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Applied and Environmental Microbiology, November 2000, p. 4696-4704, Vol. 66, No. 11
0099-2240/00/$04.00+0
Copyright © 2000, American Society for Microbiology. All rights reserved.
Identification and Characterization of an ATP
Binding Cassette L-Carnitine Transporter in
Listeria monocytogenes
Katy R.
Fraser,1
Duncan
Harvie,1
Peter J.
Coote,2 and
Conor P.
O'Byrne1,*
Department of Molecular and Cell Biology,
Institute of Medical Sciences, University of Aberdeen,
Foresterhill, Aberdeen AB25 2ZD, Scotland,1
and Microbiology Department, Unilever Research, Colworth
Laboratory, Sharnbrook, Bedfordshire MK44 1LQ,
England2
Received 30 May 2000/Accepted 17 August 2000
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ABSTRACT |
We identified an operon in Listeria monocytogenes EGD
with high levels of sequence similarity to the operons encoding the OpuC and OpuB compatible solute transporters from Bacillus
subtilis, which are members of the ATP binding cassette (ABC)
substrate binding protein-dependent transporter superfamily. The
operon, designated opuC, consists of four genes which are
predicted to encode an ATP binding protein (OpuCA), an extracellular
substrate binding protein (OpuCC), and two membrane-associated proteins presumed to form the permease (OpuCB and OpuCD). The operon is preceded
by a potential SigB-dependent promoter. An opuC-defective mutant was generated by the insertional inactivation of the
opuCA gene. The mutant was impaired for growth at high
osmolarity in brain heart infusion broth and failed to grow in a
defined medium. Supplementation of the defined medium with peptone
restored the growth of the mutant in this medium. The mutant was found
to accumulate the compatible solutes glycine betaine and choline to
same extent as the parent strain but was defective in the uptake of
L-carnitine. We conclude that the opuC operon
in L. monocytogenes encodes an ABC compatible solute
transporter which is capable of transporting L-carnitine
and which plays an important role in osmoregulation in this pathogen.
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INTRODUCTION |
The food-borne pathogen
Listeria monocytogenes represents a problem for the food
industry because it is found ubiquitously in nature, it can grow at
refrigeration temperatures, and it is capable of growth over a wide
range of osmotic pressures (8, 9). Like many organisms,
L. monocytogenes responds to hyperosmotic stress by
accumulating osmotically active compounds, which are not inhibitory to
enzymatic processes within the cell; these compounds are the so-called
compatible solutes. The accumulation of these solutes, termed
osmoadaptation, serves to counteract the outward flow of water, thereby
maintaining cell turgor (6, 10, 19). In L. monocytogenes, the compatible solutes betaine and carnitine are
also thought to play a role in cold adaptation. The rate of betaine
accumulation is found to be maximal at about 10°C, and growth is
stimulated almost twofold at 4°C when betaine is included in the
growth medium (20). Carnitine accumulates to higher levels (three- to fourfold) at 4°C than at 30°C (20) and is
transported at significant rates at 7°C (31).
The compounds used by bacteria as compatible solutes include amino
acids, such as proline and glutamate; quaternary amines, such as
betaine and carnitine; sugars (e.g., trehalose); and small peptides
(e.g., N-acetyl-glutaminyl-glutamine amide and
prolyl-glycyl-glycine). From among these, L. monocytogenes
is known to derive osmoprotective effects from betaine
(N,N,N-trimethylglycine
[20]), carnitine (
-hydroxy-
-[trimethyloammonio]butyrate
[4]), and small proline-containing peptides
(2). The transport of betaine and carnitine by L. monocytogenes has been studied in some detail. The extent of
betaine accumulation is directly dependent on the osmolarity of the
growth medium (20, 27, 28). The intracellular concentration
of betaine increases approximately 20-fold when the external osmolarity is raised by 1.5 M with NaCl (20). The transport rate is
osmotically activated and, at least in part, sodium driven
(11). The transport of carnitine in L. monocytogenes is ATP dependent and is mediated by a high-affinity
uptake system, with a Km of 10 µM and a
Vmax of 48 nmol min
1 mg of
protein1 (31). This system appears to be
specific for L-carnitine and the related compounds
acetylcarnitine and butyrobetaine; the presence of either proline or
betaine in excess has little effect on carnitine uptake
(31). The accumulation of carnitine is influenced by the
osmolarity of the medium, and uptake is subject to negative regulation
by preaccumulated solute (32).
For other gram-positive organisms, such as Bacillus
subtilis, Corynebacterium glutamicum, and
Lactococcus lactis, a number of compatible solute
transporters have now been well characterized. B. subtilis
has at least five solute transporters (each given the designation Opu,
for osmoprotectant uptake). OpuE is a single-component proline
transporter and a member of the sodium/solute symporter family
(34). OpuD is a single-component glycine betaine transporter (15). OpuA, OpuB, and OpuC are all closely related
transporters which belong to the ATP binding cassette (ABC) superfamily
of transporters and which can transport proline betaine and glycine betaine (OpuA); choline (OpuB); and ectoine, crotonobetaine,
-butryobetaine, carnitine, choline-O-sulfate, choline,
proline betaine, and glycine betaine (OpuC) (19). In
C. glutamicum, BetP has been identified as the main glycine
betaine transporter. It belongs to same family of transporters as OpuD
from B. subtilis and CaiT (carnitine transport) and BetT
(choline transport) from Escherichia coli (29).
In a recent study, a glycine betaine transporter was identified for L. lactis and designated BusA (betaine uptake system). It is
an ABC transporter which is closely related to the OpuA system from B. subtilis (26).
Despite several studies on the physiology of compatible solute uptake
in L. monocytogenes, not until recently have genetic approaches led to the identification of two betaine transporters in
this organism. BetL is a high-affinity secondary betaine transporter that is required for optimal growth in high-osmolarity medium (30). It is a member of a small family of transport proteins including BetT and CaiT from E. coli, BetP from C. glutamicum (29), and OpuD from B. subtilis
(19). A second transporter, designated Gbu, was identified
recently by screening of a mutant library for mutants defective in
betaine-mediated osmoprotection (21). This transporter is
encoded by three genes (gbuABC) which are closely related to
the opuAA, opuAB, and opuAC genes of
B. subtilis (18, 21). Recently, a membrane
vesicle system was used to demonstrate that the Gbu transporter can be
activated either by an osmotic gradient or by low temperatures
(12). Gbu belongs to the ABC superfamily of transporters,
which includes the ProU betaine transporter from E. coli. It
is not yet clear whether the BetL and Gbu transporters represent the
only betaine transporters in L. monocytogenes or whether one
or more others remain unidentified.
No carnitine transporter has yet been identified at the genetic level
for L. monocytogenes. Here we report the identification and
characterization of an operon from L. monocytogenes encoding a new member of the ABC superfamily. We show that this operon is
required for efficient growth under conditions of elevated osmolarity
and demonstrate that a mutation in this operon leads to a defect in the
ability to transport the solute L-carnitine.
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MATERIALS AND METHODS |
Bacterial strains and growth conditions.
The wild-type
L. monocytogenes serotype 1/2a strain EGD was used
throughout. It was grown in brain heart infusion (BHI) broth (Difco),
defined medium (DM) (2), or DM supplemented with 0.5% (wt/vol) type I peptone (Sigma) (DMP). Cultures were grown in 25 ml of
medium (in 125-ml flasks) at 30°C with aeration. Cell growth was
monitored spectrophotometrically (Ultrospec 4050; LKB, Biochrom) by
measuring the optical density at 600 nm (OD600) of 1-ml
samples taken at suitable intervals during growth. The
opuC::pAULA mutant was maintained on BHI agar
plates with 2 µg of erythromycin ml1. In liquid medium,
erythromycin selection was not used, as it was found to reduce the
growth rate. PCR was used to confirm that the
opuC::pAULA integration was stable even in the
absence of selection. The E. coli strain DH5
was used
routinely for cloning experiments. It was cultured in Luria broth at
37°C. Strains were maintained long term at 
80°C in 1-ml aliquots
after the addition of 7% (vol/vol) dimethyl sulfoxide (Sigma) to
overnight cultures.
Mutant construction.
The opuCA gene was
insertionally inactivated using the temperature-sensitive suicide
vector pAULA. This 9.2-kb plasmid carries an erythromycin resistance
marker, the pUC19 multicloning site, and a temperature-sensitive
replication origin which enables chromosomal integration events to be
selected at a nonpermissive temperature (7). Oligonucleotide
primers directed against the opuCA gene were used to amplify
a 400-bp region internal to the gene by PCR. The PCR primers (P121
[5'-TGACGGATCCACATCATGGCGGAAGATC-3'] and P117
[5'-TGACGGATCCGCTTCATCCATATCATGG-3']) used
included at their 5' ends BamHI recognition sites
(underlined) which facilitated the cloning of the PCR product into
BamHI-digested pAULA. The resulting clone, designated
pCOB26, was isolated from E. coli DH5 and used to
electrotransform L. monocytogenes EGD. Chromosomal integration of pCOB26 was selected by repeated plating at 42°C with
selection for erythromycin (2 µg ml1) resistance as
described previously (7). The integration of pCOB26 into the
opuC locus in EGD was confirmed by PCR, and the resulting
strain was designated EGD opuC::pAULA. The
vector-specific For (position 20) and Rev primers
(5'-TGTAAAACGACGGCCAGT-3' and 5'-CAGGAAACAGCTATGAC-3',
respectively) were used to confirm the absence of independently
replicating pCOB26 in the integrant strain. The PCR primers P125 and
P114 (5'-CACACGTGCCACAAGTACG-3' and
5'-CACGAGTAACAATTCCGACAAG-3', respectively), which amplify
the entire wild-type opuCA gene, were used to confirm the
insertion of pAULA in the integrant strain (no PCR product was detected
from the integrant strain). The primers P125 and For were used for
further confirmation of this integration (a PCR product was detected
only from the integrant strain).
The presence of a transcriptional terminator downstream from the
erythromycin resistance gene on pAULA (as well as the fact that pAULA
is 9.2 kb), which is oriented with the direction of opuCA
transcription, suggests that the insertion mutation is polar, thereby
inactivating the entire opuC operon. The stability of the
pAULA insertion was confirmed by PCR analysis of cultures grown without
erythromycin selection at 30°C. Even after repeated subculturing, no
plasmid excision was detected.
Cloning and sequencing.
A 4.3-kb HindIII
fragment from L. monocytogenes ScottA (which was being
investigated because a Tn917 insertion conferring acid
sensitivity mapped to this region) was sequenced and found to carry two
full open reading frames (ORFs) and a partial ORF spanning 2.3 kb at
the 3' end of the fragment. These ORFs showed high levels of sequence
similarity to the opuC and opuB operons of
B. subtilis. The sequence obtained from the 4.3-kb clone was used to design PCR primers for the amplification of this region from
L. monocytogenes EGD. The remainder of the operon was
amplified by inverse PCR. Southern analysis of the opuC
region in L. monocytogenes EGD indicated that the 3' end of
the operon was carried on a 4.2-kb ClaI fragment (data not
shown). Chromosomal DNA isolated from EGD was digested with
ClaI, purified on a Wizzard column (Promega), and ligated
with T4 DNA ligase (Roche). The ligated chromosomal DNA was then used
as a template for PCR with oligonucleotide primers directed against the
known opuC sequences. The 2.5-kb inverse PCR product
obtained was sequenced by primer walking. The sequence was obtained
from both strands using a BigDye Terminator cycle sequencing kit (PE
Applied Biosystems). The DNA sequence was determined using a
Perkin-Elmer Applied Biosystems 377 automated sequencer. The DNA
sequence obtained was analyzed using DNASTAR Inc. software on a Power
Macintosh computer.
Betaine and carnitine transport assays.
The uptake of
betaine and carnitine was measured using the method of Verheul et al.
(31), modified as follows. Cells were grown overnight in DMP
supplemented with 0.04% (wt/vol) glucose. Glucose (0.4% [wt/vol])
was added to the overnight culture, and growth was continued to an
OD600 of 0.4. This culture was then used to inoculate 100 ml of DMP (0.5% [vol/vol] inoculum). Cells were grown at 30°C with
shaking to mid-exponential phase (OD600 = 0.4). Cells
were harvested by centrifugation for 10 min at 12,000 rpm and 4°C.
The supernatant was removed, and cells were washed twice with ice-cold
assay buffer (50 mM potassium phosphate [pH 6.9], 5 mM magnesium
sulfate) containing chloramphenicol (50 µg ml1). For
studying uptake under high-osmolarity conditions, 0.5 M NaCl was added
to the assay buffer. After being washed, cells were resuspended in the
assay buffer to an OD600 of 1. The transport assay was
performed with 5 ml of cell suspension in the presence of 0.4%
(wt/vol) glucose at 30°C with stirring. Radiolabeled
L-[14C]betaine (ICN) or
L-[3H]carnitine hydrochloride (Amersham) was
added to a final concentration of 20 µM. Samples of 100 µl were
removed, immediately filtered through glass microfiber filters (Whatman
International Ltd.), and then washed twice with 2 ml of ice-cold
buffer. Filters were dried, and the radioactivity was determined by
scintillation counting. Samples (100 µl) were removed and transferred
to filters, without filtering, and dried as standards for determination
of betaine or carnitine specific activity. The total cell protein
values used to calculate solute pools were 170 µg ml1
per OD600 unit at low osmolarity and 130 µg
ml1 per OD600 unit at high osmolarity, as
previously described (2).
Measurement of steady-state solute pools.
Steady-state
carnitine or betaine pools were measured using the method of Koo and
Booth (22). Cells were grown in DMP as described above for
the uptake assays. Cultures (25 ml) in DMP (0.4% [wt/vol] glucose)
containing 200 µM betaine, carnitine, or choline were grown to an
OD600 of 0.2. A 2.5-ml aliquot was transferred to a sterile
25-ml test tube containing 10 nCi of L-[14C]betaine, 30 nCi of
L-[3H]carnitine, or 600 nCi of
[14C]choline (Amersham, Life Sciences). Incubation was
continued at 30°C with shaking. When growth in the control flask
reached an OD600 of 0.4, the test tube was removed from the
incubator. Three 0.5-ml samples were taken from the test tube, filtered
through glass microfiber filters, and washed with 3 ml of DMP (lacking betaine, carnitine, or choline). The filters were dried, and the radioactivity was determined by scintillation counting. The remaining 1 ml of culture in the test tube was transferred to a cuvette, and the
OD600 was measured. Then, 50-µl samples were removed from the cuvette and transferred to filters, without filtering, and dried as
standards for determination of betaine, carnitine, or choline specific
activity. Final solute pool values were corrected for background
radioactivity (i.e., radioactivity which was associated with the cells
and which was not removed during the washing step) as follows. Cells
were grown to an OD600 of 0.4 as described above, and then
2.5 ml was permeabilized by the addition of 5% (vol/vol) butanol and
incubation at 30°C for 30 min. Radiolabeled solute was added to the
cells, and incubated was continued for a further 30 min. Samples were
removed, filtered, and washed as described above for nonpermeabilized
cells. Background radioactivity was measured by scintillation counting,
and the values were used to correct the final solute pool calculations.
The total cell protein values used to calculate uptake rates were
170 µg ml1 per OD600 unit at low
osmolarity and 130 µg ml1 per OD600 unit at
high osmolarity, as previously described (2).
Nucleotide sequence accession number.
The GenBank accession
number for the sequence described in this paper is AF249729.
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RESULTS |
Identification of the L. monocytogenes opuC
operon.
A newly identified ORF was being investigated in L. monocytogenes ScottA. This ORF was cloned on a 4.3-kb
HindIII fragment, and the entire region was sequenced
(C. P. O'Byrne, unpublished data). Downstream of the locus being
investigated, two full ORFs and a partial ORF with high levels of
sequence homology to the opuC and opuB operons of
B. subtilis were identified. These ORFs were further
investigated, as they represented ORFs for a newly identified putative
solute transporter in L. monocytogenes. The opuC
and opuB operons of B. subtilis encode ABC
transporters capable of transporting a variety of compatible solutes
into the cell in response to increased osmolarity (15, 16, 17, 19,
24). The full sequence of the corresponding operon in L. monocytogenes EGD was obtained by a combination of PCR, inverse
PCR, and primer walking as described in Materials and Methods. EGD was
the strain of choice for this analysis, as the genome sequence for this
strain is scheduled for public release by September 2000 (see
http://www.pasteur.fr/recherche/unites/gmp/Gmp_projects.html#lm). The ScottA and EGD sequences were 94.5% identical over the
first two ORFs, although this figure may be an underestimate of their relatedness, as the ScottA sequence was obtained from one strand only
in this region and therefore may have contained sequencing errors.
Sequence analysis.
A 3,761-bp region of the EGD chromosome was
sequenced (GenBank accession number AF249729), and four ORFs were
identified (Fig. 1). ORF1, hereafter
designated opuCA, is predicted to encode a hydrophilic
protein of 397 amino acid residues (Fig.
2C) and with close sequence similarity
(71% identical, 85% similar) to OpuCA from B. subtilis. In
B. subtilis, OpuCA encodes an ATPase subunit associated with
the OpuC ABC solute transporter. The Walker A and B motifs
(35) and the linker peptide (5) are well
conserved (Fig. 2A). The initiation codon of opuCA was
identified as GTG, based on homology to the opuCA gene from
B. subtilis and because this codon is preceded by a strong
candidate Shine-Dalgarno sequence (16 to 10; 5'-ATGGAGG-3').
A potential SigB promoter was identified 58 bp upstream from the
initiation codon of ORF1 (5'-GTTTAA-N14-GGGAAA-3'), based on
a comparison with the promoter sequences of genes known to be SigB
regulated in B. subtilis and L. monocytogenes.
The 3' end of opuCA was found to be separated from the
initiation codon of ORF2 by 6 bp, including the TAA stop codon.
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FIG. 1.
Organization of the opuC operon in L. monocytogenes EGD depicted schematically. ORFs are shown as solid
arrows. The numbers in parentheses above the ORFs indicate predicted
sizes (in amino acid residues) of the protein products. A potential
transcriptional terminator is indicated (TT). The potential
SigB-dependent promoter is indicated by an angled arrow. The predicted
amino acid sequence for each ORF was used to perform BLASTP searches
(1) against the nonredundant databases (performed at
http://www.ncbi.nlm.nih.gov/BLAST/). The eight proteins with the
highest levels of sequence similarity (lowest E value
[Expect value]) are listed beneath the corresponding ORF, followed in
parentheses by the organism abbreviation and the percent identity. The
organism abbreviations are as follows: Bs, B. subtilis; Mt,
Mycobacterium tuberculosis; Ec, E. coli; Sp,
Streptococcus pneumoniae; Dr, Deinococcus
radiodurans; Af, Archaeoglobus fulgidus; Hp,
Helicobacter pylori; Sc, Streptomyces coelicolor.
Xxx, no assigned name.
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FIG. 2.
Features of the OpuC protein subunits. (A) The first 200 amino acid residues of OpuCA from L. monocytogenes (Lm) were
aligned by consensus with the corresponding N-terminal regions of OpuCa
and OpuBA from B. subtilis (Bs), and identical residues are
indicated by shading. Alignments were performed with a Clustal
algorithm (14) using MegAlign software (DNASTAR Inc). The
conserved "linker peptide" is overlined, and both Walker motifs
(35) are overlined with hatched boxes. (B) The first 40 residues of the substrate binding protein (OpuCC) from L. monocytogenes (Lm) were aligned with the corresponding regions of
OpuCC and OpuBC from B. subtilis (Bs). The predicted
processing site for the pro-OpuCC lipoprotein is indicated with an
arrowhead, and the conserved N-terminal cysteine residue is marked with
an asterisk. (C) Kyte-Doolittle (23) hydrophobicity profiles
for each of the four protein subunits of OpuC. The amino acid residue
number is indicated above the plots. The profiles were obtained with a
window of nine residues.
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ORF2, designated
opuCB, is predicted to encode a hydrophobic
protein (Fig.
2C) of 218 residues and with strong sequence homology
to
the product of the
opuCB gene of
B. subtilis
(60% identical,
80% similar). In
B. subtilis, OpuCB is a
membrane-spanning protein
(217 amino acids long) which acts as a
permease subunit in the
OpuC solute transporter. The 3' end of
opuCB was separated from
the initiation codon of ORF3 by 4 bp, including the TAA stop
codon.
ORF3 is predicted to encode a hydrophilic protein (Fig.
2C) of 308 residues and closely related to the OpuCC protein from
B. subtilis (57% identical, 75% similar). OpuCC is a 303-residue
protein which is believed to act as an extracellular substrate
binding
subunit of the OpuC transporter. It has an N-terminal
signal sequence
with the characteristic features of lipoproteins.
After processing, the
N-terminal cysteine residue is tethered
to the cell membrane via a
lipid modification (
17). The residues
required for this
modification are conserved in OpuCC from
L. monocytogenes
(Fig.
2B), indicating that this substrate binding
protein is also
likely to be tethered to the cytoplasmic membrane.
The 3' end of
opuCC is separated from the initiation codon of
the final
ORF by 17 bp, including the TAA stop
codon.
ORF4 encodes a hydrophobic polypeptide (Fig.
2C) predicted to be 223 residues long and to show a high level of sequence homology
to the
product of the corresponding gene of the
opuC operon from
B. subtilis,
opuCD (73% identical; 89%
similar). In
B. subtilis,
the OpuD protein is membrane
associated and is believed to act
as the second permease subunit in the
OpuC solute transporter,
in conjunction with
OpuCB.
An inverted repeat sequence which could function as a
rho-independent transcriptional terminator was identified 6 bp downstream
from the stop codon of
opuCD. The next ORF
detected was on the
same strand but was 112 bp downstream from the end
of
opuCD (data
not shown). Together, these factors suggest
that in
L. monocytogenes,
the
opuCA,
opuCB,
opuCC, and
opuCD genes are
likely to form an
operon which shares a high degree of sequence and
organizational
similarity with the
opuC operon from
B. subtilis.
Little is known about the regions immediately upstream and downstream
of the
opuC operon. The ORF immediately 5' of
opuCA in
L. monocytogenes EGD, including the
first 366 bp of
opuCA,
has recently been identified in a
study aimed at identifying eukaryotic
cell adhesion determinants
(
25). The gene, which is on the same
DNA strand as
opuCA, appears to play a role in adherence to the
melanoma-derived SK-Mel 28 cell line (
25). Downstream of the
opuC operon (115 bp downstream from the
opuCD
stop codon), we
have sequenced an incomplete ORF whose product has 50%
sequence
identity over 194 amino acid residues with a manganese
transport
protein from
Xylella fastidiosa. This protein
belongs to the natural
resistance-associated macrophage protein (NRAMP)
family of transporters,
which includes several bacterial manganese
transporters. The partial
ORF is also found on the same DNA strand as
the
opuC operon.
Growth characteristics of an opuC mutant.
To test
whether the opuC operon in L. monocytogenes
played any role in osmoregulation, it was mutated by insertional
inactivation of the opuCA gene as described in Materials and
Methods. The mutant was found to grow normally in BHI broth (Fig.
3a). Supplementation of the medium with
4% NaCl led to a decrease in the growth rates of the wild type and the
mutant. However, in the presence of added NaCl, the mutant was found to
grow with a specific growth rate approximately half that of the wild
type (0.41 and 0.90 h1, respectively; Fig. 3a). In
addition, the mutant formed very small colonies on BHI agar plates
supplemented with 4% NaCl, whereas growth appeared normal on BHI agar
plates without added NaCl (data not shown). Thus, inactivation of the
opuC operon in L. monocytogenes led to reduced
osmotolerance when cells were grown on BHI medium.
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FIG. 3.
Growth of EGD (open symbols) and EGD
opuCA::pAULA (solid symbols). (a) Cultures were
grown in BHI in either the presence (squares) or the absence (circles)
of 4% (wt/vol; 0.684 M) added NaCl. (b) Cultures were grown in DM
without supplementation (triangles), with 0.5% (wt/vol) peptone
(circles), or with 0.1% (wt/vol) Casamino Acids (squares).
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Attempts to grow the
opuC mutant strain in DM were
unsuccessful, despite the fact that the wild-type parent grows well in
this medium (Fig.
3b). The reason for this phenotype was unclear,
but
supplementation of the medium with 0.5% (wt/vol) peptone was
found to
enable the mutant to grow, whereas supplementation of
DM with Casamino
Acids (0.1% [wt/vol]) only partially rescued
the growth defect (Fig.
3b). The osmoprotective effect of the
peptides present in peptone
(
2) may contribute to this rescuing
effect. Several peptides
were examined in growth experiments to
determine if any could
individually restore the growth defect
of the mutant in DM. None was
found to relieve the growth defect
to the same extent as peptone (data
not shown). The growth defect
in DM was not due to the presence of
plasmid genes in the mutant
strain (which were present as a result of
the insertional inactivation
using the suicide plasmid pAULA), as the
wild-type strain transformed
with the pAULA vector grew normally in
this medium (data not shown).
The growth defect was also unlikely to
result from a secondary
mutation, as several independently isolated
integrants were found
to display the same
phenotype.
Carnitine transport is abolished in an opuC
mutant.
The close sequence similarity between OpuC from B. subtilis and OpuC from L. monocytogenes prompted us to
investigate whether the L. monocytogenes transporter was
capable of transporting carnitine (in B. subtilis, OpuC is
the sole uptake route for this compatible solute). Previous studies had
indicated that carnitine transport was ATP dependent, suggesting the
involvement of an ABC transporter. The kinetics of carnitine transport
were studied using cells grown in DMP and assayed for solute uptake in
potassium phosphate buffer, with or without added NaCl (0.5 M), in the
presence of the protein synthesis inhibitor chloramphenicol (50 µg
ml1). Under these conditions, the parent strain was found
to transport L-carnitine at a rate of approximately 10 nmol
min1 mg of cell protein1, and this rate
increased to approximately 50 nmol min1 mg of cell
protein1 when uptake was assayed in the presence of added
NaCl (Fig. 4a). In contrast, the
opuC mutant strain showed no detectable carnitine uptake
over the same time course, either with or without added NaCl. These
data indicate that carnitine transport is stimulated by hyperosmotic
shock and that both basal transport and osmotically stimulated
transport are abolished in a strain lacking the OpuC transporter.
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FIG. 4.
Compatible solute uptake in EGD (circles) or in the
opuCA::pAULA mutant derivative (squares). Cultures
were grown in DMP prior to the assay. The assay was performed with
potassium phosphate buffer with (solid symbols) or without (open
symbols) 0.5 M added NaCl. The assay was performed in the presence of
the protein synthesis inhibitor chloramphenicol (50 µg
ml1) and with 0.4% (wt/vol) added glucose.
L-[3H]carnitine hydrochloride (a) or
L-[14C]betaine (b) was added to a final
concentration of 20 µM.
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The transport of betaine, a related compatible solute, was also studied
using this assay. In the absence of added NaCl, both
the wild-type and
the
opuC mutant strains were found to accumulate
betaine at
approximately 15 nmol min
1 mg of cell
protein
1 (Fig.
4b). When 0.5 M NaCl was added to the
assay medium, the
rate increased to approximately 35 nmol
min
1 mg of cell protein
1. The presence of
the
opuC::pAULA insertion mutation therefore
had
no effect on the rate of betaine accumulation under these
assay
conditions, suggesting that OpuC is not a major route of
betaine uptake
in
L. monocytogenes.
Steady-state solute pools in an opuC mutant.
Steady-state measurements of carnitine, betaine, and choline
cytoplasmic pools were also obtained with cultures grown in DMP. Cultures were grown to mid-exponential phase in the presence or absence
of 0.5 M NaCl, and the steady-state accumulation of radiolabeled solutes was measured by removing samples for filtration and
scintillation counting as described in Materials and Methods. When
carnitine accumulation was examined, the mutant was found to accumulate only a fraction of the levels accumulated by the parent strain (Fig.
5a). Wild-type cells grown in DMP without
the addition of 0.5 M NaCl accumulated approximately four times as much
carnitine as opuC mutant cells. The addition of NaCl (0.5 M)
stimulated carnitine accumulation to approximately 400 nmol mg of cell
protein1 in the wild type, whereas the level increased
only to 80 nmol mg of cell protein1 in the mutant (Fig.
5a). Almost identical data were obtained when KCl was used as the
osmolyte. Together, these data indicate that OpuC is required for the
accumulation of high levels of carnitine under conditions of osmotic
stress. The data also suggest the presence of an alternative route for
carnitine uptake.
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|
FIG. 5.
Compatible solute pools measured at steady state.
Intracellular pools of carnitine (a), betaine (b), and choline (c) were
measured as described in Materials and Methods. Cells of EGD (WT) or
the opuCA::pAULA mutant (opuC) were
grown in DMP either with (+) or without () 0.5 M NaCl or 0.5 M KCl.
The error bars represent the standard deviation from the mean
(n = 3).
|
|
The parent strain (EGD) was found to accumulate betaine to
approximately 1,600 nmol mg of cell protein
1 when grown
in medium containing 0.5 M NaCl. This level was approximately
fivefold
higher than the level accumulated in the absence of added
salt.
Similarly, the
opuC mutant strain accumulated betaine to
a
higher level when grown in the presence of 0.5 M NaCl, although
there
was only a threefold increase in the level compared to that
in the
untreated control (Fig.
5b). This difference in the betaine
pools
between the parent and the
opuC mutant when cultures were
grown in DMP containing 0.5 M NaCl was small but reproducible.
It is
possible that this difference is related to the apparent
growth defect
of the mutant in DM (Fig.
3b). The mutant may derive
some nutrients
(i.e., peptides or amino acids) from the peptone
in DMP which allow it
to overcome the apparent auxtrophy in DM.
This accumulation of
nutrients may alter the intracellular solute
pools of the mutant enough
to affect the betaine requirement and
therefore the final betaine pool
in this medium. When 0.5 M KCl
was used as the osmolyte, only a slight
increase in betaine accumulation
was observed, and the parent and the
mutant accumulated similar
levels (Fig.
5b). This finding is consistent
with the known stimulatory
effect of Na
+ on betaine
transport in
L. monocytogenes (
11). Taken
together
with the kinetic data (Fig.
4b), these data suggest that in
L. monocytogenes, OpuC does not play a major role in betaine
accumulation.
Given the high levels of sequence homology between OpuC and OpuB in
B. subtilis, it was also important to test whether OpuC
in
L. monocytogenes was capable of transporting choline, the
only
compatible solute known to be accumulated via OpuB in
B. subtilis.
We examined the steady-state accumulation of choline in
the mutant
and wild-type strains grown in DMP with or without the
addition
of 0.5 M NaCl (Fig.
5c). In the absence of added NaCl, both
the
mutant and the wild type accumulated choline at approximately
40 nmol mg of cell protein
1. In the presence of added NaCl,
choline accumulation increased
approximately threefold in both the wild
type and the mutant.
Similarly, when the osmolarity of the growth
medium was raised
by 0.5 M with KCl instead of NaCl, an increase in
choline accumulation
was detected for both strains (Fig.
5c). These
data indicate that
choline is accumulated to a low level (compared to
carnitine and
betaine; see Fig.
5a and b) by
L. monocytogenes and that this
uptake is subject to osmotic
stimulation but is not dependent
on the OpuC transporter. The
accumulation of choline by
L. monocytogenes has not
previously been demonstrated, but the low level of transport
is
consistent with the fact that choline acts poorly as an osmoprotectant.
Patchett et al. (
27) reported that the presence of choline
(1
mM) in plates prepared with DM and supplemented with 4% (wt/vol)
NaCl provides only a slight osmoprotective
effect.
| |
DISCUSSION |
Physiological studies of L. monocytogenes have
previously shown that the uptake of carnitine is ATP dependent, and
transport was therefore predicted to occur via an ABC transporter
(31). Here we have confirmed that an ABC transporter
(designated OpuC, based on its close homology to the corresponding
transporter in B. subtilis) belonging to the binding
protein-dependent subgroup is the major carnitine uptake system in
L. monocytogenes EGD. The ATP binding domains (which include
Walker motifs [35]), which are the most characteristic
feature of the ABC transporters (5, 13), are well conserved
in the OpuCA protein (Fig. 2A). OpuC appears not to play a role in the
accumulation of betaine or choline, compatible solutes that are
chemically related to carnitine. This notion is consistent with the
finding that betaine and choline have little inhibitory effect on this
transporter, even when present at a 100-fold excess (31). It
is interesting that in B. subtilis, OpuC does have a role,
albeit a minor one, in betaine accumulation (16). The small
degree of sequence divergence between the three related transporters
(L. monocytogenes OpuC, B. subtilis OpuC, and
B. subtilis OpuB) is therefore enough to account for
considerable diversity in the substrate specificity. The determinant of
substrate specificity in binding protein-dependent ABC transporters
remains unclear, but the extracellular substrate binding subunit as
well as the permease subunits are likely to play a role
(13). In this respect, it is perhaps significant that among
the four transporter subunits, the greatest divergence is seen in the
substrate binding protein (Fig. 1).
The rate of carnitine transport in L. monocytogenes EGD is
shown here to be osmotically stimulated (Fig. 4a). This stimulation is
not dependent on increased levels of OpuC expression, as the uptake
assays were performed in the presence of chloramphenicol. The presence
of an osmotic gradient is therefore sufficient to stimulate the
activity of the carnitine uptake system in the cell. This finding is in
contrast to that of an earlier study showing that the initial rate of
uptake of carnitine or betaine was independent of the assay medium
osmolarity for cells cultured in DM (32). In that study, the
authors also showed that osmotic stimulation was observed only when the
cells were allowed to preaccumulate either betaine or carnitine,
suggesting that the accumulation of either compatible solute could
inhibit the activity of the transporter(s) and that this inhibition
could be overcome by hyperosmotic shock. In the present study, cells
were grown in DMP prior to the assay of carnitine uptake. It is
possible that the preaccumulation of peptides (supplied in peptone),
known to have an osmoprotective effect on L. monocytogenes
(2), leads to inhibition of the carnitine transporter(s) and
that this inhibition is reversed by hyperosmotic shock. In order to
test this idea, we examined rates of carnitine transport by wild-type
cells cultured in DM. The initial uptake rate was approximately 110 nmol mg1 min1 (10-fold faster than in DMP),
and this rate was found to be independent of the assay medium
osmolarity (data not shown). It seems likely, therefore, that the
activity of the carnitine transporter(s) is inhibited by preaccumulated
peptides or amino acids from the DMP growth medium and that this
inhibition can be overcome, at least partially, by osmotic stimulation.
The mechanisms underlying this regulation remain to be elucidated.
The identification of a putative SigB-dependent promoter upstream from
the opuCA gene may indicate a role for this stress-inducible (3) sigma factor in the regulation of opuC
expression. The sequence identified (at position 58) both closely
resembles the consensus 10 and 35 boxes identified for other
SigB-dependent promoters (3, 34) and shows a good match to
the conserved spacing (14 ± 1 bp) between these elements (Fig.
6). Sleator et al. (30) have
also identified a potential SigB-dependent promoter upstream of the
betL gene in L. monocytogenes. It is interesting that two genes in B. subtilis that encode compatible solute
transporters are also preceded by potential SigB-dependent promoters:
opuD, which encodes a betaine transporter, and
opuE, which encodes a proline transporter (Fig. 6)
(34). It is noteworthy that in L. monocytogenes,
a sigB mutant is impaired in its ability to use both betaine
and carnitine as osmoprotectants. In addition, betaine transport is
defective in a sigB mutant (3), although the
transport of carnitine has not been studied directly with a strain
lacking this sigma factor. Becker et al. (3) have also shown
that the transcription of sigB is strongly induced by
elevated osmolarity. Taken together, these observations suggest that
opuC may be regulated at the transcriptional level by SigB. We are currently investigating this hypothesis.
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|
FIG. 6.
Alignment of the putative opuC SigB promoter
with known SigB promoters from L. monocytogenes and B. subtilis. The sequence identified upstream from opuCA
in L. monocytogenes is shown aligned with other known or
predicted SigB promoter sequences. Genes indicated with an asterisk
have a potential SigB promoter which has not yet been confirmed
experimentally. Position is given as the distance of the final base
shown in the 10 box from the initiation codon. The alignment of
promoters was adapted and updated from the literature (3,
34).
|
|
Here we have identified the opuC operon initially on the
basis of sequence homology with opuC in B. subtilis. A recent study has also identified the opuC
operon in L. monocytogenes by screening a bank of insertion
mutants to isolate a carnitine uptake mutant (C. Hill, personal
communication). In that study, a mutant was selected that was unable to
grow on high-osmolarity medium supplemented with carnitine. The
chromosomal region surrounding the plasmid insertion in this strains
was sequenced and found to be almost identical to the sequences
described here for the opuCA and opuCB genes. It
is interesting to note that in that study, the mutant strain was also
found to have defective growth in the DM used (Hill, personal
communication). The reason for this growth defect remains unclear. It
is possible that the OpuC transporter is also capable of transporting
some component of DM (e.g., an amino acid) and that the inactivation of
OpuC therefore leads to some auxotrophy. Provision of this component in
an alternative form in the added peptone (e.g., a short peptide) may be
sufficient to overcome this auxotrophy. Further studies are under way
to address this possibility.
Given the complexity of solute transport in the related gram-positive
organism B. subtilis, where at least five solute
transporters are known to be involved in osmoregulation, it seems
possible that other compatible solute transporters remain to be
identified in L. monocytogenes. Recently, another
solute-transporting ABC transporter was identified in L. monocytogenes: the Gbu betaine transporter, which is encoded by
only three genes and which is related to the OpuA transporter in
B. subtilis (21). Evidence also exists to
indicate that peptide transport in L. monocytogenes, which
is known to relieve hyperosmotic stress (2), is also dependent on an ATP-dependent transporter (33). There is
substantial sequence similarity between OpuC and Gbu as well as between
OpuC and OpuA, and it is possible that these transporters have evolved from a common ancestor, as seems likely for OpuC and OpuB in B. subtilis (17). It is possible that other ABC solute
transporters in L. monocytogenes are responsible for
transporting other solutes or accumulating solutes under other growth
conditions. In this respect, it is interesting to note that even in the
opuC mutant, there is still a detectable carnitine pool
(approximately 20 nmol mg of cell protein1 compared to
approximately 70 nmol mg of cell protein1 in the parent).
Furthermore, this residual level of accumulation can be stimulated by
the addition of NaCl (approximately three- to fourfold) (Fig. 5a).
These data suggest that in L. monocytogenes, an alternative
route for carnitine accumulation must exist. The availability of the
L. monocytogenes genome sequence, which is due to be
released shortly (see
http://www.pasteur.fr/recherche/unites/gmp/Gmp_projects.html#lm), should allow other potential solute transporters to be identified and
classified for this important food-borne pathogen.
| |
ACKNOWLEDGMENTS |
We thank Colin Hill for sharing data prior to publication, Phil
Carter for help with the DNA sequencing, and Ian Booth and Txaro
Amezaga for helpful discussions. We also thank Trinad Chakraborty for
generously providing the plasmid pAULA.
C.P. O'Byrne is supported by an ACT(R) University of Aberdeen
fellowship. This work was funded in part by a Unilever Research CASE award.
| |
FOOTNOTES |
*
Corresponding author. Mailing address: Department of
Molecular and Cell Biology, Institute of Medical Sciences, University of Aberdeen, Foresterhill, Aberdeen AB25 2ZD, Scotland, United Kingdom.
Phone: (44 1224) 273151. Fax: (44 1224) 273144. E-mail: c.obyrne{at}abdn.ac.uk.
| |
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Abstract
Introduction
