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Appl Environ Microbiol, July 1998, p. 2439-2442, Vol. 64, No. 7
0099-2240/98/$04.00+0
Copyright © 1998, American Society for Microbiology. All rights reserved.
Cytoplasmic Membrane Lipoprotein LppC of
Streptococcus equisimilis Functions as an Acid
Phosphatase
Horst
Malke*
Institute for Molecular Biology, Jena
University, D-07745 Jena, Germany
Received 6 February 1998/Accepted 1 May 1998
 |
ABSTRACT |
The function of the streptococcal cytoplasmic membrane lipoprotein,
LppC, was identified with isogenic Streptococcus
equisimilis H46A and Escherichia coli JM109 strain
pairs differing in whether they contained [H46A and JM109(pLPP2)] or
lacked (H46A lppC::pLPP10 and JM109) the
functional lppC gene for comparative phosphatase determinations under acidic conditions. lppC-directed acid
phosphatase activity was demonstrated zymographically and by
specific enzymatic activity assays, with whole cells or cell membrane
preparations as enzyme sources. LppC acid phosphatase
showed optimum activity at pH 5, and the enzyme activity was
unaffected by Triton X-100, L-(+)-tartaric acid, or
EDTA. Database searches revealed significant structural homology of
LppC to the Streptococcus pyogenes LppA, Flavobacterium meningosepticum OplA, Helicobacter
pylori HP1285, and Haemophilus influenzae Hel
[e (P4)] proteins. These results suggest a possible
function for these proteins and establish a novel function of
streptococcal cell membrane lipoproteins.
| |
INTRODUCTION |
In a previous study from this
laboratory, we reported the cloning and nucleotide sequence of a novel
Streptococcus equisimilis chromosomal gene, designated
lppC, which encodes a 32.4-kDa lipoprotein associated with
the streptococcal cytoplasmic membrane or the outer membrane of
Escherichia coli when expressed in this organism (5). The lppC gene is located immediately 3' to
and is transcribed independently of the unrelated
gapC gene that codes for glyceraldehyde-3-phosphate dehydrogenase (4). As revealed by Southern, Northern, and
Western analyses, homologs of lppC (and gapC)
are conserved and also expressed in Streptococcus pyogenes
(5). Database searches performed at that time found
homology of LppC only to the hel gene-encoded outer-membrane antigen e (P4) from Haemophilus
influenzae (6), to which it exhibits 58%
sequence similarity. The biological function of e (P4)
has remained elusive until very recently, when it was reported to
be involved in the uptake of hemin as a source of porphyrin, an
essential growth factor for H. influenzae when grown aerobically (9). Our attempts to provide evidence for a role of lppC in hemin uptake failed as, unlike the hel
gene, lppC was unable to complement hemA mutants
of E. coli for growth on hemin as the sole
porphyrin source in aerobic conditions. Furthermore, S. equisimilis H46A, the source of lppC, was
incapable of hemin binding or of growing on this compound in
iron-limited medium (5).
Sequence database searching was continued at regular intervals for
additional homologs of LppC and revealed weak structural similarity at
low quality (quality score, 92.3) to the aphA gene product
of E. coli MG1655 (sequence identity and similarity
between LppC and AphA, 20.3 and 46.7%, respectively). Thaller et al.
(16) had cloned and sequenced the aphA gene in
the meantime and functionally characterized its product as an acid
phosphatase. Sequence similarity between LppC and AphA prompted
me to explore the possibility that the streptococcal protein has
similar enzymatic activity. Here I provide biochemical, serological,
and genetic evidence that the LppC protein does function as an acid
phosphatase.
| |
MATERIALS AND METHODS |
Bacterial strains and culture conditions.
Two pairs of
strains, with or without functional lppC, were used to
identify the function of this gene. S. equisimilis H46A, a human serogroup C strain,
contained wild-type lppC, whereas H46A
lppC::pLPP10 was an erythromycin-resistant
chromosomal insertion mutant carrying lppC interrupted at
codon 144 by pLPP10 (5). Similarly, E. coli
JM109 (21) was free of lppC, and JM109(pLPP2) contained plasmid-located lppC together with its promoter
and terminator as a 1,152-bp fragment in the EcoRV site of
pACYC184 (5). The streptococcal strains were grown without
agitation at 37°C in brain-heart infusion medium (Difco) in ambient
air. E. coli strains were cultured aerobically at
37°C in Luria-Bertani medium (11). If appropriate, the
media contained erythromycin (2.5 µg/ml) and chloramphenicol (35 µg/ml) to select for plasmids.
Zymographic detection of phosphatase activity.
Whole-cell
protein preparations were examined for phosphatase activity by the
zymogram technique essentially as described by Thaller et al.
(14). Briefly, cells from 10-ml overnight cultures were
disrupted by sonication, and the unheated sonicates were subjected to
sodium dodecyl sulfate-polyacrylamide gel electrophoresis (5). After treatment with renaturation buffer containing 1% Triton X-100, the gels were incubated overnight at 37°C in 100 mM
sodium acetate buffer (pH 5.5) containing the phosphatase substrate (0.25 mM) 5-bromo-4-chloro-3-indolyl-phosphate (BCIP; Sigma). The
appearance of blue bands indicated the presence of phosphatase activity. Western immunoblot analysis of the protein extracts performed
in parallel with monospecific LppC antibodies served to compare the
migration distances of the reactive protein bands in the two detection
systems. The LppC antibodies had an enzyme-linked immunosorbent assay
titer of >1,000 and were raised in rabbits as described previously
(5). Western blots incubated with the primary antibodies
were subsequently reacted with peroxidase-conjugated goat anti-rabbit
immunoglobulin G (Bio-Rad) as the secondary antibody by standard
procedures.
Phosphatase assays.
Whole cells or subcellular cell
fractions were assayed for phosphatase activity with disodium
p-nitrophenyl phosphate (pNPP; Sigma) as the substrate by
measuring the released p-nitrophenol (pNP) colorimetrically
at 415 nm in the linear range of the calibration curves. Under standard
conditions, the assays were performed in a volume of 1.2 ml in 37.5 mM
citrate-4.16 mM chloride buffer (pH 4.8) containing 7.6 mM pNPP. The
reactions were initiated by addition of the preparations to be tested
for enzyme activity. Incubation was at 37°C for 30 min before the
reactions were terminated by the addition of 5 ml of 0.1 N NaOH.
Phosphatase inhibition tests were performed in standard reaction
mixtures in the presence of 2% Triton X-100, 16.7 mM
L-(+)-tartaric acid, or 15 mM EDTA. The pH dependence of
the phosphatase activity was determined in citrate buffer with pNPP as
substrate.
For whole-cell phosphatase assays, bacteria were harvested from 16-h
cultures, washed twice in physiological NaCl solution, and used at 1.6 U of optical density at 600 nm (OD600) (corresponding to
~3.2 × 109 cells) in the reaction mixtures. The
bacteria were removed by centrifugation before absorbance was recorded.
Cell membrane fractions were prepared as described previously
(5). Briefly, E. coli cells were
spheroplasted by lysozyme treatment in the presence of 1 M sucrose and
lysed in Tris-HCl buffer containing 2% Triton X-100 and DNase. Triton
X-100 specifically solubilizes the proteins of the inner membrane
(7, 12). The lysate was centrifuged for 1 h at
40,000 × g in an SW50 rotor, and the precipitate
containing the outer membrane was washed three times in distilled water
before being frozen for further use. Streptococcal cells were
protoplasted by combined treatment with lysozyme and mutanolysin in the
presence of 66% sucrose (5). The protoplasts were lysed by
three freeze-thaw cycles, followed by sonication to shear the DNA.
Subsequent centrifugation at 40,000 × g yielded the
pelleted cytoplasmic membrane fraction, which was washed and stored as
described above.
The protein content of the bacterial membrane fractions was determined
by the bicinchoninic acid method with bovine serum
albumin as the
standard, following the procedure recommended by
the supplier of the
assay kit (Sigma). Specific acid phosphatase
activities in the
whole-cell and the cell membrane assay were
expressed on a
per-OD
600 unit basis and a per-milligram of membrane
protein basis, respectively.
| |
RESULTS |
Zymographic detection of lppC-directed phosphatase
activity.
The lppC gene is efficiently expressed under
its natural promoter in E. coli JM109(pLPP2) as
demonstrated previously by reactivity of a novel ~32-kDa protein with
monospecific anti-LppC antibodies on Western blots (5).
Whole-cell protein preparations from strains JM109 and
JM109(pLPP2) were therefore tested for phosphatase activity by zymography. As shown in Fig.
1, the JM109(pLPP2) extract gave rise to
a prominent band in the zymogram that migrated at the same rate as the
anti-LppC reactive band in the Western blot run in parallel. Neither of
the reactive bands was detected in the pLPP2-free control strain. This
result indicated that lppC specified enzymatic activity that
releases phosphate from BCIP under acidic conditions. Zymography with
BCIP as the phosphatase substrate was too insensitive to detect the
enzymatic activity of LppC in whole-cell protein preparations of H46A,
presumably due to much lower relative LppC amounts in the latter cells
compared to those of E. coli JM109(pLPP2) that
overproduced the protein (5).
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FIG. 1.
Detection of LppC protein in E. coli
JM109(pLPP2) by Western blotting (A) and zymography (B). The results
were obtained from sodium dodecyl sulfate-12% polyacrylamide gel
electrophoretograms of whole-cell extracts (equivalent to ~6 × 108 cells/slot) from JM109(pLPP2) (lanes 1 and 3) and JM109
(plasmid-free control, lanes 2 and 4) reacted, after blotting, with a
1:1,000 dilution of affinity-purified polyclonal antibodies to LppC (A)
or, without blotting, with phosphatase substrate, BCIP (B). Lane S
contained marker proteins, with molecular masses indicated on the
left.
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|
Acid phosphatase activity of whole cells and membrane fractions
from S. equisimilis and E. coli.
To substantiate and expand the zymographic observation, a
whole-cell assay was performed to determine whether the LppC protein functions as an acid phosphatase capable of releasing pNP from the
standard substrate, pNPP. As shown in Table
1, the enzyme activity
produced by wild-type H46A cells exceeded that elaborated by
cells of the isogenic lppC insertion mutant by a
factor of 7.9. An even-greater difference between the enzyme activities of cells with or without functional lppC was seen in the
heterologous E. coli strain pair, in which JM109(pLPP2)
was 14.8 times more active than the plasmid-free control strain.
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TABLE 1.
Specific acid phosphatase activity of whole cells and
cell membranes of the indicated S. equisimilis and E. coli strains as
measured by the release of pNP from p-nitrophenyl phosphate
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|
Since previous data show that the LppC protein is located in the
streptococcal cytoplasmic membrane or in the
E. coli (pLPP2)
outer membrane (
5), the
corresponding membrane fractions were
also assayed for phosphatase
activity (Table
1). The specific
enzyme activities in terms of total
membrane protein were 27.5-fold
and more than 200-fold higher
in the preparations from H46A and
JM109(pLPP2), respectively, than the
corresponding activities
seen in the membranes of the control strains.
In fact, the activities
of the latter ranged close to the borderline of
measurability.
In both the whole-cell and the membrane assay, the
specific phosphatase
activities detected in JM109(pLPP2) exceeded those
observed in
H46A by factors of about 3.6 and 12.1, respectively.
Presumably,
the greater activities in JM109(pLPP2) reflected the higher
dose
or more efficient expression of
lppC, or both, in the
heterologous
strain.
The
E. coli JM109(pLPP2) outer-membrane
preparation was used as a source of LppC phosphatase to study
some basic properties
of the enzyme. Optimum acid phosphatase activity
of LppC was observed
in a relatively sharp peak at pH 5, with
activities at pH 4.5
and 6.4 amounting to only about 8 and 21%,
respectively, of the
activity seen at optimum pH (Fig.
2). Enzyme activity was resistant
to 2%
Triton X-100 in the reaction mixture. Furthermore, the enzyme
could not
be inhibited by tartrate and EDTA at concentrations
of 16.7 and 15 mM,
respectively (data not shown). Regarding the
pH optimum of the enzyme
produced in the homologous organism,
the phosphatase activity of
S. equisimilis membrane preparations
also
showed an optimum at about pH 5.
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FIG. 2.
lppC-directed specific
p-nitrophenyl phosphate-hydrolyzing activity of
E. coli JM109(pLPP2) outer-membrane protein in citrate
buffer of different pH values.
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|
Identification of LppC homologs by sequence comparisons.
When
initially described, LppC was reported to exhibit significant
sequence similarity only to the Hel [e (P4)] protein of H. influenzae (5). In the
meantime, the expanded sequence databases allowed the additional
identification of putative structural homologs of LppC in
S. pyogenes [LppA (12a)],
Flavobacterium meningosepticum (OlpA; EMBL database
accession no. Y12759), Helicobacter pylori (HP1285
[18]) and, as mentioned in the introduction,
E. coli (AphA [16]). When ranked
on the basis of optimized homology scores (8) relative to
LppC, these proteins fell into the order LppC > LppA > OlpA > Hel > HP1285 > AphA (data not shown). By using
Monte Carlo statistical analysis, based on the guidelines of Lipman and
Pearson (8), to evaluate the significance of homology, LppC
was found to be significantly homologous to all of the above
proteins except AphA, to which, however, homology is still probable
(data not shown). Multiple alignment of the amino acid sequences
of the above-mentioned proteins (Fig. 3) revealed the greatest degree of diversion at both termini of the proteins. The 13-amino-acid region corresponding to LppC coordinates 97 to 109 was detected as the longest region with the highest degree of
sequence similarity, followed by a 4- and a 6-amino-acid region of
similar quality toward the C-terminal ends. However, none of these
regions or any other part of the sequences exhibited the conserved RHG
triad of the high-molecular-mass acid phosphatases. This sequence
motif has been proposed to contain the histidine residue used in the
phosphoryl transfer reaction that may proceed through a
transient phosphohistidine enzyme intermediate (2, 19). Of
the six proteins shown in Fig. 3, data are available only for AphA
(16) and, as shown here, LppC that establish their functioning as acid phosphatases. Furthermore, evidence for the lipoprotein nature of the proteins has been published only for the Hel
(6), LppC, and LppA proteins (5). The N-terminal sequences of HP1285 and AphA, although containing a cysteine residue, differ strongly from the consensus [(L, V) (A, S, T) (G, A) 
C] of
the lipoprotein signal sequence cleavage site (13, 20). Besides, AphA can be readily released from the periplasmic space (16), suggesting that, unlike lipoproteins, it is not
tightly associated with the cell envelope.
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FIG. 3.
Gapped sequence alignment (17) of the
S. equisimilis LppC (5),
S. pyogenes LppA (12a), F. meningosepticum OlpA (EMBL database accession no. Y12759),
H. pylori HP1285 (18), H. influenzae
Hel (6), and E. coli AphA (16)
proteins. Amino acids conserved in at least two-thirds of the proteins
are in inverse font and were used to formulate a consensus sequence.
Different degrees of shading indicate aligned amino acids with similar
contributions to secondary structure. Note that the LppA sequence is
still preliminary and incomplete at the N terminus.
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| |
DISCUSSION |
As a group of enzymes, phosphatases are diverse and have widely
different properties (19). The present results
characterize the LppC enzyme as a cell membrane lipoprotein acid
phosphatase that functions in the presence of tartrate and EDTA. EDTA
resistance of its functional activity suggests that, similar to the
class A acid phosphatases of the enteric bacteria
(14-16), the enzyme does not require metal ion cofactors.
The LppC enzyme has resistance to the inhibitory action of tartrate, as
do the enteric class B acid phosphatases which, however, are EDTA
susceptible and appear not to accept BCIP as a substrate (15,
16). With regard to size, the molecular mass of the LppC
polypeptide (~32 kDa) lies between that of the high- (40 to 60 kDa)
and the low-molecular-mass (14 to 18 kDa) acid phosphatases (10,
19). It remains to be investigated whether the active form of the
streptococcal protein is a homo-oligomer, as are, e.g., the
enterobacterial NapA (15) and AphA (16)
phosphatases.
Of considerable interest is the fact that the functional identification
of lppC establishes a novel role for cytoplasmic
membrane-associated lipoproteins of the streptococci, if not of the
gram-positive bacteria in general. The various functions attributed to
these proteins in recent years have hitherto not included phosphatase activity (for a review, see reference 13). Although
the number of LppC homologs proposed here is still small, it is
remarkable that those recognized occur in pathogenic or potentially
pathogenic species (Fig. 3). Most of them, including LppC, require
further functional characterization to provide insight into their
possible physiological role. It remains to be seen whether this role is limited to serving nutritional and metabolic regulatory functions by
scavenging organic phosphoesters (16, 19) or extends to pathogenetic functions. As a matter of fact, acid phosphatases from
several bacterial species have recently been recognized as virulence
factors that support intracellular survival by inhibiting the
respiratory burst (1, 3, 10). In this connection, hydrolysis
of phosphate esters, particularly when localized to cell surface
structures, may be linked to cellular signal transduction processes. It
is thus important to know whether or not LppC also exhibits
phosphotransferase activity, as shown for the NapA (15) and
AphA (16) phosphatases. A more specific issue that is raised by the functional identification of lppC relates to the
primary function of the H. influenzae Hel
[e (P4)] protein. On the basis of the present results, it
can be speculated that this protein is an acid phosphatase and thus
requires reevaluation with respect to its functional role.
| |
ACKNOWLEDGMENTS |
I thank Ulrike Wrazidlo for outstanding technical assistance.
Accessibility of the database of the Streptococcus pyogenes genome sequencing project at the University of Oklahoma is gratefully acknowledged.
This work was supported by grants from the Thuringian Ministry of
Science, Research and Arts; the German Research Association; and the
Fonds of the Chemical Industry to H.M.
| |
FOOTNOTES |
*
Mailing address: Institute for Molecular Biology, Jena
University, Winzerlaer Strasse 10, D-07745 Jena, Germany. Phone:
49-(0)3641-657530. Fax: 49-(0)3641-657520. E-mail:
hmalke{at}imb-jena.de.
| |
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Appl Environ Microbiol, July 1998, p. 2439-2442, Vol. 64, No. 7
0099-2240/98/$04.00+0
Copyright © 1998, American Society for Microbiology. All rights reserved.
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Abstract
Introduction
