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The uptake system of free thiamine in mutants of Escherichiacoli
Vol. 47, No. 2, 1972
BIOCHEMICAL
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
THE UPTAKE SYSTEM OF FREE THIAMINE OF ESCHERICHIA COLI
Takashi
Hiroshima
Received April
Kawasaki
IN MUTANTS
and Kazuo Yamada
Department of Biochemistry University School of Medicine Hiroshima, Japan
3, 1972
SUMMARY Mutants of Escherichia coli auxotrophic for thiamine monophosphate took up I%-thiamineas its free form from the external medium against a concentration gradient regardless of the presence of glucose. The radioisotope was then transported outward in the presence of glucose, but not in its absence. 2,4-Dinitrophenol and sodium azide eliminated the effect of added glucose. The other mutant auxotrophic for thiamine pyrophosphate showed the same profile of uptake as the parent strain except for the accumulation of the radioisotope as 14C-thiamine monophosphate in the cytoplasm. The uptake a manner
similar
(2) that
the
first,
then
which
uptake
in
a membrane It
second
step,
not
conclusively
crosses
the
diffusion
or of
active
whether
the
of at
the
membrane
is
membrane
Press, Inc.
free
Thiamine
is
in
the
catalyzed
cyto-
by
(3).
It
reaction
two steps:
as its
(TPP)
probably
in
was proposed
least
carrier.
however,
by a process
transport.
accumulation
0 1972, by Academic
cell
established,
465 Copyright
2) and it
pyrophosphate which
proceeds
composed
pyrophosphokinase
thiamine
coli
(1,
by a specific
as thiamine
thiamine
is
is
through
is mediated
the
Escherichia
transport
process
passes
accumulated
plasm
in
to active
thiamine
form,
of thiamine
is
of also
as TPP is
whether
free
facilitated not
involved
clear in
(2, the
4)
Vol. 47, No. 2, 1972
thiamine
BIOCHEMICAL
uptake.
to separate been
tried
form
either
In order
these with
obtained
monophosphokinase
thiamine
in
(5,
cytoplasm
thiamine
taken
depending
--E. coli
K12.
(KG1673) 1.3)
have been
been
isolated
strains
the
after
which
or TPP alone
Cells
were grown
stationary been
described
14C-thiamine in
the
obtained
the
not
method
into
defi-
membrane
the
cell.
all
derivatives parent
from
KG1673 have (8) (KG1674
as -
of
14C-thiamine
(1).
of Sigma.
mCi/mmole)
at the uptake
analysis
has been
previously
Centre,
with
and harvested
cell
466
strain
(EC 2.5.
(9) supplemented
Chromatographic the
14.0
of the
of
on 1 x 10q5M thiamine.
products
Radiochemical
is
the
TMP or TPP
indicated
(1).
are the
to hold
nitrosoguanidine
medium
as described
thiazole-2-14C; from
but
The assay
same manner
and that
enzyme
derived
1 x lo-8M
otherwise
transported
presence
pyrophosphorylase
with
on a minimal
of TMP and TPP used (thiamine
are
Mutants
(7).
previously
the
a role
through in
is
source
and properties
(KG1679),
phase.
to
itself in
When this
outward
mutagenesis
1 x 10B8M TPP unless
ability
AND METHODS
grow on either
1678)
has
or TPP.
energy
thiaminephosphate described
the
membrane
state
an attempt
uptake
thiamine
experiments
The isolation
lacking
lack
6) may play
up passes
in
that
cell
on energized
used
thiamine
that
as TMP.
MATERIALS Strains
the
or exogenous
thiamine
the
the
problems,
(TMP)
suggest
across
an endogenous
probably
of
of --E. coli monophosphate
transported
cient,
these
mutants
thiamine
of either
to solve
two processes
The results actively
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
carried
of out
Preparations Thiamine-14C
hydrochloride England.
has
was
BIOCHEMICAL
Vol. 47, No. 2, 1972
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
RESULTS AND DISCUSSION The parent
strain
(KG1673) and its
(KG1679) took
up 14C-thiamine
tially
same fashion
in the
of glucose, glucose
although
shown in Fig.
the rate
strain
of
a rapid
the uptake
l4 C-thiamine profile
was essentially
or the
of
the
uptake
higher
than
amount of
14C-thiamine
at 0".
by KG1675 was lost
found This
cell
suggests
of KG1673, free
tively.
These results
of
cells
1675,
with
incubated
formed
with
the to
the
taken the
up
cell
by chromatographic
of the
uptake
14C-thiamine
in the
cell
weight
as 2.55 ml per g dry
14C-thiamine transport
analysis
the
concentra-
of KG1675 was calculated space of -E. coli
which
external
thiamine
467
to be
2 min at 37'.
(2 min),
(lo),
KG1675 cell.
for
water
in the of
in the presence
and 14C-TMP, respec-
14C-thiamine
taken
this
37',
and 1679 was found
level
an active
of uptake
at
14C-thiamine
14C-thiamine,
cellular
suggests
that
were obtained
incubated
of
rate
medium through
to be 2.4 x 10e5M when the
concentration
the
incubation
in the cell
form of thiamine
14C-TMP and 14C-TPP,
At the maximal
and then
absence
was present.
The intracellular by cells
glucose
of KG1675 was reduced
to the external
membrane when glucose
of
shown in its
10 - 15 min of in the
of the parent
presence
that
After
as that
time;
In the
slowly.
of free
as
in the absence of
decreased
tion
presence,
with
a peak at 2 min,
these
in its
absence of
a TMP auxotroph,
reaching
of glucose
the presence
by KG1675,
occurred,
radioisotope
of
in the
same as that
TPP auxotroph.
initial
the same level
medium essen-
regardless
50 % of that
showed a characteristic it
time
external
mutant
1.
The uptake
glucose
from the
with
was approximately
TPP-requiring
as its
is
24 times
is the
medium.
This
free
form in
Vol. 47, No. 2, 1972
BIOCHEMICAL
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
h 0
A
t
a
//
/
5
10 blin
Min
uptake by three Fig. 1 (left). Time course of 14C-thiamine mutants of E. coli. Cells of three mutants grown and harvested as given in the text were washed and resuspended in minimal medium (9) containing 100 pg/ml chloramphenicol with or without The uptake of 14C-thiamine was measured in the 0.4% glucose. same manner as described previously (1). The concentration of 14C-thiamine (specific activity, 14.0 mCi/mmole) added to the Open symbols represent the uptake uptake medium was 1 x lo-6M. in the presence of 0.4% glucose and closed symbols, in the A, A: KG1673; o, l : KG1675; 0, l : KG1679. absence of glucose. x: uptake of 14C-thiamine at O", which was practically identical in these three strains regardless of the presence of glucose. Fig. 2 (right). Uptake of 14C-thiamine by 4 auxotrophs for TMP. Uptake of thiamine was carried out under the same conditions as shown in Fig. 1. These 4 strains could be divided into 2 groups (KG1674 and 1678; KG1676 and 1677), which show slightly different patterns of uptake. Open symbols represent the uptake in the presence of glucose and closed symbols, in the absence of glucose. o, l : KG1674 and 1678; A, A: KG1676 and 1677.
468
15
Vol. 47, No. 2, 1972
In order up is
to show that
specific
thiamine
for
(KG1674,
although
identical
mutants
glucose
trated
for
containing
3.
decrease
KG1675 and a rapid conversely
demonstrated
This in which
assumption
was present thiamine
in the
uptake
DNP to the of
uptake
absence of
this
is
of
not
showed the
illustrated. same effect of
free
phosphorylating
with
cells
uptake
of
was
4).
glucose,
When DNP
the rate
by 40%.
of
Addition
resulted
same as that
The addition
medium
of
in a time
obtained
in the
of the uncoupler
brought
about
a rapid
at
rise
when glucose
was present,
Sodium azide
at 0.02M concentration
although
as DNP. thiamine systems
isolating
mutants
of -E. coli
dependent
loss
14C-thiamine
of
illus-
at 37O, a rapid
(Fig.
glucose
incubation
the uptake
Separation coupled
the
is
by the experiment
approximately
the
and DNP.
This
presence
KG1673 and 1679.
supported
medium without
essentially
glucose
rate
of both
medium containing
2 and 10 min after in the
uptake
completely
in these
of the
(DNP) was added
was reduced
uptake
occurs
incubation
rate
cells
was further
2,4-dinitrophenol
was not
was observed
in the
with
showed
was added to the uptake
uptake
increase
tested
as found with
of energy.
at 10 min after
in amount of the
TMP auxo-
assumed to be due to the
supply
of
2). which
When glucose
no glucose
strains
uptake
(Fig.
TMP is
TMP, the uptake
uptake
of the
strains
as an exogenous
in Fig.
course
of thiamine
once taken
4 additional
All
the radioactivity
auxotrophic
for
of
1678).
the pattern
of
of 14C-thiamine
cells
1617,
among these
The loss
loss
auxotrophic
with
same characteristics
KG1675,
of
1676,
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
the
mutants
was determined
trophs the
BIOCHEMICAL
transport
system
from the
has been established
auxotrophic taken
469
for
TMP.
up by these
by The energy-
mutants
is
Vol. 47, No. 2,1972
BIOCHEMICAL
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
5
0
10
Min
Min
Fig. 3 (left). Effect of adding glucose on the uptake of thiamine by three mutants. At the time indicated by arrow, glucose was added at 0.4% concentration to the uptake medium without glucose and incubation was continued for another 10 min. Closed symbols show the uptake after addition of glucose. A, A: KG1673; o, l : KG1675; t3, l : KG1679. The other conditions for the uptake were same as shown in Fig. 1.
Fig. 4 (right). Effect of 2,4-dinitrophenol (DNP) on the uptake by KG1675. DNP was added to the uptake medium at 2 x 10-3M. The medium was preincubated for 5 min at 37' prior to addition of 14C-thiamine. The other conditions for the uptake were same as given in Fig. 1. o: glucose added; l : both glucose and DNP added; 4: no glucose added; A: no glucose, but DNP added. assumed
to be due to
1) the
and 2) energetic
state
specific
protein
carrier It
has been
lack
of thiamine
monophosphokinase,
of the
cell
membrane
for
thiamine
is
shown recently
that 470
active
in which
the
functioning. transport
of
amino
Vol. 47, No. 2, 1972
acids
(ll),
sugars
a D-lactate it
was not
of free the
compound
probably is
supported
involved by the
to trap ly
either
removed
through the
is
property
of these
proteins
(enzymes)
(14)
an electron
transport
whether coupled
described
generated in
experiments that
suggest
that
to the
due to the or the
therefore,
concentrative
energy transport This
in Fig.
is
4.
are present, system
cytoplasm formed negatively
accumulate
as above
a high
thiamine.
binding
to
chain.
the
thiamine
TMP or TPP thus
either
coupled
same system
phosphorylation thiamine
is
to electron
of free
phosphorylate
compounds and,
to the
demonstrated
oxidative
cell
or not
by coupling
transport
transported
the
and manganese
determined
as TMP or TPP. from
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
via
results
When enzymes generated
13),
thiamine
mentioned,
system
(12,
dehydrogenase
Although uptake
BIOCHEMICAL
with
ATP
is utilized concentrativemight
not
be
charged cellular
in
the
cytoplasm.
REFERENCES T., Miyata, I., Esaki, K., and Nose, Y., Arch. 1. Kawasaki, Biochem. Biophys., 131, 223 (1969). 2. Kawasaki, T., Miyata,T, and Nose, Y., Arch. Biochem. Biophys., 131, 231 (1969). 3. Miyata, I., Kawasaki, T., and Nose, Y., Biochem. Biophys. Research Commun., 27, 601 (1967). J., and Stadtman, E. R., J. Biol. Chem., 4. Hochstadt-Ozer, 246, 5304 (1971). H., and Hayashi, R., J. Bacterial., 109, 936 5. Nakayama, (1972). A., Nishino, H., and Nose, Y., Biochim. Biophys. 6. Iwashima, Acta, 258, 333 (1972). 7. Kawasaki,., Nakata, T., and Nose, Y., J. Bacterial., 95, 1483 (1968). 8. Adelberg, E. A., Mandel, M., and Chen, G. C. C., Biochem. Biophys. Research Conunun., 2, 788 (1965). B. D., and Mingioli, E. S., J. Bacterial., 9. Davis, -60, 17 (1950). S. G., and Solomon, A. K., J. Gen. Physiol., 10. Schultz, -45, 355 (1961). 11. Kaback, H. R., and Milner, L. S., Proc. Nat. Acad. Sci., 66, 1008 (1970). E. M., Jr., and Kaback, H. R., Proc. Nat. Acad. 12. Barnes, Sci., 66, 1190 (1970). x M., Jr., and Kaback, H. R., J. Biol. Chem., 13. Barnes, 246, 5518 (1971). P., J. Bacterial., 104, 1307 (1970). 14. Bhaacharyya, 471
BIOCHEMICAL
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
THE UPTAKE SYSTEM OF FREE THIAMINE OF ESCHERICHIA COLI
Takashi
Hiroshima
Received April
Kawasaki
IN MUTANTS
and Kazuo Yamada
Department of Biochemistry University School of Medicine Hiroshima, Japan
3, 1972
SUMMARY Mutants of Escherichia coli auxotrophic for thiamine monophosphate took up I%-thiamineas its free form from the external medium against a concentration gradient regardless of the presence of glucose. The radioisotope was then transported outward in the presence of glucose, but not in its absence. 2,4-Dinitrophenol and sodium azide eliminated the effect of added glucose. The other mutant auxotrophic for thiamine pyrophosphate showed the same profile of uptake as the parent strain except for the accumulation of the radioisotope as 14C-thiamine monophosphate in the cytoplasm. The uptake a manner
similar
(2) that
the
first,
then
which
uptake
in
a membrane It
second
step,
not
conclusively
crosses
the
diffusion
or of
active
whether
the
of at
the
membrane
is
membrane
Press, Inc.
free
Thiamine
is
in
the
catalyzed
cyto-
by
(3).
It
reaction
two steps:
as its
(TPP)
probably
in
was proposed
least
carrier.
however,
by a process
transport.
accumulation
0 1972, by Academic
cell
established,
465 Copyright
2) and it
pyrophosphate which
proceeds
composed
pyrophosphokinase
thiamine
coli
(1,
by a specific
as thiamine
thiamine
is
is
through
is mediated
the
Escherichia
transport
process
passes
accumulated
plasm
in
to active
thiamine
form,
of thiamine
is
of also
as TPP is
whether
free
facilitated not
involved
clear in
(2, the
4)
Vol. 47, No. 2, 1972
thiamine
BIOCHEMICAL
uptake.
to separate been
tried
form
either
In order
these with
obtained
monophosphokinase
thiamine
in
(5,
cytoplasm
thiamine
taken
depending
--E. coli
K12.
(KG1673) 1.3)
have been
been
isolated
strains
the
after
which
or TPP alone
Cells
were grown
stationary been
described
14C-thiamine in
the
obtained
the
not
method
into
defi-
membrane
the
cell.
all
derivatives parent
from
KG1673 have (8) (KG1674
as -
of
14C-thiamine
(1).
of Sigma.
mCi/mmole)
at the uptake
analysis
has been
previously
Centre,
with
and harvested
cell
466
strain
(EC 2.5.
(9) supplemented
Chromatographic the
14.0
of the
of
on 1 x 10q5M thiamine.
products
Radiochemical
is
the
TMP or TPP
indicated
(1).
are the
to hold
nitrosoguanidine
medium
as described
thiazole-2-14C; from
but
The assay
same manner
and that
enzyme
derived
1 x lo-8M
otherwise
transported
presence
pyrophosphorylase
with
on a minimal
of TMP and TPP used (thiamine
are
Mutants
(7).
previously
the
a role
through in
is
source
and properties
(KG1679),
phase.
to
itself in
When this
outward
mutagenesis
1 x 10B8M TPP unless
ability
AND METHODS
grow on either
1678)
has
or TPP.
energy
thiaminephosphate described
the
membrane
state
an attempt
uptake
thiamine
experiments
The isolation
lacking
lack
6) may play
up passes
in
that
cell
on energized
used
thiamine
that
as TMP.
MATERIALS Strains
the
or exogenous
thiamine
the
the
problems,
(TMP)
suggest
across
an endogenous
probably
of
of --E. coli monophosphate
transported
cient,
these
mutants
thiamine
of either
to solve
two processes
The results actively
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
carried
of out
Preparations Thiamine-14C
hydrochloride England.
has
was
BIOCHEMICAL
Vol. 47, No. 2, 1972
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
RESULTS AND DISCUSSION The parent
strain
(KG1673) and its
(KG1679) took
up 14C-thiamine
tially
same fashion
in the
of glucose, glucose
although
shown in Fig.
the rate
strain
of
a rapid
the uptake
l4 C-thiamine profile
was essentially
or the
of
the
uptake
higher
than
amount of
14C-thiamine
at 0".
by KG1675 was lost
found This
cell
suggests
of KG1673, free
tively.
These results
of
cells
1675,
with
incubated
formed
with
the to
the
taken the
up
cell
by chromatographic
of the
uptake
14C-thiamine
in the
cell
weight
as 2.55 ml per g dry
14C-thiamine transport
analysis
the
concentra-
of KG1675 was calculated space of -E. coli
which
external
thiamine
467
to be
2 min at 37'.
(2 min),
(lo),
KG1675 cell.
for
water
in the of
in the presence
and 14C-TMP, respec-
14C-thiamine
taken
this
37',
and 1679 was found
level
an active
of uptake
at
14C-thiamine
14C-thiamine,
cellular
suggests
that
were obtained
incubated
of
rate
medium through
to be 2.4 x 10e5M when the
concentration
the
incubation
in the cell
form of thiamine
14C-TMP and 14C-TPP,
At the maximal
and then
absence
was present.
The intracellular by cells
glucose
of KG1675 was reduced
to the external
membrane when glucose
of
shown in its
10 - 15 min of in the
of the parent
presence
that
After
as that
time;
In the
slowly.
of free
as
in the absence of
decreased
tion
presence,
with
a peak at 2 min,
these
in its
absence of
a TMP auxotroph,
reaching
of glucose
the presence
by KG1675,
occurred,
radioisotope
of
in the
same as that
TPP auxotroph.
initial
the same level
medium essen-
regardless
50 % of that
showed a characteristic it
time
external
mutant
1.
The uptake
glucose
from the
with
was approximately
TPP-requiring
as its
is
24 times
is the
medium.
This
free
form in
Vol. 47, No. 2, 1972
BIOCHEMICAL
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
h 0
A
t
a
//
/
5
10 blin
Min
uptake by three Fig. 1 (left). Time course of 14C-thiamine mutants of E. coli. Cells of three mutants grown and harvested as given in the text were washed and resuspended in minimal medium (9) containing 100 pg/ml chloramphenicol with or without The uptake of 14C-thiamine was measured in the 0.4% glucose. same manner as described previously (1). The concentration of 14C-thiamine (specific activity, 14.0 mCi/mmole) added to the Open symbols represent the uptake uptake medium was 1 x lo-6M. in the presence of 0.4% glucose and closed symbols, in the A, A: KG1673; o, l : KG1675; 0, l : KG1679. absence of glucose. x: uptake of 14C-thiamine at O", which was practically identical in these three strains regardless of the presence of glucose. Fig. 2 (right). Uptake of 14C-thiamine by 4 auxotrophs for TMP. Uptake of thiamine was carried out under the same conditions as shown in Fig. 1. These 4 strains could be divided into 2 groups (KG1674 and 1678; KG1676 and 1677), which show slightly different patterns of uptake. Open symbols represent the uptake in the presence of glucose and closed symbols, in the absence of glucose. o, l : KG1674 and 1678; A, A: KG1676 and 1677.
468
15
Vol. 47, No. 2, 1972
In order up is
to show that
specific
thiamine
for
(KG1674,
although
identical
mutants
glucose
trated
for
containing
3.
decrease
KG1675 and a rapid conversely
demonstrated
This in which
assumption
was present thiamine
in the
uptake
DNP to the of
uptake
absence of
this
is
of
not
showed the
illustrated. same effect of
free
phosphorylating
with
cells
uptake
of
was
4).
glucose,
When DNP
the rate
by 40%.
of
Addition
resulted
same as that
The addition
medium
of
in a time
obtained
in the
of the uncoupler
brought
about
a rapid
at
rise
when glucose
was present,
Sodium azide
at 0.02M concentration
although
as DNP. thiamine systems
isolating
mutants
of -E. coli
dependent
loss
14C-thiamine
of
illus-
at 37O, a rapid
(Fig.
glucose
incubation
the uptake
Separation coupled
the
is
by the experiment
approximately
the
and DNP.
This
presence
KG1673 and 1679.
supported
medium without
essentially
glucose
rate
of both
medium containing
2 and 10 min after in the
uptake
completely
in these
of the
(DNP) was added
was reduced
uptake
occurs
incubation
rate
cells
was further
2,4-dinitrophenol
was not
was observed
in the
with
showed
was added to the uptake
uptake
increase
tested
as found with
of energy.
at 10 min after
in amount of the
TMP auxo-
assumed to be due to the
supply
of
2). which
When glucose
no glucose
strains
uptake
(Fig.
TMP is
TMP, the uptake
uptake
of the
strains
as an exogenous
in Fig.
course
of thiamine
once taken
4 additional
All
the radioactivity
auxotrophic
for
of
1678).
the pattern
of
of 14C-thiamine
cells
1617,
among these
The loss
loss
auxotrophic
with
same characteristics
KG1675,
of
1676,
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
the
mutants
was determined
trophs the
BIOCHEMICAL
transport
system
from the
has been established
auxotrophic taken
469
for
TMP.
up by these
by The energy-
mutants
is
Vol. 47, No. 2,1972
BIOCHEMICAL
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
5
0
10
Min
Min
Fig. 3 (left). Effect of adding glucose on the uptake of thiamine by three mutants. At the time indicated by arrow, glucose was added at 0.4% concentration to the uptake medium without glucose and incubation was continued for another 10 min. Closed symbols show the uptake after addition of glucose. A, A: KG1673; o, l : KG1675; t3, l : KG1679. The other conditions for the uptake were same as shown in Fig. 1.
Fig. 4 (right). Effect of 2,4-dinitrophenol (DNP) on the uptake by KG1675. DNP was added to the uptake medium at 2 x 10-3M. The medium was preincubated for 5 min at 37' prior to addition of 14C-thiamine. The other conditions for the uptake were same as given in Fig. 1. o: glucose added; l : both glucose and DNP added; 4: no glucose added; A: no glucose, but DNP added. assumed
to be due to
1) the
and 2) energetic
state
specific
protein
carrier It
has been
lack
of thiamine
monophosphokinase,
of the
cell
membrane
for
thiamine
is
shown recently
that 470
active
in which
the
functioning. transport
of
amino
Vol. 47, No. 2, 1972
acids
(ll),
sugars
a D-lactate it
was not
of free the
compound
probably is
supported
involved by the
to trap ly
either
removed
through the
is
property
of these
proteins
(enzymes)
(14)
an electron
transport
whether coupled
described
generated in
experiments that
suggest
that
to the
due to the or the
therefore,
concentrative
energy transport This
in Fig.
is
4.
are present, system
cytoplasm formed negatively
accumulate
as above
a high
thiamine.
binding
to
chain.
the
thiamine
TMP or TPP thus
either
coupled
same system
phosphorylation thiamine
is
to electron
of free
phosphorylate
compounds and,
to the
demonstrated
oxidative
cell
or not
by coupling
transport
transported
the
and manganese
determined
as TMP or TPP. from
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
via
results
When enzymes generated
13),
thiamine
mentioned,
system
(12,
dehydrogenase
Although uptake
BIOCHEMICAL
with
ATP
is utilized concentrativemight
not
be
charged cellular
in
the
cytoplasm.
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