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Nuclear and cytoplasmic glutamate dehydrogenases (NADP-dependent) in Saccharomyces cerevisiae
BIOCHEMICAL
Vol. 64, No. 2, 1975
AND BIOPHYSICAL
RESEARCH COMMUNICATIONS
NUCLEAR AND CYTOPLASMIC GLUTAMATE DEHYDROGENASES (NADP-DEPENDENT) IN SACCHAROMYCES CEREVISIAE Laura
Camardella,
Guido
International
Institute Marconi
Via
Received
April
4,
di Prisco,
Felice
Garofano
and Anna Maria
of Genetics and Biophysics, 10, 80125 Naples, Italy
Guerrini
CNR,
1975 SUMMARY
The intracellular localization of NADP-dependent glutamate dehydrogehase has been studied in Saccharomyces cerevisiae. has been found to be associated Beside cytoplasmic GDH, enzyme activity with the nuclear fraction in amounts comparable to those reported in nuclei of higher organisms. The yield and distribution of both GDH aCtivities have been analyzed in mutants showing, under particular growth conditions, defective mitochondrial functions. INTRODUCTION NADP-dependent has been described in higher
GDH, in lesser
organisms
this
GDH of yeast
tions
(5,6).
bound
to mitochondria, Several
investigation also
yeast
it
nuclei
that
investigated
mic and nuclear
enzymes
tions
a relatively
of the cells,
nuclear
using
differentiate the possibility
is
regulated mutants
local-
cytoplasmic
frac-
GDH associated
(7-13).
reported
below
GDH level. it
from
demonstrate
the
and
(14):
cytoplasmic
the synthesis
it
enzyme.
of the cytoplas-
the physiological cerevisiae
the
that
The purification elsewhere
in dependerceof of Saccharomyces
with
We have extended
be reported that
weakly
localization.
another
tissue
high
Although
the enzyme may be very
found
GDH will
the presence (4).
of mitochondrial
soluble
have a different
from animal
clearly
We have
mitochondrial
organism
and the experiments
of yeast
shows properties
in the
cerevisiae
(1,2,3);
been reported
believed
found
have recently
fraction contain
characterization
latter
may indeed
investigators to yeast,
been
Saccharomyces
authors
has also
enzyme was commonly in the
nuclear
of yeast
by several amounts,
has often
Although
the purified
dehydrogenase
and characterized
of NAD-dependent ization,
glutamate
defective
condiin
functions. EXPERIMENTAL
Strains: The following yeast strains of Saccharomyces 1511 (15) and an isogenic derivative -pts mutant strain Growth conditions: Cultures were grown in YEP medium
Copyright All rights
o I9 75 by Academic Press. Im. in any form reserved.
of reproduction
773
cerevisiae were rho- 1511-1. consisting
used:
of 1% Difco
the
Vol. 64, No. 2, 1975
yeast extract the medium.
BIOCHEMICAL
and 2% Difco Cultures were
Respiration polarographically
peptone; grown
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
1% glucose and 3Z 23°C and 36°C with
at
The oxygen uptake a KM Gilson Oxigraph.
measurements: with
of
the
glycerol vigorous
whole
were added shaking.
cells
was
to
measured
Preparation of protoplasts: Early stationary phase cells were treated according to the procedure of Kov~? (16) for preparation of yeast mitochondria, except that snail gut juice was substituted by Glusulase. When protoplasts were formed in 80% yield, they were disrupted in a Sorvall Omni Mixer for 30 sec. at the maximum speed without previously washing away the Glusulase. In fact, it was observed that GDH was partially extracted from the protoplasts by the lytic enzyme, which however did not interfere with the GDH assay. The enzyme activity of the homogenate was assayed Enzyme assay: metrically at 30°C, in cuvettes of l-cm light path, by recording in absorbance at 340 nm of the reduced coenzyme. In a final volume the mixture contained: 0.1 M (NH&SO4, 0.1 M phosphate buffer pH a-ketoglutarate and 0.1 mM NADPH. Activity is expressed as pmoles oxidized per minute, using a molar extinction coefficient of 6.22 one I.rmole representing one activity unit. Reagents: Endo Lab., the other
Erythromycin used as lactobionate NADPH from Calbiochem, a-ketoglutarate reagents were of the highest purity RESULTS
Nuclear
gene
mitochondrial able
substrates
obtained
by
growing
rise
The
the
as
cytoplasmic
pathway. in
we
the
have
mutant
mutations
However,
cells
The
presence
used
can
same
of
yeast
respiratory-deficient
pts
from Abbott, Glusulase from Pierce Chemicals. commercially available.
(18,19).
cells
below,
and
36”C,
well
yeast
was
from All
AND DISCUSSION
glycolytic
yeast
to
1511
structurally at
the
reported
give
as in
using
experiments which
mutations
functions
spectrophotothe decrease of 1 ml, 7.0, 0.013 M of cofactor X 103 (17),
can
affect
the
grow
on
ferment-
phenotype
can
erythromycin
strains
be
(20).
and
growth
For
the
conditions
phenotypes.
strain,
functionally
grown
at
unaffected
mitochondriaare
23°C
and
used
as
mitochondria.
altered
and
the
control,
After
“petite”
develops
prolonged
phenotype
growth
is
expressed
at
23°C
(15,21). The 36°C
for
800
X g,
lo-15% and
about
a few
20 of
by
bound results
of of
cells
in
was the
The 0.32
could
at
36’C
in
are was
the
the
shown twice
the
by in
Table
that
of
774
homogenate the nuclei,
pellet,
supernatant
of
(221,
the
ultrasonic 1. the
even was
purification
2 M sucrose
extracted
the
contained in
further
grown
supernatant;
which
until
in be
cells of
remained
After
experiments grown
found
activity
centrifugation
of
centrifugation
precipitate
M sucrose,
and
homogenates
After
activity.
nuclei these
in
activity
cells.
high-speed the
measured
with
enzymatic
to
the
associated intact
of
was generations.
washing
devoid
gram
level
85-90%
was
repeated
tion
GDH
The
activity
yield at
at
remaining cell
debris
after
completely the
treatment
control
and
nuclear was
fracstill
(14). of
23OC,
enzyme but
The per the
BIOCHEMICAL
Vol. 64, No. 2, 1975
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
Table Distribution
of
GDH activity grown at
23°C
fraction
1 in
23°C
(1.3
(1.8
g cells)
units/g
100
89.7
1.116
89.8
800 x g sediment
0.054
10.3
0.126
10.2
of
for
activity the
and
grown
completely
at
(21).
in
amount
these
The the
enzyme
cultures
of
GDH
of per
the
the
and
1511
strain
of
cells
cultures
of and
the
was
1511
of
mutant
36’C:
functions,
two-fold
in
as
the
terms
in
these
than
that
are
distribu-
comparable
higher
is
content,
well
also
mg/
strain
cytochrome
homogenate,as
at
2.5
phenotype
mitochondrial and
strain,
absence
rho-
fractions,were
grown
the
constant.
respiratory-deficient
the
cytoplasmic
was
presence
synthesis in
fraction
spontaneous
The
content and
gram
in
of
protein
nuclear
nuclear with
23°C
cases
mitochondrial
between
the
temperature.
in
1.240
obtained at
cultures
same
expressed
found
results
with
the
respiration,
blocked
with
20 generations
erythromycin,
tion
associated
2 shows about
100
5:
0.480
1511-l
to
those
cases,
the
of
control
the
23°C. The
thesize
observation
higher
that
levels
hypothesizing
controls is
36°C
800 x g supernatant
Table
by
strain
0.535
grown
at
%
1511
homogenate
percentage
of
of
g cells)
units/g
ml
cultures and 36°C
the
lost
enzyme
under
ization
of
both
the
mitochondria
(23)
beads.
Again,
pellet,
but
was
at
were
recovered
the
the
was the
level
in
with
sap.
An cell
not
GDH could
synthesized
out
involving
in
functions
syn-
be
in
the
and
that
explained
mitochondria, this
function
above.
carried
cell
used,
cytoplasmic
cytoplasmic
associated in
GDH activity was
and
mitochondrial
protein,
outlined
activity,not found
altered
nuclear
conditions
experiments
constantly
with
a regulatory synthesis
the
Further
was
of
that
cells
found
soluble
775
an attempt
to
nuclei,which, alternative
associated cytoplasmic
with fraction.
the
in
our
by
means
method
fragmentation
clarify
of
the
local-
experiments, preparation of
mitochondrial
of glass
Vol. 64, No. 2, 1975
BIOCHEMICAL
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
Table
2
Distribution of GDH activity in cultures grown at 23°C in the presence and absence and in cultures of the isogenic derivative
control
fraction
(2 g cells)
+erythr.
of 1511 strain of erythromycin, rho- 1511-1
(0.85
g cells)
rho-
(1.3
g cells)
units/g
%
units/g
%
units/g
%
homogenate
0.592
100
1.168
100
1.046
100
800 x g supernatant
0.536
90.5
1.040
89.2
0.968
83
800 x g sediment
0.056
9.5
0.126
10.8
0.184
17
This chondrial
result,
the conclusion with
together
functions
nuclei
reached is
with
do not
the finding
show enzyme
by other
localized
that
levels
investigators
in the
soluble
mutants
lower that
than
with
impaired
the enzyme not
cytoplasmic
mito-
the control,
phase
supports associated
and not
in the mito-
chondria. The biological suitable effective
mutants, tool
role with
of nuclear
GDH is
altered
nuclear
this
problem.
to tackle
still
unclear.
GDH activity,
The isolation
could
provide
an
REFERENCES 1.
Grisolia, Acta z,
S., Quijada, 61-70.
C.L., Bull.
and Fernandez,
2.
Fourcade,
A. (1968)
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Fourcade,
A.,
Sot.
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Bernhardt, W., Zink, 118, 549-555.
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Perlman, 245-259.
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di Prisco, G., Banay-Schwartz, M., Biophys. Res. Commun. 33, 606-612.
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Zbarsky, I.B., Pokrovsky, A.A., Lashneva, N.V., and Delektorskaya, (Biochemistry) 181, 993.
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Ph. S., C.P., 13-19.
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H.R.
W.F.,
Biol.
so,
Biochcm.
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R. (1971)
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Arch.
and Strecker,
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331-344.
Biochim.
Biophys.
Acta
Biochem.
Biophys.
136,
P. (1970)
Perevoshchikova, L.N. (1968)
Biophys.
1671-1679. Biophys.
H. (1966) (1970)
Biochkm.
Biochim. H.J.
(1968)
Biophys. Biochem.
K.A., Gapparov, M.M., Dokl. Akad. Nauk SSSR
of
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9. 10. 11. 12.
di Prisco,
and Strecker,
G.,
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H.J.
(1970)
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J. Biochem.
483-489.
Rerzfeld, A., Federman, M., and Greenpard, 0. (1973) J. Cell Biol. 475-483. Franke, W.W., Deumling, B., Ermen, B., Jarasch, E.D., and Kleinig, (1970) J. Cell Biol. 5, 379-395. Chem. -248, 2044-2048. Kato, T., and Lowry, O.H. (1972) J. Biol.
13.
di Prisco, G., 58, 683-689.
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Camardella, preparation).
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Puglisi, P.P., 2, 461-469.
16.
Kova/F, L., 153, 32-42.
17.
Horecker, B.L., and Kornberg, A. (1948) J. Biol. Ephrussi, B. (1953) Nucleo-Cytoplasmic Relations London, Oxford University Press.
18.
12,
and Garofano,
L.,
19.
Sherman,
20.
Clark-Walker,
21.
Guerrini,
22.
Rozijn, 105-112.
23.
Del Giudice, 2, 865-871.
di Prisco,
F. (1963) A.M., H., L.,
T.
(1974)
Biochem.
Garofano,
F.,
(1970)
and Greksgk,
H.,
Genetics
G.D.,
Th.
G.,
and Cremona,
Bed&o&,
F.
48,
M.A.,
and Tonino, and Puglisi,
Res.
and Guerrini,
Biochem.
Biophys.
M. (1968)
Commun.
A.M. Res.
Biochim.
R.
(in
Commun.
Biophys.
Acta
Chem. -175, 385-390. in Yicrorganisms.
375-385.
and Linnane,
Pedrini,
Biophys.
57,
A.W.
(1967)
and Gionti,
J. Cell E. (in
Biol.
2,
l-14.
preparation).
G.J.M.
(1964)
Biochim.
Biophys.
Acta
-'91
P.P.
(1974)
Biochem.
Biophys.
Res.
Commun.
777
Vol. 64, No. 2, 1975
AND BIOPHYSICAL
RESEARCH COMMUNICATIONS
NUCLEAR AND CYTOPLASMIC GLUTAMATE DEHYDROGENASES (NADP-DEPENDENT) IN SACCHAROMYCES CEREVISIAE Laura
Camardella,
Guido
International
Institute Marconi
Via
Received
April
4,
di Prisco,
Felice
Garofano
and Anna Maria
of Genetics and Biophysics, 10, 80125 Naples, Italy
Guerrini
CNR,
1975 SUMMARY
The intracellular localization of NADP-dependent glutamate dehydrogehase has been studied in Saccharomyces cerevisiae. has been found to be associated Beside cytoplasmic GDH, enzyme activity with the nuclear fraction in amounts comparable to those reported in nuclei of higher organisms. The yield and distribution of both GDH aCtivities have been analyzed in mutants showing, under particular growth conditions, defective mitochondrial functions. INTRODUCTION NADP-dependent has been described in higher
GDH, in lesser
organisms
this
GDH of yeast
tions
(5,6).
bound
to mitochondria, Several
investigation also
yeast
it
nuclei
that
investigated
mic and nuclear
enzymes
tions
a relatively
of the cells,
nuclear
using
differentiate the possibility
is
regulated mutants
local-
cytoplasmic
frac-
GDH associated
(7-13).
reported
below
GDH level. it
from
demonstrate
the
and
(14):
cytoplasmic
the synthesis
it
enzyme.
of the cytoplas-
the physiological cerevisiae
the
that
The purification elsewhere
in dependerceof of Saccharomyces
with
We have extended
be reported that
weakly
localization.
another
tissue
high
Although
the enzyme may be very
found
GDH will
the presence (4).
of mitochondrial
soluble
have a different
from animal
clearly
We have
mitochondrial
organism
and the experiments
of yeast
shows properties
in the
cerevisiae
(1,2,3);
been reported
believed
found
have recently
fraction contain
characterization
latter
may indeed
investigators to yeast,
been
Saccharomyces
authors
has also
enzyme was commonly in the
nuclear
of yeast
by several amounts,
has often
Although
the purified
dehydrogenase
and characterized
of NAD-dependent ization,
glutamate
defective
condiin
functions. EXPERIMENTAL
Strains: The following yeast strains of Saccharomyces 1511 (15) and an isogenic derivative -pts mutant strain Growth conditions: Cultures were grown in YEP medium
Copyright All rights
o I9 75 by Academic Press. Im. in any form reserved.
of reproduction
773
cerevisiae were rho- 1511-1. consisting
used:
of 1% Difco
the
Vol. 64, No. 2, 1975
yeast extract the medium.
BIOCHEMICAL
and 2% Difco Cultures were
Respiration polarographically
peptone; grown
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
1% glucose and 3Z 23°C and 36°C with
at
The oxygen uptake a KM Gilson Oxigraph.
measurements: with
of
the
glycerol vigorous
whole
were added shaking.
cells
was
to
measured
Preparation of protoplasts: Early stationary phase cells were treated according to the procedure of Kov~? (16) for preparation of yeast mitochondria, except that snail gut juice was substituted by Glusulase. When protoplasts were formed in 80% yield, they were disrupted in a Sorvall Omni Mixer for 30 sec. at the maximum speed without previously washing away the Glusulase. In fact, it was observed that GDH was partially extracted from the protoplasts by the lytic enzyme, which however did not interfere with the GDH assay. The enzyme activity of the homogenate was assayed Enzyme assay: metrically at 30°C, in cuvettes of l-cm light path, by recording in absorbance at 340 nm of the reduced coenzyme. In a final volume the mixture contained: 0.1 M (NH&SO4, 0.1 M phosphate buffer pH a-ketoglutarate and 0.1 mM NADPH. Activity is expressed as pmoles oxidized per minute, using a molar extinction coefficient of 6.22 one I.rmole representing one activity unit. Reagents: Endo Lab., the other
Erythromycin used as lactobionate NADPH from Calbiochem, a-ketoglutarate reagents were of the highest purity RESULTS
Nuclear
gene
mitochondrial able
substrates
obtained
by
growing
rise
The
the
as
cytoplasmic
pathway. in
we
the
have
mutant
mutations
However,
cells
The
presence
used
can
same
of
yeast
respiratory-deficient
pts
from Abbott, Glusulase from Pierce Chemicals. commercially available.
(18,19).
cells
below,
and
36”C,
well
yeast
was
from All
AND DISCUSSION
glycolytic
yeast
to
1511
structurally at
the
reported
give
as in
using
experiments which
mutations
functions
spectrophotothe decrease of 1 ml, 7.0, 0.013 M of cofactor X 103 (17),
can
affect
the
grow
on
ferment-
phenotype
can
erythromycin
strains
be
(20).
and
growth
For
the
conditions
phenotypes.
strain,
functionally
grown
at
unaffected
mitochondriaare
23°C
and
used
as
mitochondria.
altered
and
the
control,
After
“petite”
develops
prolonged
phenotype
growth
is
expressed
at
23°C
(15,21). The 36°C
for
800
X g,
lo-15% and
about
a few
20 of
by
bound results
of of
cells
in
was the
The 0.32
could
at
36’C
in
are was
the
the
shown twice
the
by in
Table
that
of
774
homogenate the nuclei,
pellet,
supernatant
of
(221,
the
ultrasonic 1. the
even was
purification
2 M sucrose
extracted
the
contained in
further
grown
supernatant;
which
until
in be
cells of
remained
After
experiments grown
found
activity
centrifugation
of
centrifugation
precipitate
M sucrose,
and
homogenates
After
activity.
nuclei these
in
activity
cells.
high-speed the
measured
with
enzymatic
to
the
associated intact
of
was generations.
washing
devoid
gram
level
85-90%
was
repeated
tion
GDH
The
activity
yield at
at
remaining cell
debris
after
completely the
treatment
control
and
nuclear was
fracstill
(14). of
23OC,
enzyme but
The per the
BIOCHEMICAL
Vol. 64, No. 2, 1975
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
Table Distribution
of
GDH activity grown at
23°C
fraction
1 in
23°C
(1.3
(1.8
g cells)
units/g
100
89.7
1.116
89.8
800 x g sediment
0.054
10.3
0.126
10.2
of
for
activity the
and
grown
completely
at
(21).
in
amount
these
The the
enzyme
cultures
of
GDH
of per
the
the
and
1511
strain
of
cells
cultures
of and
the
was
1511
of
mutant
36’C:
functions,
two-fold
in
as
the
terms
in
these
than
that
are
distribu-
comparable
higher
is
content,
well
also
mg/
strain
cytochrome
homogenate,as
at
2.5
phenotype
mitochondrial and
strain,
absence
rho-
fractions,were
grown
the
constant.
respiratory-deficient
the
cytoplasmic
was
presence
synthesis in
fraction
spontaneous
The
content and
gram
in
of
protein
nuclear
nuclear with
23°C
cases
mitochondrial
between
the
temperature.
in
1.240
obtained at
cultures
same
expressed
found
results
with
the
respiration,
blocked
with
20 generations
erythromycin,
tion
associated
2 shows about
100
5:
0.480
1511-l
to
those
cases,
the
of
control
the
23°C. The
thesize
observation
higher
that
levels
hypothesizing
controls is
36°C
800 x g supernatant
Table
by
strain
0.535
grown
at
%
1511
homogenate
percentage
of
of
g cells)
units/g
ml
cultures and 36°C
the
lost
enzyme
under
ization
of
both
the
mitochondria
(23)
beads.
Again,
pellet,
but
was
at
were
recovered
the
the
was the
level
in
with
sap.
An cell
not
GDH could
synthesized
out
involving
in
functions
syn-
be
in
the
and
that
explained
mitochondria, this
function
above.
carried
cell
used,
cytoplasmic
cytoplasmic
associated in
GDH activity was
and
mitochondrial
protein,
outlined
activity,not found
altered
nuclear
conditions
experiments
constantly
with
a regulatory synthesis
the
Further
was
of
that
cells
found
soluble
775
an attempt
to
nuclei,which, alternative
associated cytoplasmic
with fraction.
the
in
our
by
means
method
fragmentation
clarify
of
the
local-
experiments, preparation of
mitochondrial
of glass
Vol. 64, No. 2, 1975
BIOCHEMICAL
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
Table
2
Distribution of GDH activity in cultures grown at 23°C in the presence and absence and in cultures of the isogenic derivative
control
fraction
(2 g cells)
+erythr.
of 1511 strain of erythromycin, rho- 1511-1
(0.85
g cells)
rho-
(1.3
g cells)
units/g
%
units/g
%
units/g
%
homogenate
0.592
100
1.168
100
1.046
100
800 x g supernatant
0.536
90.5
1.040
89.2
0.968
83
800 x g sediment
0.056
9.5
0.126
10.8
0.184
17
This chondrial
result,
the conclusion with
together
functions
nuclei
reached is
with
do not
the finding
show enzyme
by other
localized
that
levels
investigators
in the
soluble
mutants
lower that
than
with
impaired
the enzyme not
cytoplasmic
mito-
the control,
phase
supports associated
and not
in the mito-
chondria. The biological suitable effective
mutants, tool
role with
of nuclear
GDH is
altered
nuclear
this
problem.
to tackle
still
unclear.
GDH activity,
The isolation
could
provide
an
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