects,
or
sequential
reaction
pathways.
Characterizing
crosssubstrate
interactions
often
requires
kinetic
studies,
substrate
specificity
assays,
and
systems-level
analyses
to
distinguish
direct
enzymatic
effects
from
network-level
regulation.
predicting
metabolic
responses
to
mixed
substrates.
Strategies
to
manage
crosssubstrate
interactions
include
substrate
feeding
regimes,
enzyme
engineering
to
adjust
specificity,
and
compartmentalization
of
pathways
to
reduce
unintended
cross-talk.