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The effect of nalidixic acid on the expression of some genes in Escherichia coli K-12
Vol. 64, No. 1, 1975
BIOCHEMICAL
THE EFFECT OF NALIDIXIC
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
ACID ON THE EXPRESSION OF SOME GENES
IN ESCHERICHIA COLI K-12 -H.Shuman and M.Schwartz Unite de GBnetique Moleculaire Departement de Biologie Moleculaire Institut Pasteur,Paris. Received
March
14,1975
SUMMARY The synthesis of maltodextrin phosphorylase and the phage X receptor of Escherichia coli K-12 is substantially inhibited by the presence of 50 pg nalidixic acid/ml in the culture medium. B-galactosidase synthesis is inhibited to a lesser extent and no inhibition of L-tryptophanase synthesis is observed. The inhibition of enzyme synthesis is apparently not due to the effect of nalidixic acid on deoxyribonucleic acid synthesis.
INTRODUCTION Nalidixic
acid
(1-ethyl-1,4-dihydro-7-methyl-4-0x0-1,
8-naphthydrine-3-carboxylic deoxyribonucleic understood which
for
(2,8).
that
This
in the
they
Escherichia
significantly
(50pg/ml)
is
poorly
literature
DNA synthesis
synthesis
(13,14,
is based on the observation bacteria
do not
incorporate
amino acids from that
into
that thymine
protein
observed
(2).
experiments
K-12 cells,
in the
to stop
on protein
different
drug.
to describe coli
acid
do incorporate
absence of the
We wish
acid
of the drug,
DNA while not
have appeared
is no effect assumption
of bacterial
whose mode of action
Many reports
there
presence
at a rate
synthesis
is an inhibitor
the use of nalidixic
example).
in the into
acid
describe
assuming
acid)
which
a concentration
commonly used to
interrupt
show that
in
of nalidixic DNA synthesis
also
BIOCHEMICAL
Vol. 64, No. 1,1975
inhibits
the
appearance
for
the bacteriophage
in part, the
of maltodextrin
the product
(~~2,4,1,1),
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
of the
lambda,
gene,
which
malA region
of
the Escherichia
1amB gene is
located
of the malA
and malB regions
ma1T product
and is
(1,3,4,15,Hofnung of
glucose
subject
the products
coli
is
source
in
The expression by the
repression results).
The
and malB regions
the malA
coli
located
controlled
unpublished
K-12 cells
by adding
monophosphate
(3,4).
positively
of both
at least
chromosome and the
to catabolite
in Escherichia
as carbon
adenosine
is determined,
in the malB region
and Schwartz,
can be induced
and the receptor
The malP gene is
by the
synthesis
phosphorylase
maltose
which
are using
and 3':5'
cyclic-
(CAMP) to the medium (Fig.Ia
and Ib).
RESULTS AND DISCUSSION The induction both
in the
in Figure
of the
absence and presence
la.
the receptor
An 80% reduction was observed
same experiment, maltodextrin the
the into
acid
acid
appearance
nalidixic inhibition
not
acid
in the
shown).
This
on the maltose
of DNA synthesis.
effect
suggests
of
with of
phosphorylase of
1Opq
or
14C-thymine
was completely that
system is not
205
of
was observed
material
In order
In the
of synthesis
were observed
incorporation
insoluble
of
in the presence
maltodextrin
acid
shown
of the drug.
per ml. At a concentration
although
is
of synthesis
rate
was observed
of either
trichloroacetic
acid
rate
per ml no significant
lambda receptor,
inhibitcd,(data
in the
The above effects
50 pg of nalidixic of nalidixic
of nalidixic
a 70% reduction
(Fig.lb).
by CAMP and maltose,
in the presence
phosphorylase
drug.
on the
X receptor
to test
the
effect
a consequence this
of of
hypothesis
BIOCHEMICAL
Vol. 64, No. 1,1975
AND BIOPHYSICAL
20 t
RESEARCH COMMUNICATIONS
bJ
I 0.35
0.45 Absorbance
0.55 i600nml
0.65
0.35
0 45 Absorbance
0.55 1600nm)
0.65
04 1600nm,
05
dJ 400
L 02
FIGURE 1 : The effect inducible proteins. The activity plotted as a function
0.3 A bsorboncc
0.4 l6OOnm)
05
t
03 Absorbonce
of nalidixic . -
acid -_
on the synthesis
of each protein per ml of culture of the absorbance of the culture
of some is at 600 nm.
a) Lambda receptor. A culture of exponentially growing Escherichia coli K-12 cells, using glucose (2xl0'2M) as carbon source was divided in half. Nalidixic acid was added to one half of the culture at a final concentration of 50 vg/ml. After shaking at 37 C for 15 minutes, CAMP and maltose were added to both halves of the culture, at final concentrations of 4x10-3M and 10m2M, respectively. One ml samples were taken from each culture into chloramphenicol (100 pg/ml) at 0 C, at 0, 10, 20, 30, 45, and 60 min after addition of CAMP and maltose. After the A600 was determined for each sample, the cells were centrifuged, resuspended in O.lml of tris-cholate-EDTA buffer, (10) and extracted for 30 min at 37 C. Lambda receptor activity was determined in the extracts as described by RandallHazelbauer and Schwartz (10). (O-O without nalidixic acid, PJ -m with nalidixic acid). b) Maltodextrin phosphorylase. The procedure is the same as that used in a) except 2ml samples were taken and maltodextrin phosphorylase activity was determined in sonicated extracts of the bacteria. The sensitive method of Schwartz and Worcel (12) which measures incorporation of 32P inorganic phosphate into glucose-lphosphate was used to determine the amount of maltodextrin phosphorylase activity in the extracts. (O-O without nalidixic acid, a-a with nalidixic acid). c) L-tryptophanase. The procedure used was the same as in a) except that L-tryptophan (lmg/ml final concentration) was added to the culture instead of maltose, to induce synthesis of L-tryptophanase. L-tryptophanase activity was determined in toluenized cells using
206
BIOCHEAKAL
Vol. 64, No. 1, 1975
the procedure p--n with
AND BIOPHYSICAL
of Newton et s.(7). nalidixic azd).
RESEARCH COMMUNKATIONS
(O-O without
nalidixic
acid).
d) @-galactosidase. The procedure was as in a) except that the culture was divided into 4 parts before treatment with nalidixic acid. Nalidixic acid was added to two of the aliquots and after shaking for 15 min at 37 C, CAMP and isopropyl-B-D-thiogalactoside (IPTG) (5x10-3M final concentration) were added to one treated and one untreated aliquot. IPTG (5x10-3M, final concentration) alone B-galactosidase activity was added to the two remaining aliquots. was determined in toluenized cells by the method of Horiuchi et al -(5). IPTG + CAMP O-O IPTG + CAMP + nalidixic acid a-0 I?TG 0-e IPTG + nalidixic acidm-m
we examined
the
synthesis
lambda receptor
in a strain
In such a strain, transfer
of the
cells
synthesis
receptor.
In the
maltodextrin
inhibited view
of these
nalidixic
acid
a consequence
that
it
that
on the expression the effect
these
experiments interfere
induction
the effect
with
that
maltose
of the maltose
to
is not
the possibility of the bacteria the
system. acid
both
system and on the
nalidixic
207
of
system
induce
maltose.
transport
was
the effect
of nalidixic
transport
of
at 30 C or 42 C. In
ability
transport
to transport suggest
synthesis
on DNA synthesis.
the
maltose
of the maltose
the bacteria
the
we have tested with
on the
or lambda
of the maltose
of the drug
enough internal
effect
and lambda receptor
seems likely
was done by examining
of
acid,
either
interferes
directly the
results
induction
after
phosphorylase
incubation
nalidixic
ability of
during
experiments
on the
immediately
of nalidixic
In preliminary
to accumulate This
presence
acid
a dnaBtS mutation.
at 42 C had little
phosphorylase
of
and
to 42 C. In the absence of nalidixic
of maltodextrin
severely
phosphorylase
carries
stops
of the bacteria
of
both
which
DNA synthesis
acid,incubation rate
of maltodextrin
The results acid
but
does not
does prevent
system in addition
of
BIOCHEMICAL
Vol. 64, No. 1, 1975
to lambda receptor shown below of
for
and maltodextrin
the
i3-galactosidase
acid
does not Figure
the
synthesis
without
with
of synthesis
acid
has no effect
in the
of
acid
of L-tryptophanase. synthesis
any involvement
suggest of nalidixic
acid
of L-tryptophanase
sensitive
the effect
that
nalidixic
intercalate
supercoiled inhibit
operons
(11).
that
the
have
not
dehydrogenase
shown).
These repression
is
synthesis. nalidixic
product
acid by
may act
orange
of some catabolite
lines
nalidixic
acid,
or a metabolic agent
of
it,
reasoning
it
product
may preferentially
of some genes such as those
208
as
drugs which
DNA such as acridine
expression
of
DNA (9).
shown that
these
transcription
nalidixic
nor does CAMP reverse
that
in supercoiled
Following
as an intercalating
on the
amount of RNA produced
or a metabolic
and Pogell
bromide
effect
the drug does not affect
repression)
in the
agent
Senkaran
or
of the phage S-13 genome. They postulate
acid,
an intercalating
with
of catabolite
of the drug on %-galactosidase
transcription
synthesis
of homoserine
since
Puga and Tessman have observed
--in vivo
There
In addition,
(data
on
(an enzyme whose synthesis
to catabolite
causes an 80% reduction
nalidixic
acid
either
has no apparent
results
very
of nalidixic
B-galactosidase
dehydrogenase
do not
that
and B-galactosidase.
rate
on the
on the
indicate
effect
or glucose-6-phosphate
synthesis
induction
of the drug when induced
rate
effect
acid
CAMP transport.
of L-tryptophanase
CAMP. Nalidixic
in the
The results
of nalidixic
and Id show the
presence
phosphorylase.
and L-tryptophanase
is a 40% reduction in the
effect
interfere
lc
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
sensitive
could of
and ethidium
be proposed it,
inhibit
acting the
of the maltose
BIOCHEMICAL
Vol. 64, No. 1,1975
system.
Whatever
suggest
that
can have
their
nalidixic
interpretation acid,
an effect
AND BIOPHYSICAL
on the
RESEARCH COMMUNICATIONS
, our observations
besides
blocking
expression
of
DNA synthesis
some genes.
ACKNOWLEDGEMENTS This National
investigation
was supported
Institutes
of Health,
the"Centre
Recherche
Scientifique'j
the"Delegation
Recherche
Scientifique
et Technique"
a 1'Energie for
granting
Atomique". him
H.S.thanks
a fellowship
LITERATURE
by grants
Gendrale
the
de Ia a la
and the"Commissariat the
during
National
from
"Fondation the
course
Philippe" of this
work.
CITED
1. Chao,J.,and Weatherbee,C.J. (1974) J.Bacteriol,x,l81-188. 2. Goss,W.A., Deitz,W.H.,and Cook,T.M.(1965) J.Bacteriol.e,1068-1074. 3. Hatfield,D.,Hofnung,M. and Schwartz,M. (1969) J.Bacteriol. !@,559-567. 4. Hofnung,M. Hatfield,D.,and Schwartz,M. (1974) J.Bacteriol. 117,40-47 (1962) Bioch.Biophys.Acta, 5. Horium,T.,Tomizawa,J.,and Novick,A. 55 1152-163. 6. Kohiyama,M.,Cousin,D.,Ryter,A. and Jacob,F. (1966). Annales Inst.Pasteurr110,465-486. (1965) J.Biol.Chem.240,1211 7. Newton,W.A.,Morino,Y.,Snell,E.E. 8. Pedrini,A.M.,Geroldi,D.,Siccardi,A. and Falaschi,A. (1972) Eur.J.Biochem.25#259-365. 9. Puga,A. and Tessman>. (1974) J.Mol.Bio1.75,99-108. 10. Randall-Hazelbauer,L.rand Schwartz,M. (1973) J.Bacteriol.z, 1436-1446. 11. Sankaran,L. and Poge1,B.M. (1973). Differential inhibition of catabolite sensitive enzyme induction by intercalating dyes Nature New Biol. 245,251-260. and Worcelx (1971) J.Mol.Bio1.61,329-342. 12. Schwartz,M. and Schaber,I. (1973). 245,144-145. 13. Traub,W.H.,Kleber,I. 14. Weiner,R.M. and Blackman,M.A. (1973). J.Bacteriol.l16,1398-1404. 15. Yokota,T.tand Kasuga,T. (1972). J.Bacterio1.109,13~1308.
209
BIOCHEMICAL
THE EFFECT OF NALIDIXIC
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
ACID ON THE EXPRESSION OF SOME GENES
IN ESCHERICHIA COLI K-12 -H.Shuman and M.Schwartz Unite de GBnetique Moleculaire Departement de Biologie Moleculaire Institut Pasteur,Paris. Received
March
14,1975
SUMMARY The synthesis of maltodextrin phosphorylase and the phage X receptor of Escherichia coli K-12 is substantially inhibited by the presence of 50 pg nalidixic acid/ml in the culture medium. B-galactosidase synthesis is inhibited to a lesser extent and no inhibition of L-tryptophanase synthesis is observed. The inhibition of enzyme synthesis is apparently not due to the effect of nalidixic acid on deoxyribonucleic acid synthesis.
INTRODUCTION Nalidixic
acid
(1-ethyl-1,4-dihydro-7-methyl-4-0x0-1,
8-naphthydrine-3-carboxylic deoxyribonucleic understood which
for
(2,8).
that
This
in the
they
Escherichia
significantly
(50pg/ml)
is
poorly
literature
DNA synthesis
synthesis
(13,14,
is based on the observation bacteria
do not
incorporate
amino acids from that
into
that thymine
protein
observed
(2).
experiments
K-12 cells,
in the
to stop
on protein
different
drug.
to describe coli
acid
do incorporate
absence of the
We wish
acid
of the drug,
DNA while not
have appeared
is no effect assumption
of bacterial
whose mode of action
Many reports
there
presence
at a rate
synthesis
is an inhibitor
the use of nalidixic
example).
in the into
acid
describe
assuming
acid)
which
a concentration
commonly used to
interrupt
show that
in
of nalidixic DNA synthesis
also
BIOCHEMICAL
Vol. 64, No. 1,1975
inhibits
the
appearance
for
the bacteriophage
in part, the
of maltodextrin
the product
(~~2,4,1,1),
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
of the
lambda,
gene,
which
malA region
of
the Escherichia
1amB gene is
located
of the malA
and malB regions
ma1T product
and is
(1,3,4,15,Hofnung of
glucose
subject
the products
coli
is
source
in
The expression by the
repression results).
The
and malB regions
the malA
coli
located
controlled
unpublished
K-12 cells
by adding
monophosphate
(3,4).
positively
of both
at least
chromosome and the
to catabolite
in Escherichia
as carbon
adenosine
is determined,
in the malB region
and Schwartz,
can be induced
and the receptor
The malP gene is
by the
synthesis
phosphorylase
maltose
which
are using
and 3':5'
cyclic-
(CAMP) to the medium (Fig.Ia
and Ib).
RESULTS AND DISCUSSION The induction both
in the
in Figure
of the
absence and presence
la.
the receptor
An 80% reduction was observed
same experiment, maltodextrin the
the into
acid
acid
appearance
nalidixic inhibition
not
acid
in the
shown).
This
on the maltose
of DNA synthesis.
effect
suggests
of
with of
phosphorylase of
1Opq
or
14C-thymine
was completely that
system is not
205
of
was observed
material
In order
In the
of synthesis
were observed
incorporation
insoluble
of
in the presence
maltodextrin
acid
shown
of the drug.
per ml. At a concentration
although
is
of synthesis
rate
was observed
of either
trichloroacetic
acid
rate
per ml no significant
lambda receptor,
inhibitcd,(data
in the
The above effects
50 pg of nalidixic of nalidixic
of nalidixic
a 70% reduction
(Fig.lb).
by CAMP and maltose,
in the presence
phosphorylase
drug.
on the
X receptor
to test
the
effect
a consequence this
of of
hypothesis
BIOCHEMICAL
Vol. 64, No. 1,1975
AND BIOPHYSICAL
20 t
RESEARCH COMMUNICATIONS
bJ
I 0.35
0.45 Absorbance
0.55 i600nml
0.65
0.35
0 45 Absorbance
0.55 1600nm)
0.65
04 1600nm,
05
dJ 400
L 02
FIGURE 1 : The effect inducible proteins. The activity plotted as a function
0.3 A bsorboncc
0.4 l6OOnm)
05
t
03 Absorbonce
of nalidixic . -
acid -_
on the synthesis
of each protein per ml of culture of the absorbance of the culture
of some is at 600 nm.
a) Lambda receptor. A culture of exponentially growing Escherichia coli K-12 cells, using glucose (2xl0'2M) as carbon source was divided in half. Nalidixic acid was added to one half of the culture at a final concentration of 50 vg/ml. After shaking at 37 C for 15 minutes, CAMP and maltose were added to both halves of the culture, at final concentrations of 4x10-3M and 10m2M, respectively. One ml samples were taken from each culture into chloramphenicol (100 pg/ml) at 0 C, at 0, 10, 20, 30, 45, and 60 min after addition of CAMP and maltose. After the A600 was determined for each sample, the cells were centrifuged, resuspended in O.lml of tris-cholate-EDTA buffer, (10) and extracted for 30 min at 37 C. Lambda receptor activity was determined in the extracts as described by RandallHazelbauer and Schwartz (10). (O-O without nalidixic acid, PJ -m with nalidixic acid). b) Maltodextrin phosphorylase. The procedure is the same as that used in a) except 2ml samples were taken and maltodextrin phosphorylase activity was determined in sonicated extracts of the bacteria. The sensitive method of Schwartz and Worcel (12) which measures incorporation of 32P inorganic phosphate into glucose-lphosphate was used to determine the amount of maltodextrin phosphorylase activity in the extracts. (O-O without nalidixic acid, a-a with nalidixic acid). c) L-tryptophanase. The procedure used was the same as in a) except that L-tryptophan (lmg/ml final concentration) was added to the culture instead of maltose, to induce synthesis of L-tryptophanase. L-tryptophanase activity was determined in toluenized cells using
206
BIOCHEAKAL
Vol. 64, No. 1, 1975
the procedure p--n with
AND BIOPHYSICAL
of Newton et s.(7). nalidixic azd).
RESEARCH COMMUNKATIONS
(O-O without
nalidixic
acid).
d) @-galactosidase. The procedure was as in a) except that the culture was divided into 4 parts before treatment with nalidixic acid. Nalidixic acid was added to two of the aliquots and after shaking for 15 min at 37 C, CAMP and isopropyl-B-D-thiogalactoside (IPTG) (5x10-3M final concentration) were added to one treated and one untreated aliquot. IPTG (5x10-3M, final concentration) alone B-galactosidase activity was added to the two remaining aliquots. was determined in toluenized cells by the method of Horiuchi et al -(5). IPTG + CAMP O-O IPTG + CAMP + nalidixic acid a-0 I?TG 0-e IPTG + nalidixic acidm-m
we examined
the
synthesis
lambda receptor
in a strain
In such a strain, transfer
of the
cells
synthesis
receptor.
In the
maltodextrin
inhibited view
of these
nalidixic
acid
a consequence
that
it
that
on the expression the effect
these
experiments interfere
induction
the effect
with
that
maltose
of the maltose
to
is not
the possibility of the bacteria the
system. acid
both
system and on the
nalidixic
207
of
system
induce
maltose.
transport
was
the effect
of nalidixic
transport
of
at 30 C or 42 C. In
ability
transport
to transport suggest
synthesis
on DNA synthesis.
the
maltose
of the maltose
the bacteria
the
we have tested with
on the
or lambda
of the maltose
of the drug
enough internal
effect
and lambda receptor
seems likely
was done by examining
of
acid,
either
interferes
directly the
results
induction
after
phosphorylase
incubation
nalidixic
ability of
during
experiments
on the
immediately
of nalidixic
In preliminary
to accumulate This
presence
acid
a dnaBtS mutation.
at 42 C had little
phosphorylase
of
and
to 42 C. In the absence of nalidixic
of maltodextrin
severely
phosphorylase
carries
stops
of the bacteria
of
both
which
DNA synthesis
acid,incubation rate
of maltodextrin
The results acid
but
does not
does prevent
system in addition
of
BIOCHEMICAL
Vol. 64, No. 1, 1975
to lambda receptor shown below of
for
and maltodextrin
the
i3-galactosidase
acid
does not Figure
the
synthesis
without
with
of synthesis
acid
has no effect
in the
of
acid
of L-tryptophanase. synthesis
any involvement
suggest of nalidixic
acid
of L-tryptophanase
sensitive
the effect
that
nalidixic
intercalate
supercoiled inhibit
operons
(11).
that
the
have
not
dehydrogenase
shown).
These repression
is
synthesis. nalidixic
product
acid by
may act
orange
of some catabolite
lines
nalidixic
acid,
or a metabolic agent
of
it,
reasoning
it
product
may preferentially
of some genes such as those
208
as
drugs which
DNA such as acridine
expression
of
DNA (9).
shown that
these
transcription
nalidixic
nor does CAMP reverse
that
in supercoiled
Following
as an intercalating
on the
amount of RNA produced
or a metabolic
and Pogell
bromide
effect
the drug does not affect
repression)
in the
agent
Senkaran
or
of the phage S-13 genome. They postulate
acid,
an intercalating
with
of catabolite
of the drug on %-galactosidase
transcription
synthesis
of homoserine
since
Puga and Tessman have observed
--in vivo
There
In addition,
(data
on
(an enzyme whose synthesis
to catabolite
causes an 80% reduction
nalidixic
acid
either
has no apparent
results
very
of nalidixic
B-galactosidase
dehydrogenase
do not
that
and B-galactosidase.
rate
on the
on the
indicate
effect
or glucose-6-phosphate
synthesis
induction
of the drug when induced
rate
effect
acid
CAMP transport.
of L-tryptophanase
CAMP. Nalidixic
in the
The results
of nalidixic
and Id show the
presence
phosphorylase.
and L-tryptophanase
is a 40% reduction in the
effect
interfere
lc
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
sensitive
could of
and ethidium
be proposed it,
inhibit
acting the
of the maltose
BIOCHEMICAL
Vol. 64, No. 1,1975
system.
Whatever
suggest
that
can have
their
nalidixic
interpretation acid,
an effect
AND BIOPHYSICAL
on the
RESEARCH COMMUNICATIONS
, our observations
besides
blocking
expression
of
DNA synthesis
some genes.
ACKNOWLEDGEMENTS This National
investigation
was supported
Institutes
of Health,
the"Centre
Recherche
Scientifique'j
the"Delegation
Recherche
Scientifique
et Technique"
a 1'Energie for
granting
Atomique". him
H.S.thanks
a fellowship
LITERATURE
by grants
Gendrale
the
de Ia a la
and the"Commissariat the
during
National
from
"Fondation the
course
Philippe" of this
work.
CITED
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