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Heterogeneous amino acid transport rate changes in an E. coli unsaturated fatty acid auxotroph
Vol. 81,No.2, 1978 March 30, 1978
BIOCHEMICALAND BIOPHYSICALRESEARCH COMMUNICATIONS Pages
HETEROGENEOUS AMINO ACID TRANSPORT RATE CHANGES IN AN r.
588-595
COLI
UNSATURATED FATTY ACID AUXOTROPH Joseph
T. Holden, James Bolen, Joyce and John de Groot Division of Neurosciences of Hope National Medical Duarte, CA 91010
City
Received
January
A. Easton
Center
31,1978
SUMMARY - Amino acid transport rates in an E. coli unsaturated fatty acid auxotroph were non-uniformly affected by en%chment of membrane lipids in various unsaturated fatty acids. Proline and threonine transport rates were depressed much more than lysine and asparagine rates by trans unsaturated acids. Myristoleate and linolenate enrichment also produced non-uniform but lesser rate reductions. Although changes in the relative numoer of effective transport catalysts could account for these findings, comparisons of proline and lysine transport rates over a broad temperature range indicated that non-uniform alterations in transport catalyst reaction rates account at least partly for the activity changes associated with membrane lipid alterations. Several
laboratories
by membrane ported
lipid
fatty
primarily
in fatty
of various
lipid
investigations and little rates
order/disorder utilized
attention
of a variety
different
fatty
Using tarum
plots
to reduce
cellular
different
amino
transitions
is
is sup-
of membrane correlative
temperatures occurred.
on comparative
in
rate at which
Most of these
changes
as a function
lipids changes
displayed
or at most a few transport
systems
affected
conclusion
system
relative
has been focused of transport
substrates, in absolute
of growth
with
acids.
several
cultured
a single,
produced
a transport
and the
This
enrichment
points
phase
transport
(l-4).
that
at which
in Arrhenius
solute
composition
melting
temperatures
transitions membrane
acid
by the observation
acids
the relative
have shown that
E. coli
under
conditions lipid
acid
lipid-overproducing
levels
transport
of pantothenic (6), systems
acid
did
588
not
(5)
and L. plan-
restriction
we have previously
0006-291X/78/0812-0588$01,00/0 Copyright 0 1978 by Academic Press, Inc. All rights of reproduction in any form reserved.
mutants
respond
reported uniformly
sufficient that when the
EIOCHEMICAL
Vol. 81, No. 2, 1978
membrane
lipid
demonstrate several activity is
composition that
of several
the
indication
binding
proteins
in fatty
acids
was modified.
nutritional
unsaturated
acids
amino
acid
transport
may be less that
The studies
enrichment
fatty
that
AND’ 8lOPHYStCAL
reduce
of E. coli
produced transport systems
severely membrane
differential
RESEARCH COMMUNKATIONS
described membranes
here in one of
changes
in the
systems.
Of especial
dependent
on shock-releasable
affected
by membrane
interest
enrichment
fluidity.
MATERIALS AND METHODS Organisms: Experiments were carried out with E. coli unsaturated fatty acid auxotroph K1062 (provided by Dr. P. Overath). This strain also carries an altered fad E gene which limits its ability to degrade fatty acids, although there was a measurable conversion of 18:l to 16:l fatty acid in these experiments. Stock cultures were maintained on glucoseyeast extract-agar supplemented with Brij 35 (0.5%) and oleic acid (0.05%). Growth conditions: Cells were grown in Vogel Bonner medium E (VB) (7) using glycerol as carbon source. Ethanol solutions of unsaturated fatty acids were added to 0.15 mM immediately prior to inoculation. Fatty acid solubility was facilitated and toxicity minimized using bovine serum albumin (1.5 mg/ml; essentially fatty acid-free, fraction V, Sigma), Cultures were grown at 37'C with shaking. An initial overnight tube culture, using inoculum cells from an agar slant, was used to inoculate a second overnight tube culture. The inoculum was adjusted so that growth reached a cell density of 0.30 mg/ml after approximately lo-12 divisions at a convenient time on the following day. The final large-scale log phase culture was harvested at 0.30 mg/ml after lo-12 divisions (20-22 hrs). Strict control of growth conditions was required to attain reproducible (+ 5-10%) transport rates from day to day. Prior to harvest, the cultures were cooled and then centrifuged at 2,200 x 6. The cells were washed twice with cold VB lacking glycerol, fatty acid and serum albumin. Washed cells were resuspended in this medium to a density of 12 mg/ml and stored in ice until used ( cl.5 hrs). The lipid fatty acid content of chromatography. Cells grown with the as indicated in the respective acid: 60%; myristoleic acid, 29%; linolenic fatty acid.
the mutant was determined by gas following fatty acids were enriched palmitelaidic acid, 51%; elaidic acid, acid, 25% as combined 16:3 and 18:3
Transport rate measurements: Cells were preincubated for 15 minutes at 27°C in 0.9 ml of VB supplemented with glycerol (0.4%), chloramphenicol (0.1 mg/ml), and aminooxy acetic acid (2 mM). The suspension was bubbled with oxygen for 10 seconds at 30 seconds prior to initiation of the reaction. The final cell concentration was 1.2 mg/ml. The reaction was started by adding 0.1 ml of radioactive amino acid using a pipetter attached to an event marker which recorded amino acid addition, subsequent removal of 0.1 ml reaction aliquots, and their expulsion onto millipore filters covered with 1.0 ml of VB at room temperature (Q 21"~). Filters were rinsed once with 3 ml of VB. For each reaction, five consecutive
589
BtOCHEMICAL
Vol. 81, No. 2, 1978
AND 8IOPHYStCAL
RESEARCH COMMUNICATIONS
TABLE I Effect of Growth with Trans Unsaturated Fatty Acids on Amino Acid Transport by r. & Fatty Acid Auxotroph K1062 Uptake Fatty Acid Supplement Cis-Vaccenic acid (1B:l)
Rate
(9)
Proline
Threonine
Asparaqine
Lysine
100
100
100
100
Palmitelaidic acid (16:lt)
6.2
6.8
45
41
Elaidic acid
1.5
2.6
14
14
(18:lt)
Transport rates observed in cis-vaccenate-enriched cells were arbitrarily set at 100% for each amino acid. The absolute transport rates observed in were as follows (all values are pmoles Tin proline, 3.35 ? 0.19; threonind, 11.18 _ 1.04; asparagine, 0.26 + 0.043; lysine, 2.97 2 0.15.
samples were taken within the initial 12-16 seconds of incubation. Filters were immediately transferred to counting vials containing 2 ml of absolute ethanol. Radioactivity was measured by scintillation counting, and isotope content was converted to amounts of amino acid, using appropriate standards. Transport rates were determined graphically from plots of cellular amino acid content vs. incubation time. Chemicals: 14C]-labeled amino acids were obtained from New England Nuclear. [ 16 C]-Asparagine was purified as described previously (8). acids were obtained from Applied Sciences Laboratory and Sigma. All chemicals were the highest grade commercially available.
Fatty other
RESULTS Cells fatty than
grown
acids those
The rate
agine
relatively
transported observed
reductions
asparagine less
with
and lysine.
sensitive
than
several in the mutant were
greater Aspartic
proline
high
melting
point
amino
acids
at rates
grown for acid
with
proline
and lysine.
590
unsaturated
substantially
cis-vaccenic
acid
and threonine
and leucine
and threonine,
trans
(data
than
lower (Table
I).
for
not
shown)
but more sensitive
than
were aspar-
VoL81,No.
8lOCHEMlCAl AND BIOPHYSICALRESEARCH COMMUNICATIONS
2,1978
TABLE II Effect of Growth with Low Melting Point Fatty Acids on Amino Acid Transport by g. coli Fatty Acid Auxotroph K1062 Uptake Fatty Acid Supplement
Alanine
Cis-Vaccenic
acid
Myristoleic Linolenic
(18:l)
Rate
(%)
Arginine
Asparagine
100
100
100
7':
2
125 104
acid (14:l) acid (18:3)
Transport rates are expressed as a percentage of the rate observed with cis-vaccenate grown cells whose values were arbitrarily set at 100%. The transport rates observed with cis-yaccenate cells were as follows (all values are pmoles min-1 gm' ): alanine, 6.98 ? 0.46; arginine, 3.31 ? 0.44; asparagine, 0.26 + 0.043.
Lipid
enrichment
generally
had a less
Some amino like
in
acids
arginine,
more than
lower
melting
pronounced
effect
on transport
asparagine
were
not affected
like were
affected
any other
amino
myristoleate-enriched acid
melts
behavior acyl
in terms
does not
effects
of transport
tion,
lysine
slightly.
below
whether
these
of exogenously
and proline
on the
synthesis
effects.
transport
behavior
Since
in
this
of this
rates
compared
transport
rate
fatty
fatty
dichotomous
changes
acids
lipid
fatty
a broad cells
systems
591
showed
catalysts,
to answer
in cis-vaccenateover
reflected
on the reaction
of transport
In an effort
of cis-vaccenate-enriched
and proline
were
supplied
Using
lysine
was reduced
of membrane
heterogeneous
cells
the
others,
uptake
O"C, an explanation
telaidate-enriched
son,
II).
(Table
vs. asparagine
ratios
acids
significantly;
heterogeneous.
of order/disorder
of both
the response
fatty
rates
Alanine
The alanine
was clearly
catalysts,
or some combination
unsaturated
seem tenable.
was not clear
differential rates
cells
solely
It
acid.
at temperatures
chains
only
point
this
ques-
and palmi-
temperature
range.
as a basis
of compari-
different
responses
BIOCHEMICAL
Vol. 81, No. 2, 1978
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
0
0
9r--G--
d
40
OC 4.0 -
0
/
/
a
I
I
A
3.0 -
/
0
A
a
2.0 -
/I
0
&
A/
/
0
a'
/
i'-'-
\ A
r'
A
0 1.0 -
0
9/
0’ A-
./\ A-0
*:84
20
30
TEMPERATURE
to temperature proline
transport
1.
l‘t-.
AlA
10
Fig.
.
40
("C)
Effect of temperature on proline (0,)) and lysine (a,~) transport rates in E. coli K1062 grown with cis-vaccenic acid (open symbols) or palmitelaidic acid (filled symbols). Inset: variation with temperature in the ratio; transport rate in cis-vaccenate (CV) cells/transport rate in palmitelaidate (16:lt) cells for proline (0) and lysine (A).
in palmitelaidate-enriched rates
exceeded
cells lysine
rates
592
(Fig.
1).
in cis-vaccenate
Whereas cells
at
BIOCHEMICAL AND BIOPHYSICAL RESEARCH COMMUNICATIONS
Vol. 81, No. 2, 1978
all
temperatures
up to 4O"C,
enriched
cells.
declined
in activity
is
in the
acid.
for
seconds
rates
of carriers
is
modification
composition
is altered
transport
for
lipids
lysine,
unlikely
of the
variation
was modified.
to be metabolically rates,
reaction
these
rates
as an explanation
fatty of
and palmitelaidate-enriched
temperature
transport
which
this
the differential
as the
system
cells,
containing
in cis-vaccenate-
to measure
non-uniform
these
in palmitelaidate-
but not the
illustrates
and proline
required
was reversed
proline,
transition
directly
transport
complement
the
of a phase
lysine
pattern
above 32°C in palmitelaidate-enriched
1 inset
the relative cells
Furthermore,
range
Fig.
this
Since
modified data
in the 15
strongly
implicate
when the membrane
of the
the
non-identical
lipid
behavior
of
catalysts. DISCUSSION
We have previously acid
transport
lipid
systems
or bacterial
reports
acid
lipid
in several
rates
The magnitude transport
were
the most
appears,
reduced
that
case, the
lysine
either
point
trans
considerably
the
different the
fluidity
a possible
proline
were
catalyst
lysine than
is the
molecular undergoes
for
the
lipids,
or that
explanation
593
they
system transport of this
a more extensive
fatty
proline least
is
behavior. enriched
different
and proline
proline
in cells
unsaturated
study
of
of this
reduced
of
unsaturated
modifications
lysine
transporting
This
in an E. coli
examined,
and asparagine
that
distinctly but that
varied
acids
amino
(5,6).
investigation
Among the systems
sensitive,
membrane
melting
effect
systems.
with
environments
latter
of this
therefore,
associate
high
several
when the amount
to directed
facilitate amino
for
is modified
phenomenon
amenability
all
rates modified
composition
will
for
uptake
of this
whose
relatively
acid
acid
composition
Transport
that
heterogeneously
examples
auxotroph
membrane
are
fatty
additional
fatty
reported
acids. amino
and threonine
sensitive.
It
transport
systems
occur
in similar
less
affected
system. behavior conformational
by
In the might
be change
BIOCHEMICAL
Vol. 81, No. 2, 1978
than
is
required
of the
to a reduction ently
does
in membrane not depend
and possibly (9).
our
survey
dependent
systems
ment than
is
suggested
have noted
out
effects
which
demonstrate
membrane alter
fatty
the number
composition
of "carriers"
in addition
to,
temperature
change
affecting
to changes
to non-uniform since
in membrane
alterations
presumably
changes is
ments.
The finding,
of course,
effects
on "carrier"
synthesis
acid
lysine
other
groups
acid
composi-
not
alterations
rather
than,
catalysts.
1 show that
must
or
The at least
transport be attributed
of these
was fixed
in
may differentially
and proline
rates
rule
such as these
growth
component
of "carriers"
during
fatty
acids
of these
in Fig.
of the
does
is
lipids.
with
during
rates
described
fatty
enrich-
at temperatures
several
the fatty
in the reaction
the complement
rate
associated
that
the reaction
responses
acid
to reduced
experiments
synthesized
experiments
some of the dichotomous systems
rate
fatty
(4,10,11).
in interpreting
transport acid
transport
one
binder-
unfavorably
in membrane
reactions
One of the difficulties
that
activity
laboratory,
of changes
and transport
whereas
of palmitelaidate-enriched in this
appar-
such a component
in addition
system
transition
include appears
factors
system
component,
to trans
in the proline
carried
on enzymatic
it
sensitive
transport
fall
transport
systems
That
system.
phase
non-uniform
less
is more vulnerable
binding
incomplete,
are
may affect
the studies
therefore,
The proline
transport
is still
by the marked
Besides
tion
lysine
the proline
above the expected
and,
fluidity.
generally
fluidity
catalyst
on a shock-releasable
two of the
While
membrane
lysine
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
catalysts, in such experi-
out additional
heterogeneous
growth.
ACKNOWLEDGMENTS These studies were supported by grants No. GM 20395 and CA 11186 from the U.S. Public Health Service and by the Aerospace Industry Research Fund. The authors are indebted to Mr. William Laffin and Dr. Nedra M. Utech for their assistance during these studies and to Dr. Peter Overath for the r. coli fatty acid auxotroph.
8lOCHEMlCAL AND EIOPHYSICAL RESEARCH COMMUNICATIONS
Vol. 81, No. 2, 1978
REFERENCES H. U.,
and Overath,
J. Mol.
Schairer,
2.
Wilson, Comnun.
3.
Esfahani, M., Limbrick, (1971) Proc. Nat. Acad.
4.
Shechter, Biochem.
5.
Holden, J. T., Utech, N. M., Hegeman, G. D., Biochem. Biophys. Res. Comnun. 50, 266-272.
6.
Holden, J. T., Easton, Acta 382, 657-660.
7.
Vogel,
8.
Holden, 640-655.
9.
Oxender,
G., Rose, S., 38, 617-623.
and Fox,
J. T.,
Biochem.
L.,
and Gulik-Krzywicki,
J. A.,
and Bunch,
T.
44,
(1974)
and Kenyon,
J. M. (1975)
and Bunch,
J. M. (1973)
Biochim.
Biophys.
and Vagelos,
P. R. (1972)
J.
Biophys.
97-106.
Acta
307,
777-814.
10.
Mavis,
11.
Morrisett, J. D., Pownall, H. J., Plumlee, R. T., Smith, L. C., Zehner, Z. E., Esfahani, M., and Wakil, S. J. (1975) J. Biol. Chem. 250, 6969-6976.
595
J.
Eur.
Biochim.
Chem. 218,
41,
S. J.
C. N. (1973)
J. Biol.
Rev. Biochem.
Res.
and Wakil,
D. M. (1956)
Ann.
209-214.
Biophys.
and Bonner,
D. L. (1972) R. D.,
C. F. (1970)
Eiol.
A. R., Knutton, S., Oka, T., Sci. U. S. 68, 3180-3184.
E., Letellier, 49, 61-76.
H. J.,
P.
(1969)
1.
Biol.
Chem. 247,
652-659.
BIOCHEMICALAND BIOPHYSICALRESEARCH COMMUNICATIONS Pages
HETEROGENEOUS AMINO ACID TRANSPORT RATE CHANGES IN AN r.
588-595
COLI
UNSATURATED FATTY ACID AUXOTROPH Joseph
T. Holden, James Bolen, Joyce and John de Groot Division of Neurosciences of Hope National Medical Duarte, CA 91010
City
Received
January
A. Easton
Center
31,1978
SUMMARY - Amino acid transport rates in an E. coli unsaturated fatty acid auxotroph were non-uniformly affected by en%chment of membrane lipids in various unsaturated fatty acids. Proline and threonine transport rates were depressed much more than lysine and asparagine rates by trans unsaturated acids. Myristoleate and linolenate enrichment also produced non-uniform but lesser rate reductions. Although changes in the relative numoer of effective transport catalysts could account for these findings, comparisons of proline and lysine transport rates over a broad temperature range indicated that non-uniform alterations in transport catalyst reaction rates account at least partly for the activity changes associated with membrane lipid alterations. Several
laboratories
by membrane ported
lipid
fatty
primarily
in fatty
of various
lipid
investigations and little rates
order/disorder utilized
attention
of a variety
different
fatty
Using tarum
plots
to reduce
cellular
different
amino
transitions
is
is sup-
of membrane correlative
temperatures occurred.
on comparative
in
rate at which
Most of these
changes
as a function
lipids changes
displayed
or at most a few transport
systems
affected
conclusion
system
relative
has been focused of transport
substrates, in absolute
of growth
with
acids.
several
cultured
a single,
produced
a transport
and the
This
enrichment
points
phase
transport
(l-4).
that
at which
in Arrhenius
solute
composition
melting
temperatures
transitions membrane
acid
by the observation
acids
the relative
have shown that
E. coli
under
conditions lipid
acid
lipid-overproducing
levels
transport
of pantothenic (6), systems
acid
did
588
not
(5)
and L. plan-
restriction
we have previously
0006-291X/78/0812-0588$01,00/0 Copyright 0 1978 by Academic Press, Inc. All rights of reproduction in any form reserved.
mutants
respond
reported uniformly
sufficient that when the
EIOCHEMICAL
Vol. 81, No. 2, 1978
membrane
lipid
demonstrate several activity is
composition that
of several
the
indication
binding
proteins
in fatty
acids
was modified.
nutritional
unsaturated
acids
amino
acid
transport
may be less that
The studies
enrichment
fatty
that
AND’ 8lOPHYStCAL
reduce
of E. coli
produced transport systems
severely membrane
differential
RESEARCH COMMUNKATIONS
described membranes
here in one of
changes
in the
systems.
Of especial
dependent
on shock-releasable
affected
by membrane
interest
enrichment
fluidity.
MATERIALS AND METHODS Organisms: Experiments were carried out with E. coli unsaturated fatty acid auxotroph K1062 (provided by Dr. P. Overath). This strain also carries an altered fad E gene which limits its ability to degrade fatty acids, although there was a measurable conversion of 18:l to 16:l fatty acid in these experiments. Stock cultures were maintained on glucoseyeast extract-agar supplemented with Brij 35 (0.5%) and oleic acid (0.05%). Growth conditions: Cells were grown in Vogel Bonner medium E (VB) (7) using glycerol as carbon source. Ethanol solutions of unsaturated fatty acids were added to 0.15 mM immediately prior to inoculation. Fatty acid solubility was facilitated and toxicity minimized using bovine serum albumin (1.5 mg/ml; essentially fatty acid-free, fraction V, Sigma), Cultures were grown at 37'C with shaking. An initial overnight tube culture, using inoculum cells from an agar slant, was used to inoculate a second overnight tube culture. The inoculum was adjusted so that growth reached a cell density of 0.30 mg/ml after approximately lo-12 divisions at a convenient time on the following day. The final large-scale log phase culture was harvested at 0.30 mg/ml after lo-12 divisions (20-22 hrs). Strict control of growth conditions was required to attain reproducible (+ 5-10%) transport rates from day to day. Prior to harvest, the cultures were cooled and then centrifuged at 2,200 x 6. The cells were washed twice with cold VB lacking glycerol, fatty acid and serum albumin. Washed cells were resuspended in this medium to a density of 12 mg/ml and stored in ice until used ( cl.5 hrs). The lipid fatty acid content of chromatography. Cells grown with the as indicated in the respective acid: 60%; myristoleic acid, 29%; linolenic fatty acid.
the mutant was determined by gas following fatty acids were enriched palmitelaidic acid, 51%; elaidic acid, acid, 25% as combined 16:3 and 18:3
Transport rate measurements: Cells were preincubated for 15 minutes at 27°C in 0.9 ml of VB supplemented with glycerol (0.4%), chloramphenicol (0.1 mg/ml), and aminooxy acetic acid (2 mM). The suspension was bubbled with oxygen for 10 seconds at 30 seconds prior to initiation of the reaction. The final cell concentration was 1.2 mg/ml. The reaction was started by adding 0.1 ml of radioactive amino acid using a pipetter attached to an event marker which recorded amino acid addition, subsequent removal of 0.1 ml reaction aliquots, and their expulsion onto millipore filters covered with 1.0 ml of VB at room temperature (Q 21"~). Filters were rinsed once with 3 ml of VB. For each reaction, five consecutive
589
BtOCHEMICAL
Vol. 81, No. 2, 1978
AND 8IOPHYStCAL
RESEARCH COMMUNICATIONS
TABLE I Effect of Growth with Trans Unsaturated Fatty Acids on Amino Acid Transport by r. & Fatty Acid Auxotroph K1062 Uptake Fatty Acid Supplement Cis-Vaccenic acid (1B:l)
Rate
(9)
Proline
Threonine
Asparaqine
Lysine
100
100
100
100
Palmitelaidic acid (16:lt)
6.2
6.8
45
41
Elaidic acid
1.5
2.6
14
14
(18:lt)
Transport rates observed in cis-vaccenate-enriched cells were arbitrarily set at 100% for each amino acid. The absolute transport rates observed in were as follows (all values are pmoles Tin proline, 3.35 ? 0.19; threonind, 11.18 _ 1.04; asparagine, 0.26 + 0.043; lysine, 2.97 2 0.15.
samples were taken within the initial 12-16 seconds of incubation. Filters were immediately transferred to counting vials containing 2 ml of absolute ethanol. Radioactivity was measured by scintillation counting, and isotope content was converted to amounts of amino acid, using appropriate standards. Transport rates were determined graphically from plots of cellular amino acid content vs. incubation time. Chemicals: 14C]-labeled amino acids were obtained from New England Nuclear. [ 16 C]-Asparagine was purified as described previously (8). acids were obtained from Applied Sciences Laboratory and Sigma. All chemicals were the highest grade commercially available.
Fatty other
RESULTS Cells fatty than
grown
acids those
The rate
agine
relatively
transported observed
reductions
asparagine less
with
and lysine.
sensitive
than
several in the mutant were
greater Aspartic
proline
high
melting
point
amino
acids
at rates
grown for acid
with
proline
and lysine.
590
unsaturated
substantially
cis-vaccenic
acid
and threonine
and leucine
and threonine,
trans
(data
than
lower (Table
I).
for
not
shown)
but more sensitive
than
were aspar-
VoL81,No.
8lOCHEMlCAl AND BIOPHYSICALRESEARCH COMMUNICATIONS
2,1978
TABLE II Effect of Growth with Low Melting Point Fatty Acids on Amino Acid Transport by g. coli Fatty Acid Auxotroph K1062 Uptake Fatty Acid Supplement
Alanine
Cis-Vaccenic
acid
Myristoleic Linolenic
(18:l)
Rate
(%)
Arginine
Asparagine
100
100
100
7':
2
125 104
acid (14:l) acid (18:3)
Transport rates are expressed as a percentage of the rate observed with cis-vaccenate grown cells whose values were arbitrarily set at 100%. The transport rates observed with cis-yaccenate cells were as follows (all values are pmoles min-1 gm' ): alanine, 6.98 ? 0.46; arginine, 3.31 ? 0.44; asparagine, 0.26 + 0.043.
Lipid
enrichment
generally
had a less
Some amino like
in
acids
arginine,
more than
lower
melting
pronounced
effect
on transport
asparagine
were
not affected
like were
affected
any other
amino
myristoleate-enriched acid
melts
behavior acyl
in terms
does not
effects
of transport
tion,
lysine
slightly.
below
whether
these
of exogenously
and proline
on the
synthesis
effects.
transport
behavior
Since
in
this
of this
rates
compared
transport
rate
fatty
fatty
dichotomous
changes
acids
lipid
fatty
a broad cells
systems
591
showed
catalysts,
to answer
in cis-vaccenateover
reflected
on the reaction
of transport
In an effort
of cis-vaccenate-enriched
and proline
were
supplied
Using
lysine
was reduced
of membrane
heterogeneous
cells
the
others,
uptake
O"C, an explanation
telaidate-enriched
son,
II).
(Table
vs. asparagine
ratios
acids
significantly;
heterogeneous.
of order/disorder
of both
the response
fatty
rates
Alanine
The alanine
was clearly
catalysts,
or some combination
unsaturated
seem tenable.
was not clear
differential rates
cells
solely
It
acid.
at temperatures
chains
only
point
this
ques-
and palmi-
temperature
range.
as a basis
of compari-
different
responses
BIOCHEMICAL
Vol. 81, No. 2, 1978
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
0
0
9r--G--
d
40
OC 4.0 -
0
/
/
a
I
I
A
3.0 -
/
0
A
a
2.0 -
/I
0
&
A/
/
0
a'
/
i'-'-
\ A
r'
A
0 1.0 -
0
9/
0’ A-
./\ A-0
*:84
20
30
TEMPERATURE
to temperature proline
transport
1.
l‘t-.
AlA
10
Fig.
.
40
("C)
Effect of temperature on proline (0,)) and lysine (a,~) transport rates in E. coli K1062 grown with cis-vaccenic acid (open symbols) or palmitelaidic acid (filled symbols). Inset: variation with temperature in the ratio; transport rate in cis-vaccenate (CV) cells/transport rate in palmitelaidate (16:lt) cells for proline (0) and lysine (A).
in palmitelaidate-enriched rates
exceeded
cells lysine
rates
592
(Fig.
1).
in cis-vaccenate
Whereas cells
at
BIOCHEMICAL AND BIOPHYSICAL RESEARCH COMMUNICATIONS
Vol. 81, No. 2, 1978
all
temperatures
up to 4O"C,
enriched
cells.
declined
in activity
is
in the
acid.
for
seconds
rates
of carriers
is
modification
composition
is altered
transport
for
lipids
lysine,
unlikely
of the
variation
was modified.
to be metabolically rates,
reaction
these
rates
as an explanation
fatty of
and palmitelaidate-enriched
temperature
transport
which
this
the differential
as the
system
cells,
containing
in cis-vaccenate-
to measure
non-uniform
these
in palmitelaidate-
but not the
illustrates
and proline
required
was reversed
proline,
transition
directly
transport
complement
the
of a phase
lysine
pattern
above 32°C in palmitelaidate-enriched
1 inset
the relative cells
Furthermore,
range
Fig.
this
Since
modified data
in the 15
strongly
implicate
when the membrane
of the
the
non-identical
lipid
behavior
of
catalysts. DISCUSSION
We have previously acid
transport
lipid
systems
or bacterial
reports
acid
lipid
in several
rates
The magnitude transport
were
the most
appears,
reduced
that
case, the
lysine
either
point
trans
considerably
the
different the
fluidity
a possible
proline
were
catalyst
lysine than
is the
molecular undergoes
for
the
lipids,
or that
explanation
593
they
system transport of this
a more extensive
fatty
proline least
is
behavior. enriched
different
and proline
proline
in cells
unsaturated
study
of
of this
reduced
of
unsaturated
modifications
lysine
transporting
This
in an E. coli
examined,
and asparagine
that
distinctly but that
varied
acids
amino
(5,6).
investigation
Among the systems
sensitive,
membrane
melting
effect
systems.
with
environments
latter
of this
therefore,
associate
high
several
when the amount
to directed
facilitate amino
for
is modified
phenomenon
amenability
all
rates modified
composition
will
for
uptake
of this
whose
relatively
acid
acid
composition
Transport
that
heterogeneously
examples
auxotroph
membrane
are
fatty
additional
fatty
reported
acids. amino
and threonine
sensitive.
It
transport
systems
occur
in similar
less
affected
system. behavior conformational
by
In the might
be change
BIOCHEMICAL
Vol. 81, No. 2, 1978
than
is
required
of the
to a reduction ently
does
in membrane not depend
and possibly (9).
our
survey
dependent
systems
ment than
is
suggested
have noted
out
effects
which
demonstrate
membrane alter
fatty
the number
composition
of "carriers"
in addition
to,
temperature
change
affecting
to changes
to non-uniform since
in membrane
alterations
presumably
changes is
ments.
The finding,
of course,
effects
on "carrier"
synthesis
acid
lysine
other
groups
acid
composi-
not
alterations
rather
than,
catalysts.
1 show that
must
or
The at least
transport be attributed
of these
was fixed
in
may differentially
and proline
rates
rule
such as these
growth
component
of "carriers"
during
fatty
acids
of these
in Fig.
of the
does
is
lipids.
with
during
rates
described
fatty
enrich-
at temperatures
several
the fatty
in the reaction
the complement
rate
associated
that
the reaction
responses
acid
to reduced
experiments
synthesized
experiments
some of the dichotomous systems
rate
fatty
(4,10,11).
in interpreting
transport acid
transport
one
binder-
unfavorably
in membrane
reactions
One of the difficulties
that
activity
laboratory,
of changes
and transport
whereas
of palmitelaidate-enriched in this
appar-
such a component
in addition
system
transition
include appears
factors
system
component,
to trans
in the proline
carried
on enzymatic
it
sensitive
transport
fall
transport
systems
That
system.
phase
non-uniform
less
is more vulnerable
binding
incomplete,
are
may affect
the studies
therefore,
The proline
transport
is still
by the marked
Besides
tion
lysine
the proline
above the expected
and,
fluidity.
generally
fluidity
catalyst
on a shock-releasable
two of the
While
membrane
lysine
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
catalysts, in such experi-
out additional
heterogeneous
growth.
ACKNOWLEDGMENTS These studies were supported by grants No. GM 20395 and CA 11186 from the U.S. Public Health Service and by the Aerospace Industry Research Fund. The authors are indebted to Mr. William Laffin and Dr. Nedra M. Utech for their assistance during these studies and to Dr. Peter Overath for the r. coli fatty acid auxotroph.
8lOCHEMlCAL AND EIOPHYSICAL RESEARCH COMMUNICATIONS
Vol. 81, No. 2, 1978
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