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Previous Article | Next Article 
Infect Immun, August 1998, p. 3591-3596, Vol. 66, No. 8
0019-9567/98/$04.00+0
Copyright © 1998, American Society for Microbiology. All rights reserved.
Receptor-Mediated Recognition and Uptake of Iron
from Human Transferrin by Staphylococcus aureus and
Staphylococcus epidermidis
Belinda
Modun,1 2
Robert W.
Evans,3
Christopher L.
Joannou,3 and
Paul
Williams1 2 4 *
School of Pharmaceutical Sciences, University
of Nottingham, University Park, Nottingham NG7
2RD,1
Institute of Infections and
Immunity,2 and
School of Clinical
Laboratory Sciences,4 University of
Nottingham, Queens Medical Centre, Nottingham NG7 2UH, and
Division of Biochemistry and Molecular Biology, U.M.D.S.,
Guy's Hospital, London SE1 9RT,3 United
Kingdom
Received 17 February 1998/Returned for modification 31 March
1998/Accepted 29 May 1998
 |
ABSTRACT |
Staphylococcus aureus and Staphylococcus
epidermidis both recognize and bind the human iron-transporting
glycoprotein, transferrin, via a 42-kDa cell surface protein receptor.
In an iron-deficient medium, staphylococcal growth can be promoted by
the addition of human diferric transferrin but not human
apotransferrin. To determine whether the staphylococcal transferrin
receptor is involved in the removal of iron from transferrin, we
employed 6 M urea-polyacrylamide gel electrophoresis, which separates
human transferrin into four forms (diferric, monoferric N-lobe, and
monoferric C-lobe transferrin and apotransferrin). S. aureus and S. epidermidis but not
Staphylococcus saprophyticus (which lacks the transferrin
receptor) converted diferric human transferrin into its apotransferrin
form within 30 min. During conversion, iron was removed sequentially
from the N lobe and then from the C lobe. Metabolic poisons such as sodium azide and nigericin inhibited the release of iron from human
transferrin, indicating that it is an energy-requiring process. To
demonstrate that this process is receptor rather than siderophore mediated, we incubated (i) washed staphylococcal cells and (ii) the
staphylococcal siderophore, staphyloferrin A, with porcine transferrin,
a transferrin species which does not bind to the staphylococcal
receptor. While staphyloferrin A removed iron from both human and
porcine transferrins, neither S. aureus nor S. epidermidis cells could promote the release of iron from porcine transferrin. In competition binding assays, both native and recombinant N-lobe fragments of human transferrin as well as a naturally occurring human transferrin variant with a mutation in the C-lobe blocked binding
of 125I-labelled transferrin. Furthermore, the
staphylococci removed iron efficiently from the iron-loaded N-lobe
fragment of human transferrin. These data demonstrate that the
staphylococci efficiently remove iron from transferrin via a
receptor-mediated process and provide evidence to suggest that there is
a primary receptor recognition site on the N-lobe of human transferrin.
| |
INTRODUCTION |
One common factor among the complex
interactions which occur between a bacterial pathogen and its host is
the ability of the invading pathogen to multiply in host tissues. In
extracellular mammalian body fluids, the iron transport proteins
transferrin and lactoferrin maintain the level of free ionic iron at a
level (about 10
18 M) which is far too low to sustain
bacterial growth (6, 43). In spite of this, pathogenic
bacteria clearly multiply successfully in vivo to establish an
infection. Since all known bacterial pathogens need iron to multiply,
it can be argued that they must be able to adapt to the severely
iron-restricted extracellular environment usually found in vivo and
develop mechanisms for assimilating transferrin- or lactoferrin-bound
iron. Such high-affinity iron-scavenging mechanisms capable of removing
iron from transferrins have been intensively investigated in
gram-negative bacteria, where they depend either on the synthesis and
secretion of low-molecular-mass iron chelators (siderophores) or,
alternatively, on direct contact between the host transferrin and a
surface receptor (for reviews, see references 9, 18,
and 43). While siderophores remove iron from
transferrin irrespective of its origin, bacterial transferrin receptors
exhibit significant specificity for the transferrins of their natural
hosts. For example, Haemophilus influenzae, Neisseria meningitidis, and Neisseria gonorrhoeae exhibit a
marked preference for human transferrin (18, 43) while the
porcine pathogen Actinobacillus (Haemophilus)
pleuropneumoniae is able to bind and use pig but not human
transferrin as an iron source (17, 32, 33). Furthermore,
gonococcal transferrin receptor mutants are incapable of causing
experimental urethritis in human male volunteers, demonstrating for the
first time that an iron acquisition system is an essential virulence
factor for human infection (11).
In contrast, the mechanism(s) by which the gram-positive staphylococci
acquire iron from transferrin has not been fully elucidated. Early work
by Schade (37) indicated that Staphylococcus
aureus grows in human serum which contains transferrin, implying
that staphylococci are able to utilize glycoprotein-bound iron.
Staphylococci have been shown to secrete siderophores such as
staphyloferrin A and staphyloferrin B which, chemically, are
carboxylate-type siderophores (20, 25, 29). They have also
been reported to employ primary metabolites such as 
-ketoacids and
-hydroxyacids as siderophores (23). More recently,
a new S. aureus siderophore termed
"aureochelin" has been identified and partially
characterized (12). Whether these siderophores are capable
of removing iron from transferrin has not been determined. However,
Lindsay et al. (27) reported that S. aureus but
not Staphylococcus epidermidis could remove iron from
55Fe-labelled transferrin via a process which did not
require transferrin-staphylococcus cell surface contact and which
therefore was assumed to be siderophore mediated.
Previously we identified a saturable specific receptor for transferrin
on the surface of S. aureus and a number of different species of coagulase-negative staphylococci, including S. epidermidis (30). This receptor involves a 42-kDa cell
wall transferrin-binding protein which, in common with the
gram-negative bacterial transferrin binding proteins, exhibits
considerable transferrin species specificity. Human, rabbit, and rat
serum transferrins but not bovine or porcine serum transferrins or hen
ovotransferrin compete efficiently with the 125I-labelled
human transferrin for the S. aureus and S. epidermidis transferrin receptor (30). Furthermore,
staphylococci recovered without subculture from an implanted peritoneal
chamber in rats are coated with surface-bound transferrin and express
the 42-kDa transferrin-binding protein (31). The presence of
a cell surface transferrin-binding protein, which, in many
staphylococci, is iron regulated (30) suggests that this
receptor may contribute to virulence by facilitating the acquisition of
transferrin-bound iron.
Human transferrin is an approximately 80-kDa monomeric protein
consisting of 679 amino acid residues with two N-linked glycan chains
and can be divided into two homologous domains, referred to as the N
and C lobes, each of which contains an iron-binding site (2,
42). Each site binds one ferric ion atom coordinated with a
bicarbonate anion. Amino acid sequencing of the two transferrin lobes
has revealed that they have a high degree of homology and may have
arisen by gene duplication (42). Approximately 42% of amino
acids in the N lobe have an identical counterpart in the C lobe which
also contains both glycan chains (21). It is therefore
possible that, since both human apotransferrin and diferric human
transferrin have similar affinities for the staphylococcal receptor
(30), the primary receptor-binding site on transferrin is
located within a single domain, as the two domains within a given lobe
undergo substantial conformational changes upon iron binding
(19).
In the present work, we explore the contribution of the staphylococcal
receptor to the acquisition of iron from transferrin and provide
evidence that there is a primary receptor recognition site on the N
lobe of human transferrin.
| |
MATERIALS AND METHODS |
Bacterial strains and growth conditions.
S. aureus BB
was obtained from J. P. Arbuthnott (University of Strathclyde,
Glasgow, United Kingdom); S. epidermidis 138 and Staphylococcus saprophyticus 907 were isolated from the
peritoneal dialysis fluid of infected patients undergoing continuous
ambulatory peritoneal dialysis (41). Staphylococci were
grown in an iron-depleted, serum-free tissue culture medium (RPMI 1640;
Sigma) statically for 18 h at 37°C in air enriched with 5%
CO2. Iron was removed from the RPMI by batch incubation
with 6% (wt/vol) Chelex 100 (Sigma) for 18 h as described before
(22). After removal of the resin, calcium chloride (10 µM)
and magnesium sulfate (100 µM) were added and the medium was filter
sterilized. For some experiments, iron-depleted RPMI was supplemented
with either diferric human transferrin (250 µM protein) or with
ferric chloride (25 µM). Growth of staphylococci was followed by
measuring the optical density at 600 nm at 1-h intervals for 24 h.
Preparation of transferrins.
Human transferrin was isolated
from outdated plasma by ammonium sulphate precipitation and
ion-exchange chromatography. Porcine transferrin was purchased from
First Link, Briarley Hill, West Midlands, United Kingdom. Transferrins
were made iron saturated by the addition of iron(III) nitrilotriacetate
to transferrin dissolved in 1 M NaHCO3. Unbound iron was
removed by gel filtration on Sephadex G-25 equilibrated with 0.05 M
NH4HCO3, and the protein-containing fractions
were collected and lyophilized (15). The iron saturation of
the protein was confirmed by electrophoresis on a 6 M
urea-polyacrylamide gel (see below). The C-lobe human transferrin
variant from a subject heterozygous for an abnormal transferrin
(14) was isolated by immunoaffinity chromatography and
ion-exchange chromatography on a Pharmacia LKB (Uppsala, Sweden) HP
Q-Sepharose column as previously described (15). The
N-terminal lobe of human transferrin was prepared as described by Evans
et al. (15) by digestion of the diferric protein in 0.1 M
NaHCO3, pH 8.3, with subtilisin (Sigma) for 6 h at
37°C at an enzyme/protein ratio of 1/30 (wt/wt). The digest was
fractionated by gel filtration on a Sephacryl S-200 column (2.4 by 120 cm) equilibrated with 0.1 M NH4HCO3. The 36-kDa fragment obtained had the characteristic absorption band of iron transferrin at 470 nm and lacked carbohydrate. The recombinant N lobe
of human transferrin was expressed in baby hamster kidney cells and
purified from culture fluid by immunoaffinity and ion-exchange chromatography as described by Zak et al. (47).
Preparation of 125I-labelled human transferrin.
Two hundred microliters of a 100-µg/ml solution of Iodogen (Pierce
and Warriner, Chester, United Kingdom) in dichloromethane was added to
a 4-ml test tube, and the dichloromethane was allowed to evaporate by
rotating in a water bath at 37°C. Three hundred micrograms of
iron-saturated human transferrin (Sigma) and approximately 6 MBq of
carrier-free 125I-labelled sodium iodide (Amersham
International plc, Little Chalfont, United Kingdom) were added to each
Iodogen-coated tube in 300 µl of phosphate-buffered saline (PBS), pH
7.4. The mixture was incubated with agitation at room temperature for
15 min, and the unincorporated 125I was removed by passing
the 125I-transferrin down a Sephadex G-25 column
(Pharmacia) preequilibrated with PBS containing 0.25% (wt/vol)
transferrin.
Transferrin binding assays.
Competitive binding assays were
carried out essentially as described by Modun et al. (30).
Briefly, iron-depleted staphylococci (108 CFU) were washed,
resuspended in 1 ml of PBS and incubated with diferric human
125I-transferrin (4 nM) in the presence of 700 nM of
unlabelled diferric human (normal or C-lobe variant) or porcine
transferrin or the monoferric transferrin N lobe (subtilisin generated
or recombinant). After 30 min of incubation, bacteria were pelleted and
washed three times in PBS and transferred to a fresh microcentrifuge tube and the amount of cell-associated 125I-transferrin was
determined with an LKB 1282 Compugamma counter (Pharmacia LKB).
Specific binding was defined as the difference between the amounts of
125I-human transferrin bound in the absence and presence of
a 100-fold excess of the unlabelled ligand.
6 M urea-polyacrylamide gel electrophoresis.
Iron removal
from transferrins by staphylococcal cells and by the siderophore
staphyloferrin A (kindly provided by G. Winkelmann, Tübingen,
Germany) was monitored over time by 6 M urea-polyacrylamide gel
electrophoresis (13, 28). S. epidermidis,
S. aureus, and S. saprophyticus grown in
iron-depleted RPMI were washed and resuspended in PBS before incubation
with 250 µg of diferric human transferrin or the recombinant
monoferric N lobe of human transferrin in the presence or absence of
glucose (0.2% wt/vol) at 37°C for intervals of 5, 10, 20, 30, and 60 min. Bacterial cells were centrifuged, and the supernatant containing
transferrin was loaded onto a 6 M urea-polyacrylamide gel prepared by
the method of Evans and Williams (13). The pH of the
supernatant was monitored during each experiment to ensure that loss of
iron from the protein was not a direct result of acidification of the
medium through the metabolism of glucose. In addition, supernatants
were assayed for the presence of siderophores by using the universal
chrome azurol S assay system of Schwyn and Neilands (38).
For some experiments, the staphylococcal siderophore staphyloferrin A
(250 µg/ml) was used instead of whole cells. Electrophoresis was
performed at 100 V for 4 h in Tris-borate-EDTA buffer (pH 7.4),
and the gel was stained with Coomassie brilliant blue. To determine
whether the release of iron from transferrin by whole staphylococcal
cells is an energy-requiring process, the metabolic poison sodium azide or nigericin (both from Sigma) was included in the reaction mixtures at
concentrations ranging from 0 to 6 mM (26, 36).
| |
RESULTS |
Utilization of iron-bound transferrin.
Figure
1A shows that in iron-depleted RPMI, the
growth of S. aureus is not supported unless the medium is
supplemented with an iron source such as ferric chloride. Growth was
also promoted by diferric human transferrin but not by apotransferrin.
Similar results were obtained for S. epidermidis (Fig. 1B).
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FIG. 1.
Utilization of transferrin-bound iron by S. aureus (A) and S. epidermidis (B). Staphylococci were
grown in RPMI ( ), iron-depleted RPMI ( ), iron-depleted RPMI
supplemented with human diferric transferrin ( ), human
apotransferrin ( ), or ferric chloride ( ). Growth was monitored by
measuring optical density (O.D.) at 600 nm at 1-h intervals over
18 h.
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|
Removal of iron from human transferrin.
Since transferrin has
two binding sites for iron, we used 6 M urea-polyacrylamide gel
electrophoresis to follow the release of iron from diferric human
transferrin. This technique is capable of resolving a partially
iron-saturated sample of human transferrin into four forms,
apotransferrin, C-terminal monoferric transferrin, N-terminal
monoferric transferrin, and diferric transferrin (13, 16, 28,
44). When incubated in PBS supplemented with glucose, S. aureus converted diferric human transferrin into its
apotransferrin form within 30 min (Fig.
2). During this time, the pH of the
incubation buffer decreased from pH 7.4 to 6.6 after 60 min of
incubation. However, such a small reduction does not influence the
release of iron from transferrin. Furthermore, iron is clearly removed sequentially, first from the N lobe of diferric transferrin, as shown
by the accumulation of the monoferric C lobe (Fig. 2). This monoferric
transferrin is then converted to the apoprotein (Fig. 2). Similar
results were obtained for S. epidermidis (data not shown). In contrast, S. saprophyticus, which lacks the
transferrin receptor and 42-kDa transferrin-binding protein
(30), was unable to remove iron from human transferrin (data
not shown).
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FIG. 2.
Time course experiment showing (by 6 M
urea-polyacrylamide gel electrophoresis) the removal of iron from
diferric human transferrin by S. aureus. Staphylococci
(108 CFU/ml) were incubated in PBS buffer plus glucose with
250 µg of diferric human transferrin at 37°C for 0 (lane 1), 5 (lane 2), 10 (lane 3), 20 (lane 4), 30 (lane 5), and 60 (lane 6) min.
Cells were pelleted by centrifugation, and the supernatant was loaded
onto a 6 M urea-polyacrylamide gel. Human apotransferrin (lane 7) and
a mixture of human diferric and monoferric N-lobe transferrin (lane 8)
are shown as controls. The positions of diferric (DF), monoferric
N-lobe (MN), and monoferric C-lobe (MC) transferrins and
apotransferrins (AP) are indicated on the right- and left-hand sides of
the figure.
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|
Removal of iron from transferrin is an energy-requiring
process.
When incubated in PBS without glucose, neither
S. aureus (Fig. 3A)
nor S. epidermidis (data not shown) was able to remove iron
from diferric human transferrin. Similarly, when incubated in PBS plus
glucose in the presence of a range of concentrations of sodium azide or
nigericin, we observed that S. aureus was unable to promote
the release of transferrin-bound iron at a concentration of 6 mM sodium
azide (Fig. 3B) or 4 mM nigericin (data not shown). By reducing the
azide or nigericin concentration to 2 mM, the removal of iron from
transferrin stalled at the monoferric C-lobe form (Fig. 3C).
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FIG. 3.
Gels (6 M urea-polyacrylamide) showing the removal of
iron from diferric human transferrin by S. aureus in the
presence and absence of glucose (A) and the effect of sodium azide on
the receptor-mediated removal of iron from human transferrin by
S. aureus (B and C). (A) Staphylococci were incubated in PBS
without (lanes 1 to 3) or with (lanes 5 to 7) glucose at 37°C for 0 (lanes 1 and 5), 20 (lanes 2 and 6), and 60 (lanes 3 and 7) min and
pelleted by centrifugation, and the supernatant was loaded onto a
urea-polyacrylamide gel. As controls, lanes 4 and 8 contain diferric
human transferrin. The positions of each of the four forms of
transferrin are indicated on the right-hand side. (B) Staphylococci
(108 CFU/ml) were incubated in PBS plus glucose at 37°C
with diferric human transferrin in the presence of 6 mM sodium azide
for 0 (lane 3), 5 (lane 4), 20 (lane 5), and 60 (lane 6) min. Cells
were pelleted, and the supernatant was loaded onto the
urea-polyacrylamide gel. Diferric human transferrin (lane 1) and human
apotransferrin (lane 2) were loaded as controls. (C) Staphylococci
(108 CFU/ml) were incubated in PBS plus glucose at 37°C
with diferric human transferrin in the presence of 2 mM sodium azide
for 0 (lane 1), 5 (lane 2), 20 (lane 3), and 60 (lane 4) min. Cells
were pelleted, and the supernatant was loaded onto the
urea-polyacrylamide gel. The positions of diferric and monoferric C
transferrins and apotransferrins are indicated on the left-hand side.
Abbreviations: AP, human apotransferrin; DF, diferric human
transferrin; MC, monoferric C-lobe transferrin; MN, monoferric N-lobe
transferrin.
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Receptor-mediated removal of iron from transferrin.
To confirm
that the removal of iron from transferrin by staphylococcal cells was
receptor rather than siderophore mediated, we exploited our previous
observation that staphylococci exhibit a preference for certain
transferrins (30). Although porcine transferrin is unable to
block the binding of human transferrin to the staphylococcal
transferrin receptor (30), siderophores do not exhibit such
transferrin species specificity (43). When incubated with
porcine transferrin, washed S. aureus cells are unable to
remove iron from porcine transferrin over a 60-min period; the same
results were obtained for S. epidermidis (data not shown). In addition, by using the universal chrome azurol S siderophore assay
(38), we were unable to detect any iron-chelating activity in the PBS plus glucose incubation buffer during the time course of the
experiment. However, when incubated with the purified staphylococcal siderophore staphyloferrin A, both human and porcine diferric transferrins were converted to their respective apotransferrin forms
(Fig. 4).
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FIG. 4.
Gels (6 M urea-polyacrylamide) showing the removal of
iron from human (A) and porcine (B) transferrin by the staphylococcal
siderophore staphyloferrin A. The siderophore was incubated in PBS plus
glucose at 37°C for 60 min. (A) Samples were removed at 0 (lane 3), 5 (lane 4), 20 (lane 5), and 60 (lane 6) min. Lanes 1 and 2 contain
diferric transferrin and human apotransferrin as controls. (B) Samples
were removed after incubation with porcine transferrin for 0 (lane 1),
20 (lane 2), and 60 (lane 3) min. The positions of diferric transferrin
(DF) and apotransferrin (AP) are indicated on the left-hand side.
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Receptor-mediated recognition of human transferrin by the
staphylococcal transferrin receptor.
Since both S. aureus and S. epidermidis removed iron initially from
the N lobe of intact human transferrin, we sought to determine whether
any receptor binding sites were located within the transferrin N lobe.
In competitive binding assays, the binding of 125I-labelled
diferric human transferrin was blocked to the same extent by unlabelled
transferrin and both the subtilisin-generated and recombinant N lobes
of human transferrin (Fig. 5). In
addition, a naturally occurring human transferrin variant with a
mutation in the C lobe (14) which perturbs the iron-binding
site and the conformation of the C lobe (15) also
efficiently blocked the binding of intact normal transferrin (Fig. 5).
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FIG. 5.
Whole-cell competition binding assay showing the
inhibition of binding of human 125I-transferrin to
staphylococci by the subtilisin-generated and recombinant N lobe of
human transferrin. Staphylococci (108 CFU/ml) were
incubated with 125I-transferrin (4 nM) in the presence of
700 nM of one of the following unlabelled transferrins: human (HTf),
human C-lobe variant (CVHTf), porcine (POTf), subtilisin generated
human N lobe (NSHTf), and recombinant human N lobe (NRHTf). After 30 min at 37°C, bacteria were pelleted and the amount of cell-associated
125I-transferrin was determined. Data presented are the
means of three independent experiments + standard deviations
(error bars).
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Removal of iron from the N lobe of human transferrin.
To
determine whether the staphylococci could remove iron from the
single-sited N lobe of human transferrin alone, we performed 6 M
urea-polyacrylamide gel electrophoresis on the supernatants obtained
following the incubation of S. aureus or S. epidermidis with the recombinant iron-binding protein. Figure
6 shows that S. aureus
efficiently removes iron from the single-sited protein within 5 min of
incubation; similar results were obtained with S. epidermidis (data not shown).
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FIG. 6.
Gel (6 M urea-polyacrylamide) showing the removal of
iron from the N-lobe fragment of human transferrin. S. aureus (108 CFU/ml) were incubated in PBS plus glucose
and 250 µg of the recombinant monoferric N lobe for intervals of 0 (lane 1), 5 (lane 2), 10 (lane 3), 20 (lane 4), 30 (lane 5), and 60 (lane 6) min. Bacterial cells were pelleted, and the supernatant was
loaded onto the urea gel. The positions of the iron-loaded N lobe (MS)
and apoprotein (AP) are indicated on the left-hand side.
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| |
DISCUSSION |
The present study was initiated to determine whether the
staphylococcal transferrin receptor identified previously as a 42-kDa transferrin binding protein (30) contributes to the
acquisition of iron from human transferrin. In an iron-depleted medium,
the growth of both S. aureus BB and S. epidermidis 138 was supported by the addition of human diferric
transferrin but not apotransferrin. For S. aureus this
finding is consistent with the uptake of 55Fe from
radiolabelled transferrin as observed by Lindsay et al. (27). S. epidermidis, however, was reported to be
unable to acquire 55Fe from transferrin. In contrast, Brock
et al. (5) reported that both S. aureus and
S. epidermidis were able to access 55Fe from
transferrin but only inefficiently. In these experiments, the bacterial
cells were separated from the radiolabelled transferrin by a dialysis
membrane. As a consequence, no direct interaction between the bacterial
cell surface and the iron-binding glycoprotein could occur, which may
account for the inefficient uptake of transferrin-bound iron observed
by Brock et al. (5).
Since, both S. aureus and S. epidermidis grew
well in RPMI medium containing diferric human transferrin as the sole
iron source, we used 6 M urea-polyacrylamide gel electrophoresis to
investigate the contribution of the transferrin receptor to the
acquisition of iron. Using this approach, we have presented evidence
for a receptor-mediated, siderophore-independent iron uptake mechanism in both S. aureus and S. epidermidis. This
receptor-mediated mechanism of iron acquisition is clearly absent in
S. saprophyticus, which lacks the transferrin receptor
(30). Further confirmation was obtained by replacing human
transferrin with porcine transferrin, since the latter does not bind to
the staphylococcal receptor. While neither S. aureus nor
S. epidermidis was able to remove iron from porcine
transferrin, the staphylococcal siderophore staphyloferrin A
efficiently removed iron from both mammalian transferrins. These data
demonstrate unequivocally that S. aureus and S. epidermidis are both able to remove transferrin-bound iron either
via receptor- or siderophore-mediated processes.
By following the time course of iron removal from human transferrin, we
observed that iron was removed first from the N lobe and then from the
C lobe. Although the ligands involved in transferrin iron binding are
generally assumed to be equivalent because of similarities in their
spectroscopic, thermodynamic, and functional properties, the
iron-binding sites on each lobe are not identical (2, 21).
In particular, the two sites differ in their affinity for iron and in
their acid lability. Iron is lost from the N lobe of transferrin at pH
values between 6 and 5.5, whereas the C-lobe site is more acid stable,
losing its iron only between pH 5.5 and 4. The physiological
significance of such differences has been the matter for much
speculation, especially since the predominant transferrin species in
plasma are the monoferric transferrin and apotransferrin forms
(21, 45). Furthermore, more iron appears to be associated
with the N- rather than the C-lobe site of monoferric transferrin
(45). However, despite their physical and chemical differences, the two sites appear to behave as functionally equivalent (2, 21), and human transferrin labelled in either domain has
been shown to donate iron equally well to immature human erythrocytes (40). Whether the gram-negative transferrin
receptor-expressing pathogens take iron sequentially from the N or C
lobe of diferric transferrin has not been reported. However, studies of
the transferrin domain preference of the enterobacterial siderophores
aerobactin and enterobactin (enterochelin) revealed that the
hydoxamate, aerobactin, removes iron preferentially from the
thermodynamically more stable C lobe whereas the phenolate,
enterobactin, exhibits a preference for the N lobe (16).
Since the removal of iron from human transferrin by S. aureus and S. epidermidis requires an energy source, it
was important to establish whether this process involved active
transport. Metabolic poisons such as sodium azide, which is a potent
inhibitor of S. aureus membrane-associated ATPase activity
(26), at 6 mM inhibited the conversion of diferric
transferrin to its apotransferrin form. With 2 mM sodium azide, the
removal of iron from diferric human transferrin stalled at the
monoferric C form; i.e., iron was removed from the N-lobe site only.
This may be a consequence of the reduced thermodynamic stability of the
N lobe compared with the C lobe (21). Similar results were
obtained with nigericin, which disrupts membrane potential
(36). The receptor-mediated acquisition of iron from
transferrin by pathogenic Neisseria is also an
energy-requiring process, in which receptor energization is a necessary
prerequisite for ligand release (4, 10, 39). However, the
Neisseria are gram-negative bacteria, and iron released from
surface-bound transferrin must cross the outer membrane, the periplasm,
and the inner membrane prior to internalization. Iron from
receptor-bound transferrin is probably transferred via a gated pore in
transferrin binding protein A (TbpA) to the periplasmic iron-binding
protein, FbpA (7). Intriguingly, FbpA is structurally and
functionally homologous to transferrin itself and reversibly binds one
ferric ion per protein molecule (34, 35). In the both
Neisseria (1) and H. influenzae
(24), FbpA is part of an ATP-dependent transporter necessary
for the internalization of iron from receptor-bound transferrin. How
iron is released from transferrin bound to the surface of staphylococci
is not yet known, but in these gram-positive bacteria it is likely to
be mechanistically different. Recently we have cloned and sequenced an
iron-regulated staphylococcal ABC transporter incorporating a 32-kDa
lipoprotein (8) which could conceivably function in a manner
analogous to FbpA by acting as an acceptor for iron released from
surface-bound transferrin.
Since the staphylococci exhibit a preference for iron from the N-lobe
binding site, we sought to determine whether the binding of the intact
transferrin molecule could be blocked by the monoferric N-lobe
fragment. Both recombinant and subtilisin-generated N lobes inhibited
binding. In addition, a naturally occurring human transferrin variant
with a mutation in the C lobe (14, 15) also efficiently blocked the binding of intact normal human transferrin. Taken together
these results suggest that the primary receptor-binding site is located
within the N-terminal lobe of the protein. Furthermore, when the
iron-loaded N lobe of human transferrin was incubated with S. aureus, there was rapid removal of the iron. These results contrast with those obtained for the human transferrin receptor (46) and many gram-negative bacterial transferrin receptors (18), the primary recognition sites for which are located in the transferrin C-terminal lobe. Furthermore, only the C fragment was
found capable of donating iron or binding to the transferrin surface
receptors of hepatoma-derived HuH-7 cells and leukemic K562 cells
(46). Neither the isolated C or N lobes nor a mixture is
capable of supporting the growth of Haemophilus
paragallinarum (which recognizes both N and C lobe sites on
ovotransferrin) or N. meningitidis (which recognizes a
C-lobe binding site only) (3, 18).
In conclusion, we have now extended our earlier work (30)
and demonstrated that both S. aureus and S. epidermidis express a functional transferrin receptor which is
involved in the acquisition of transferrin-bound iron. Competitive
transferrin binding studies and iron-uptake experiments indicate that a
primary receptor recognition site lies within the N-terminal lobe. With
this information and knowledge of receptor specificity, using
site-directed mutagenesis we can now begin to define the precise
residues involved in the transferrin-receptor interaction.
| |
ACKNOWLEDGMENTS |
This work was supported by grants from the Medical Research
Council (to P.W.), the Special Trustees for St. Thomas' Hospital (to
R.W.E. and C.L.I.), and the Wellcome Trust (to R.W.E.).
We thank Gunther Winkelmann for his kind donation of staphyloferrin A.
| |
FOOTNOTES |
*
Corresponding author. Mailing address: School of
Pharmaceutical Sciences, University of Nottingham, Nottingham NG7 2RD,
United Kingdom. Phone: 44-115-9515047. Fax: 44-115-9515110. E-mail:
Paul.Williams{at}nottingham.ac.uk.
Editor: V. A. Fischetti
| |
REFERENCES |
| 1.
|
Adhikari, P.,
S. A. Berish,
A. J. Nowalk,
K. L. Veraldi,
S. A. Morse, and T. A. Mietzner.
1996.
The fbpABC locus of Neisseria gonorrhoeae functions in the periplasm-to-cytosol transport of iron.
J. Bacteriol.
178:2145-2149[Abstract/Free Full Text].
|
| 2.
|
Aisen, P.
1989.
Physical biochemistry of the transferrins: update, 1984-1988.
Phys. Bioinorg. Chem. Ser.
5:353-371.
|
| 3.
|
Alcantara, J., and A. B. Schryvers.
1996.
Transferrin binding protein 2 interacts with both the N-lobe and C-lobe of ovotransferrin.
Microb. Pathog.
209:73-85.
|
| 4.
|
Archibald, F. S., and I. W. DeVoe.
1980.
Iron acquisition by Neisseria meningitidis in vitro.
Infect. Immun.
27:322-334[Abstract/Free Full Text].
|
| 5.
|
Brock, J. H.,
P. H. Williams,
J. Liceaga, and K. G. Woolridge.
1991.
Relative availability of transferrin-bound iron and cell-derived iron to aerobactin-producing and enterochelin-producing strains of Escherichia coli and to other microorganisms.
Infect. Immun.
59:3185-3190[Abstract/Free Full Text].
|
| 6.
|
Bullen, J. J.
1981.
The significance of iron in infection.
Rev. Infect. Dis.
3:1127-1137[Medline].
|
| 7.
|
Chen, C.-J.,
S. A. Berish,
S. A. Morse, and T. A. Meitzner.
1993.
The ferric binding protein of pathogenic Neisseria spp. functions as a periplasmic transport protein in iron acquisition from human transferrin.
Mol. Microbiol.
10:311-318[Medline].
|
| 8.
| Cockayne, A., P. J. Hill, N. J. Powell, K. Bishop, C. Sims, and P. Williams. Molecular cloning of a
32-kilodalton lipoprotein component of a novel iron-regulated
Staphylococcus epidermidis ABC transporter. Infect. Immun.
66:3767-3774.
|
| 9.
|
Cornelissen, C. N., and P. F. Sparling.
1994.
Iron piracy: acquisition of transferrin-bound iron by bacterial pathogens.
Mol. Microbiol.
14:843-850[Medline].
|
| 10.
|
Cornelissen, C. N.,
J. E. Anderson, and P. F. Sparling.
1997.
Energy-dependent changes in the gonococcal transferrin receptor.
Mol. Microbiol.
26:25-35[Medline].
|
| 11.
|
Cornelissen, C. N.,
M. Kelley,
M. M. Hobbs,
J. E. Anderson,
J. G. Cannon,
M. S. Cohen, and P. F. Sparling.
1998.
The transferrin receptor expressed by gonococcal strain FA1090 is required for the experimental infection of human male volunteers.
Mol. Microbiol.
27:611-616[Medline].
|
| 12.
|
Courcol, R. J.,
D. Trivier,
M. C. Bissinger,
G. R. Martin, and M. R. W. Brown.
1997.
Siderophore production by Staphylococcus aureus and identification of iron-regulated proteins.
Infect. Immun.
65:1944-1948[Abstract].
|
| 13.
|
Evans, R. W., and J. Williams.
1978.
Studies on the binding of different iron donors to human serum transferrin and isolation of iron-binding fragments from the N- and C-terminal regions of the protein.
Biochem. J.
173:543-552[Medline].
|
| 14.
|
Evans, R. W.,
J. Williams, and K. Moreton.
1982.
A variant of transferrin with abnormal properties.
Biochem. J.
201:19-26[Medline].
|
| 15.
|
Evans, R. W.,
J. B. Crawley,
R. C. Garratt,
J. G. Grossman,
M. Neu,
A. Aitken,
K. J. Patel,
A. Meilak,
C. Wong,
J. Singh,
A. Bomford, and S. S. Hasnain.
1994.
Characterization and structural analysis of a functional human serum transferrin variant and implications for receptor recognition.
Biochemistry
33:12512-12520[Medline].
|
| 16.
|
Ford, S.,
R. A. Cooper,
R. W. Evans,
R. C. Hider, and P. H. Williams.
1988.
Domain preference in iron removal from human transferrin by the bacterial siderophores aerobactin and enterochelin.
Eur. J. Biochem.
178:477-481[Medline].
|
| 17.
|
Gonzalez, G. C.,
D. L. Caamana, and A. B. Schryvers.
1990.
Identification and characterization of a porcine-specific transferrin receptor in Actinobacillus pleuropneumoniae.
Mol. Microbiol.
4:1173-1179[Medline].
|
| 18.
|
Gray-Owen, S. D., and A. B. Schryvers.
1996.
Bacterial transferrin and lactoferrin receptors.
Trends Microbiol.
4:185-190[Medline].
|
| 19.
|
Grossman, J. G.,
M. Neu,
R. W. Evans,
P. F. Lindley,
H. Appel, and S. S. Hasnain.
1993.
Metal-induced conformational changes in transferrins.
J. Mol. Biol.
229:585-590[Medline].
|
| 20.
|
Haag, H.,
H. P. Fiedler,
J. Meiwes, and H. Zahner.
1994.
Isolation and characterisation of staphyloferrin B, a compound with siderophore activity from staphylococci.
FEMS Microbiol. Lett.
115:125-130[Medline].
|
| 21.
|
Harris, D. C., and P. Aisen.
1989.
Physical biochemistry of transferrins. Loehr (ed.), Iron carriers and proteins.
Phys. Bioinorg. Chem. Ser.
5:239-351.
|
| 22.
|
Hasan, A. A.,
J. Holland,
A. Smith, and P. Williams.
1997.
Elemental iron does repress transferrin, haemopexin and haemoglobin receptor expression in Haemophilus influenzae.
FEMS Microbiol. Lett.
150:19-26[Medline].
|
| 23.
|
Hueck, D.,
W. Beer, and R. Reissbrodt.
1995.
Iron supply of staphylococci and of micrococci by -ketoacids.
J. Med. Microbiol.
43:26-32[Abstract].
|
| 24.
|
Kirby, S. D.,
S. D. Gray-Owen, and A. B. Schryvers.
1997.
Characterization of a ferric-binding protein mutant in Haemophilus influenzae.
Mol. Microbiol.
25:979-987[Medline].
|
| 25.
|
Konetschny-Rapp, S.,
G. Jung,
J. Meiwes, and H. Zahner.
1991.
Staphyloferrin A: a structurally new siderophore from staphylococci.
Eur. J. Biochem.
191:65-74[Medline].
|
| 26.
|
Kubak, B., and W. Yotis.
1981.
Staphylococcus aureus adenosine triphosphatase: inhibitor sensitivity and the release from membrane.
J. Bacteriol.
146:385-390[Abstract/Free Full Text].
|
| 27.
|
Lindsay, J. A.,
T. V. Riley, and B. J. Mee.
1995.
Staphylococcus aureus but not Staphylococcus epidermidis can acquire iron from transferrin.
Microbiology
141:197-203[Abstract].
|
| 28.
|
Makey, D. G., and U. S. Seal.
1976.
The detection of four molecular forms of human transferrin during the iron-binding process.
Biochim. Biophys. Acta
453:250-256[Medline].
|
| 29.
|
Meiwes, J.,
H. P. Fiedler,
H. Haag,
H. Zahner,
S. Konetschny-Rapp, and G. Jung.
1990.
Isolation and characterisation of staphyloferrin A, a compound with siderophore activity from Staphylococcus hyicus DSM 20459.
FEMS Microbiol. Lett.
67:201-206.
|
| 30.
|
Modun, B.,
D. Kendall, and P. Williams.
1994.
Staphylococci express a receptor for human transferrin: identification of a 42-kilodalton cell wall transferrin-binding protein.
Infect. Immun.
62:3850-3858[Abstract/Free Full Text].
|
| 31.
|
Modun, B.,
A. Cockayne,
R. G. Finch, and P. Williams.
1998.
The Staphylococcus aureus and Staphylococcus epidermidis transferrin-binding proteins are expressed in vivo during infection.
Microbiology
144:1005-1012[Abstract].
|
| 32.
|
Morton, D. J., and P. Williams.
1989.
Utilisation of transferrin-bound iron by Haemophilus species of human and porcine origin.
FEMS Microbiol. Lett.
65:123-128.
|
| 33.
|
Morton, D. J., and P. Williams.
1990.
Siderophore-independent acquisition of transferrin-bound iron by Haemophilus influenzae type b.
J. Gen. Microbiol.
136:927-933[Medline].
|
| 34.
|
Nowalk, A. J.,
S. B. Tencza, and T. A. Mietzner.
1994.
Co-ordination of iron by the ferric iron-binding protein of pathogenic Neisseria is homologous to the transferrins.
Biochemistry
33:12769-12775[Medline].
|
| 35.
|
Nowalk, A. J.,
K. G. Vaughan,
B. W. Day,
S. B. Tencza, and T. A. Mietzner.
1997.
Metal-dependent conformers of the periplasmic ferric-binding protein.
Biochemistry
36:13054-13059[Medline].
|
| 36.
|
Rottenberg, H., and A. Scarpa.
1974.
Calcium uptake and membrane potential in mitochondria.
Biochemistry.
13:4811-4817[Medline].
|
| 37.
|
Schade, A. L.
1963.
Significance of serum iron for the growth, biological characteristics, and metabolism of Staphylococcus aureus.
Biochem. Z.
388:140-148.
|
| 38.
|
Schwyn, B., and J. B. Neilands.
1987.
Universal chemical assay for the detection and determination of siderophores.
Anal. Biochem.
160:47-56[Medline].
|
| 39.
|
Simonson, C.,
D. Brener, and I. W. DeVoe.
1982.
Expression of a high-affinity mechanism for the acquisition of transferrin iron by Neisseria meningitidis.
Infect. Immun.
36:107-113[Abstract/Free Full Text].
|
| 40.
|
Van der Heul, C.,
M. J. Kroos,
W. L. van Noort, and H. G. van Eijk.
1981.
No functional difference of the two iron-binding sites of human transferrin in vitro.
Clin. Sci.
60:185-190[Medline].
|
| 41.
|
Wilcox, M. H.,
P. Williams,
D. G. E. Smith,
R. G. Finch, and S. P. Denyer.
1991.
Variation in the expression of cell envelope proteins of coagulase-negative staphylococci cultured under iron-restricted conditions in human peritoneal dialysate.
J. Gen. Microbiol.
137:2561-2570[Medline].
|
| 42.
|
Willams, J.
1982.
The evolution of transferrin.
Trends Biochem. Sci.
7:394-397.
|
| 43.
|
Williams, P., and E. Griffiths.
1992.
Bacterial transferrin receptors structure, function and contribution to virulence.
Med. Microbiol. Immunol.
181:301-322[Medline].
|
| 44.
|
Wolz, C.,
K. Hohloch,
A. Ocaktan,
K. Poole,
R. W. Evans,
N. Rochel,
A.-M. Albrecht-Gary,
M. A. Abdallah, and G. Döring.
1994.
Iron release from transferrin by pyoverdin and elastase from Pseudomonas aeruginosa.
Infect. Immun.
62:4021-4027[Abstract/Free Full Text].
|
| 45.
|
Zak, O., and P. Aisen.
1986.
Non-random distribution of iron in circulating human transferrin.
Blood
68:157-161[Abstract/Free Full Text].
|
| 46.
|
Zak, O.,
D. Trinder, and P. Aisen.
1994.
Primary receptor recognition site of human transferrin is in the C-terminal lobe.
J. Biol. Chem.
269:7110-7114[Abstract/Free Full Text].
|
| 47.
|
Zak, O.,
P. Aisen,
J. B. Crawley,
C. J. Joannou,
K. J. Patel,
M. Rafiq, and R. W. Evans.
1995.
Iron release from recombinant N-lobe and mutants of human transferrin.
Biochemistry
34:14428-14434[Medline].
|
Infect Immun, August 1998, p. 3591-3596, Vol. 66, No. 8
0019-9567/98/$04.00+0
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Abstract
Introduction
