From the ¶ Department of Biology and the McCollum-Pratt
Institute and the
Department of Biophysics, The Johns
Hopkins University, Baltimore, Maryland 21218
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ABSTRACT |
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ialA, one of two genes associated
with the invasion of human red blood cells by Bartonella
bacilliformis, the causative agent of several diseases, has been
cloned and expressed in Escherichia coli. The protein,
IalA, contains an amino acid array characteristic of a family of
enzymes, the Nudix hydrolases, active on a variety of nucleoside
diphosphate derivatives. IalA has been purified, identified, and
characterized as an enzyme catalyzing the hydrolysis of members of a
class of signaling nucleotides, the dinucleoside polyphosphates, with
its highest activity on adenosine 5'-tetraphospho-5'-adenosine (Ap4A), but also hydrolyzing Ap5A,
Ap6A, Gp4G, and Gp5G. In each case,
a pyrophosphate linkage is cleaved yielding a nucleoside triphosphate
and the remaining nucleotide moiety.
Bartonella bacilliformis is the only bacterium known to
invade human red blood cells, and it and other species of
Bartonella are responsible for several maladies, including
Carrion's disease (Oroya fever, verruga peruana), cat scratch disease,
trench fever, bacilliary angiomatosis, and bacilliary endocarditis (1,
2). In their studies on the invasiveness of B. bacilliformis, Mitchell and Minnick identified a two-gene locus
which, when transformed into minimally invasive Escherichia
coli, markedly increased their capacity to invade red blood cells
in vitro (3). This report attracted our attention, because
one of these two genes, ialA (for invasion-associated locus)
codes for an open reading frame containing a small array of highly
conserved amino acids we have called the Nudix box (4) (see Sequence
1).
INTRODUCTION
Top
Abstract
Introduction
Procedures
Results & Discussion
References
All 16 of the enzymes containing this Nudix signature sequence,
discovered so far (see Ref. 5), catalyze the hydrolysis of
nucleoside diphosphates linked to some other
moiety, X, hence the acronym (see "Note Added
in Proof"). The Nudix box is represented in all three
kingdoms, Archaea, Prokaryota, and Eukaryota, from viruses to humans.
Recent BLAST (6) searches have uncovered over 200 putative proteins
containing the Nudix motif in 60 species, and we are systematically
studying the members of this primordial and widely distributed family.
This communication describes the cloning of ialA, and the
expression, purification, and partial characterization of the
invasion-associated protein, IalA, as an enzyme catalyzing the
hydrolysis of dinucleoside 5'-polyphosphates.
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EXPERIMENTAL PROCEDURES |
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Materials
All biochemicals were from Sigma. Enzymes used in standard cloning procedures were from Life Technologies Inc., Stratagene, or U. S. Biochemical Corp., except the Pfu DNA polymerase from Perkin-Elmer. Oligonucleotide primers were from Integrated DNA Technologies. E. coli HMS174(DE3) cells and pET11b were obtained from Novagen. E. coli HB101 cells were from our laboratory stock. pGroESL, from George H. Lorimer, DuPont, contained the groEL and groES genes, a T7 lac promoter, and a chloramphenicol resistance gene. Sephadex G-100 was from Amersham Pharmacia Biotech.
Methods
Cloning-- The ialA gene (GenBankTM accession number L25276) from B. bacilliformis KD583 (ATCC number 35685) was amplified from genomic DNA with forward primers incorporating an NdeI site and reverse primers incorporating a BamHI site. The insert was prepared by digestion with NdeI and BamHI followed by gel purification. The pET construct, pIALa, was prepared by ligation of the insert into the NdeI and BamHI sites of pET11b to regulate expression of the ialA gene with a T7 lac promoter, and the insert was verified by sequence analysis. The pIALa was used to transform E. coli strains HB101 to test lethality and HMS174(DE3) for expression. The pIALa-transformed HMS174(DE3) cell line was then transformed with pGroESL.
Purification of IalA Protein--
Eight liters of LB medium
containing 100 µg/ml ampicillin and 64 µg/ml chloramphenicol were
inoculated with 80 ml of an overnight culture of HMS174(DE3) cells
containing pIALa and pGroESL. The culture was incubated at 37 °C to
an A600 of 0.3, then transferred to 22 °C. At
an A600 of 0.6, the cells were induced with 1 mM isopropyl--D-thiogalactopyranoside and
incubated at 22 °C for an additional 24 h. The cells were
harvested by centrifugation, washed by suspension in about 10 volumes
of an isotonic saline solution, centrifuged again, and frozen at
80 °C. About 2 g of cells were obtained per liter of culture.
Freezing the cells was essential for preparing the extract. The frozen
cells were suspended in 5 volumes of buffer A (50 mM
Tris-HCl, pH 7.5 1 mM EDTA), and the supernatant, which
contained the IalA protein, was collected after centrifugation
(Fraction I).
A 10% streptomycin sulfate solution was slowly added to Fraction I to a final concentration of 1%, while the fraction was stirred on ice. After approximately 15 min, the supernatant was collected after centrifugation (Fraction II).
Fraction II was brought to 40% saturation by the slow addition of solid ammonium sulfate. After 15 min, the precipitate was collected by centrifugation and discarded, and additional ammonium sulfate was added to the supernatant to give a 60% saturated solution. This precipitate, containing the IalA protein, was collected and dissolved in a volume of buffer A representing a 15-fold concentration of the starting material (Fraction III).
Fraction III was loaded onto a 2.5 × 60-cm Sephadex G-100 column
and eluted with buffer A containing 100 mM NaCl. The
fractions containing purified IalA protein were combined, concentrated
by pressure filtration in a Centriplus 10 microconcentrator, and stored
at 80 °C (Fraction IV).
Enzyme Assay-- This assay measures the conversion of a phosphatase-insensitive substrate to a phosphatase-sensitive product.
The standard incubation mixture contained in 50 µl: 1 mM
substrate, 50 mM Tris-HCl, pH 7.5, 1 mM
ZnCl2, 3 units of calf alkaline intestinal phosphatase, and
0.1-1.5 milliunits of enzyme. The reaction was terminated by the
addition of 250 µl of 8 mM EDTA and analyzed for
inorganic orthophosphate by the method of Ames and Dubin (7). A unit of
enzyme hydrolyzes 1 µmol of substrate/min under these conditions.
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RESULTS AND DISCUSSION |
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Expression and Purification of the IalA Protein-- Cloning of the ialA gene, and transformation of the expression host, HMS174(DE3), with pIALA produced a new, highly visible protein band of about 20 kDa in extracts of induced cultures when analyzed by polyacrylamide gel electrophoresis. However, all of the newly expressed protein was present in the insoluble fraction (inclusion body) of a low speed centrifugation, making it unsuitable for enzyme purification. Accordingly, we explored procedures for increasing the solubility of recalcitrant proteins, and we found that the combination of growing the cells at a reduced temperature, and in the presence of chaperonins co-expressed from a second plasmid, produced significant quantities of soluble IalA protein. The partial purification of the IalA protein was facilitated by the ease with which it was extracted from the cells. Merely freezing and thawing the centrifuged packed cell mass causes the soluble IalA protein to leak out with the retention of most of the other proteins. This observation is reminiscent of another of the Nudix proteins we have studied, Orf17, a dATPase from E. coli (8), which also appears in the supernatant after a freeze-thaw cycle. Whether this behavior is merely a coincidence or reflects some functional commonality is at present conjectural. Fig. 1 shows the appearance of a new protein species after induction of a plasmid carrying the ialA gene. Also shown is Fraction IV, purified according to the protocol described under "Methods." This fraction was used for all of the experiments described in this paper.
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Enzymatic Activity of the IalA Protein-- Our experience with other members of the Nudix hydrolase family of enzymes told us that the substrate of the IalA protein would probably be a nucleoside diphosphate derivative. However, none of the substrates of our previously discovered enzymes such as NADH (9), GDP-mannose (10), ADP-ribose (5), or nucleoside triphosphates (11) were hydrolyzed. A BLAST search (6) of the protein data banks using the Nudix box region of IalA as the query was not very informative, because it uncovered over 100 open reading frames, including those we had identified previously. However, when the entire amino acid sequence of the protein was used to probe the data base, homologous regions outside of the Nudix signature sequence narrowed the search. A Clustal sequence alignment (12) of the top three BLAST matches to IalA of Bartonella is shown in Fig. 2. The plant proteins from Lupinus (13) and Hordeum (GenPept Z99996) are diadenosine tetraphosphate hydrolases, and Orf 176 from E. coli, which we have cloned recently and are in the process of characterizing, is also a dinucleoside polyphosphate hydrolase.1 We therefore examined whether the IalA invasion protein also belonged to this family by assaying extracts of cells carrying the plasmid for diadenosine tetraphosphate hydrolase activity. Fig. 3 shows the appearance of the enzyme after induction. In the control culture containing the plasmid without the ialA insert, no commensurate activity was detected. After purification of the newly discovered enzyme, the substrate specificity was examined as shown in Table I. In both the diadenosine and diguanosine series, the tetraphosphate appears to be the preferred substrate, although more extensive kinetic measurements will be required to compare all the members of the series. As mentioned previously, none of the other compounds including nucleotide sugars, NADH, nucleoside triphosphates, or ADP-ribose, favored, by other members of the Nudix family, are significant substrates.
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Products of the Reaction--
In order to ascertain the pathway of
hydrolysis of adenosine tetraphosphate, a scaled up standard reaction
mixture (without alkaline phosphatase) was allowed to proceed until
approximately 70% of the initial substrate was hydrolyzed. The
products and remaining substrate were separated by high performance
liquid chromatography as shown in Fig. 4.
The disappearance of
Ap4A2 was
accompanied by the commensurate appearance of ATP and AMP. Neither
inorganic orthophosphate nor pyrophosphate is produced during the
course of the reaction, and the following equation may be written:
Ap4A + H2O ATP + AMP.
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The products formed from the other substantial substrates were analyzed
by paper electrophoresis according to Markham and Smith (14).
Gp4G, as expected, yielded GTP and GMP. When the pentaphosphates were analyzed, the products were found to be the triphosphate (ATP or GTP) and the respective diphosphate (ADP or GDP).
With the hexaphosphate, Ap6A, ATP was the sole product. Thus, the feature common to all the reactions is the obligatory formation of a nucleoside triphosphate as one of the products, arguing
that a nucleophilic attack by H2O is directed at the phosphorus atom in each of the substrates. This is in contrast to the
MutT dGTPase and Orf 17 dATPase, also members of the Nudix hydrolase
family, which catalyze nucleophilic attacks on the
phosphorus as
shown by NMR analysis of the products of dGTP or dATP hydrolyzed in
H218O (8, 15). It would be of interest to do
similar studies with the dinucleoside polyphosphate hydrolase since the
amino acid motif of the nucleotide binding site and catalytic center is
common to all members of the Nudix hydrolase family.
It is worth noting that the enzyme described here differs from the dinucleoside polyphosphate hydrolase recently reported by Cartwright and Mclennan (16). Their protein from Saccharomyces cerevisiae also contains the Nudix signature. However, it forms multiple products from Ap6A (ADP, Ap4, AMP, Ap5) and Ap5A (ADP, ATP, AMP, Ap4), and it also hydrolyzes ATP and Ap4, which are not substrates for the enzyme described in this paper. On the other hand, the specificity of the Bartonella enzyme seems to parallel, most closely, the Ap4A pyrophosphatase purified and characterized from human placenta (17) and shown to have the Nudix motif (18).
Other Properties of the Enzyme-- The protein appears to be monomeric, eluting from a gel filtration column at a position corresponding to 20 kDa. It has a broad pH optimum between 7.5 and 9.0 and requires a divalent metal ion for activity. At pH 9.0, it has optimal and approximately equal activity in 10 mM Mg2+ or 1 mM Zn2+, and it is about 50% as active in 3 mM Mn2+. The purified enzyme (Fraction IV) has a specific activity of 40 µmol/min/mg or a kcat of about 14/s.
What role does the hydrolysis of dinucleoside polyphosphates play in the invasion of red cells by B. bacilliformis? The dinucleoside polyphosphates themselves are an interesting group of cell signaling molecules broadly distributed in prokaryotes and eukaryotes and implicated in a wide variety of physiological responses, including stress or heat shock ("alarmones"), neurotransmission, platelet aggregation, cardiovascular regulation (for review, see Ref. 19), and in cell differentiation and apoptosis (20). With this plethora of diverse targets, it has been difficult to assign specific mechanisms to their modes of action. However, thought-provoking correlations are evident. We have seen that Suramin (number 8986, The Merck Index), a powerful anti-helminthic, anti-parasitic drug is a potent inhibitor of the Ap4A pyrophosphatase, reducing its catalytic rate 50% at 10 µM concentration.3 Rotlan et al. have seen similar effects in extracts of rat brain (21). Suramin has also been shown to inhibit purinergic neurotransmission (22), ADP-induced platelet aggregation (23), and the non-adrenergic, non-cholinergic inhibitory action potential (24). This suggests that adenine nucleotides, implicated as signaling molecules in these processes, are also involved in cell invasion.
It is also noteworthy that B. bacilliformis is a member of
the alpha proteobacteria and closely related phylogenetically to other
intracellular parasites, including Rickettsia, Brucella, Rhizobium, and Agrobacterium. Several lines of
evidence, including 16 S RNA sequencing (25), chaperonin homologies
(26, 27), and their bioenergetics system (28), point to the Rickettsia as the most likely antecedents of mitochondria by invading eukaryotic cells. We have recently identified an open reading frame
(GenBankTM accession number Z82300) in Rickettsia
prowazekii, the causative agent of epidemic typhus, containing the
Nudix box and highly homologous to the enzyme described in this paper.
We plan to determine whether it also is a dinucleoside pyrophosphatase
in order to assess how general the linkage is between invasiveness and
homologues of IalA. In addition, our identification of the product of
ialA as a dinucleoside pyrophosphatase should help in
uncovering the role of the second gene associated with invasion,
ialB.
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Note Added in Proof |
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A recent report (Safrany, S. T., Caffrey, J. J., Yang, X., Bernbenek, M. E., Moyer, M. B., Burkhart, W. A., and Shears, S. B. (1998) EMBO J. 17, 6599-6607) describes an enzyme purified from rat liver hydrolyzing diphosphoinositol polyphosphates. It contains the signature sequence of the Nudix hydrolases and is the first member of the family whose major substrate is not a nucleoside diphosphate derivative.
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FOOTNOTES |
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* This work was supported by Grant GM 18649 from the National Institutes of Health and is Publication 1519 from the McCollum-Pratt Institute.The costs of publication of this article were defrayed in part by the payment of page charges. The article must therefore be hereby marked "advertisement" in accordance with 18 U.S.C. Section 1734 solely to indicate this fact.
§ Recipient of Minority Access to Research Centers Predoctoral Fellowship GM-17178 from the National Institutes of Health.
** To whom correspondence should be addressed. Tel.: 410-516-7316; Fax: 410-516-5213; E-mail: zoot{at}jhu.edu.
The abbreviation used is: Ap4A, adenosine 5'-tetraphospho-5'-adenosine. Other members of the family are abbreviated in an analogous manner.
1 J. D. Walsh and M. J. Bessman, unpublished observation.
3 G. B. Conyers and M. J. Bessman, unpublished observations.
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REFERENCES |
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