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In vivo metabolic flux profiling with stable isotopes discriminates sites and quantifies effects of mitochondrial dysfunction in C. elegans.
[pyruvate dehydrogenase deficiency]
Mitochondrial
respiratory
chain
(
RC
)
disease
diagnosis
is
complicated
both
by
an
absence
of
biomarkers
that
sufficiently
divulge
all
cases
and
limited
capacity
to
quantify
adverse
effects
across
intermediary
metabolism
.
We
applied
high
performance
liquid
chromatography
(
HPLC
)
and
mass
spectrometry
(
MS
)
studies
of
stable-isotope
based
precursor-product
relationships
in
the
nematode
,
C
.
elegans
,
to
interrogate
in
vivo
differences
in
metabolic
flux
among
distinct
genetic
models
of
primary
RC
defects
and
closely
related
metabolic
disorders
.
C
.
elegans
strains
studied
harbor
single
nuclear
gene
defects
in
complex
I
,
II
,
or
III
RC
subunits
(
gas-
1
,
mev-
1
,
isp-
1
)
;
enzymes
involved
in
coenzyme
Q
biosynthesis
(
clk-
1
)
,
the
tricarboxylic
acid
cycle
(
TCA
,
idh-
1
)
,
or
pyruvate
metabolism
(
pdha-
1
)
;
and
central
nodes
of
the
nutrient-sensing
signaling
network
that
involve
insulin
response
(
daf-
2
)
or
the
sirtuin
homologue
(
sir-
2
.
1
)
.
Synchronous
populations
of
2000
early
larval
stage
worms
were
fed
standard
Escherichia
coli
on
nematode
growth
media
plates
containing
1
,
6
-
(
13
)
C
2
-
glucose
throughout
their
developmental
period
,
with
samples
extracted
on
the
first
day
of
adult
life
in
4
%
perchloric
acid
with
an
internal
standard
.
Quantitation
of
whole
animal
free
amino
acid
concentrations
and
isotopic
incorporation
into
amino
and
organic
acids
throughout
development
was
performed
in
all
strains
by
HPLC
and
isotope
ratio
MS
,
respectively
.
GC
/
MS
analysis
was
also
performed
to
quantify
absolute
isotopic
incorporation
in
all
molecular
species
of
key
TCA
cycle
intermediates
in
gas-
1
and
N
2
adult
worms
.
Genetic
mutations
within
different
metabolic
pathways
displayed
distinct
metabolic
profiles
.
RC
complex
I
(
gas-
1
)
and
III
(
isp-
1
)
subunit
mutants
,
together
with
the
coenzyme
Q
biosynthetic
mutant
(
clk-
1
)
,
shared
a
similar
amino
acid
profile
of
elevated
alanine
and
decreased
glutamate
.
The
metabolic
signature
of
the
complex
II
mutant
(
mev-
1
)
was
distinct
from
that
of
the
other
RC
mutants
but
resembled
that
of
the
TCA
cycle
mutant
(
idh-
1
)
and
both
signaling
mutants
(
daf-
2
and
sir-
2
.
1
)
.
All
branched
chain
amino
acid
levels
were
significantly
increased
in
the
complex
I
and
III
mutants
but
decreased
in
the
PDH
mutant
(
pdha-
1
)
.
The
RC
complex
I
,
coenzyme
Q
,
TCA
cycle
,
and
PDH
mutants
shared
significantly
increased
relative
enrichment
of
lactate
+
1
and
absolute
concentration
of
alanine
+
1
,
while
glutamate
+
1
enrichment
was
significantly
decreased
uniquely
in
the
RC
mutants
.
Relative
intermediary
flux
analyses
were
suggestive
of
proximal
TCA
cycle
disruption
in
idh-
1
,
completely
reduced
TCA
cycle
flux
in
sir-
2
.
1
,
and
apparent
distal
TCA
cycle
alteration
in
daf-
2
.
GC
/
MS
analysis
with
universally-labeled
(
13
)
C-
glucose
in
adult
worms
further
showed
significantly
increased
isotopic
enrichment
in
lactate
,
citrate
,
and
malate
species
in
the
complex
I
(
gas-
1
)
mutant
.
S
table
isotopic
/
mass
spectrometric
analysis
can
sensitively
discriminate
primary
RC
dysfunction
from
genetic
deficiencies
affecting
either
the
TCA
cycle
or
pyruvate
metabolism
.
These
data
are
further
suggestive
that
metabolic
flux
analysis
using
stable
isotopes
may
offer
a
robust
means
to
discriminate
and
quantify
the
secondary
effects
of
primary
RC
dysfunction
across
intermediary
metabolism
.
Diseases
Validation
Diseases presenting
"high performance"
symptom
alpha-thalassemia
benign recurrent intrahepatic cholestasis
canavan disease
cystinuria
familial hypocalciuric hypercalcemia
neonatal adrenoleukodystrophy
pyruvate dehydrogenase deficiency
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