The Rickettsia prowazekii Invasion Gene Homolog (invA) Encodes a Nudix Hydrolase Active on Adenosine (5')-pentaphospho-(5')-adenosine*

Jariyanart Gaywee{ddagger}, WenLian Xu§, Suzana Radulovic{ddagger}, Maurice J. Bessman§ and Abdu F. Azad{ddagger},

{ddagger} Department of Microbiology and Immunology, School of Medicine, University of Maryland, Baltimore, Maryland 21201
§ Department of Biology and the McCollum-Pratt Institute, The Johns Hopkins University, Baltimore, Maryland 21218


    ABSTRACT
 TOP
 ABSTRACT
 MATERIALS AND METHODS
 RESULTS
 DISCUSSION
 REFERENCES
 
The genomic sequence of Rickettsia prowazekii, the obligate intracellular bacterium responsible for epidemic typhus, reveals an uncharacterized invasion gene homolog (invA). The deduced protein of 18,752 Da contains a Nudix signature, the specific motif found in the Nudix hydrolase family. To characterize the function of InvA, the gene was cloned and overexpressed in Escherichia coli. The expressed protein was purified to near homogeneity and subsequently tested for its enzymatic activity against a series of nucleoside diphosphate derivatives. The purified InvA exhibits hydrolytic activity toward dinucleoside oligophosphates (NpnN; n >= 5), a group of cellular signaling molecules. At optimal pH 8.5, the enzyme actively degrades adenosine (5')-pentaphospho-(5')-adenosine into ATP and ADP with a Km of 0.1 mM and kcat of 1.9 s-1. Guanosine (5')-pentaphospho-(5')-guanosine and adenosine-(5')-hexaphospho (5')-adenosine are also substrates. Similar to other Nudix hydrolases, InvA requires a divalent metal cation, Mg2+ or Zn2+, for optimal activity. These data suggest that the rickettsial invasion protein likely plays a role in controlling the concentration of stress-induced dinucleoside oligophosphates following bacterial invasion.


Rickettsia prowazekii is the etiologic agent of epidemic typhus and Brill-Zinsser disease. These illnesses are louse-borne rickettsioses that are reemerging worldwide (1, 2). The organism is an obligate intracellular Gram-negative bacterium growing only within the eukaryotic host cell cytoplasm (3). Humans are exposed to R. prowazekii through direct contact with contaminated body louse feces. The bacterium begins its life cycle in the human host by invading the epithelial cells via the process of induced phagocytosis (3, 4). Then, it rapidly escapes from the phagosome into the host cytoplasm where it replicates and eventually causes the invaded cell to burst (3, 4). Destruction of host cells is the basis of rickettsial pathogenesis (3). Although systemic approaches have revealed substantial information about the biology of rickettsial host cell invasion, the molecular basis underlying the invasive mechanism remains undefined.

Recently, the completion of the R. prowazekii genome project revealed the presence of the invasion gene homolog, invA (5). The invA open reading frame encodes a polypeptide of 161 amino acids with a predicted molecular mass of 18,752 daltons, containing a conserved motif called the Nudix box (Nucleoside diphosphates linked to some other moiety, X) (6). Nudix boxes are present in the Nudix hydrolase family, a group of diverse enzymes that catalyze the hydrolysis of nucleoside diphosphate derivatives (6). Alignment analysis of the deduced amino acid sequence of R. prowazekii InvA demonstrated 37–44% identity to the putative invasion proteins of other invasive bacteria including Bartonella bacilliformis IalA, Neisseria meningitidis putative Ap4A1 pyrophosphatase, Helicobactor pylori InvA, Escherichia coli YgdP, Salmonella typhimurium putative invasion protein, Haemophilus influenzae InvA, and Pseudomonas aeruginosa invasion protein homolog (Fig. 1). Among these homologous genes, only B. bacilliformis ialA and E. coli K1 ygdP have been documented to be associated with host cell invasion (7, 8). Furthermore, purified IalA and YgdP were shown to be members of the dinucleoside oligophosphate pyrophosphatase subfamily of the Nudix hydrolases (911). Their specific substrates, dinucleoside oligophosphates, are considered to be a class of signaling molecules involved in cell stress responses, cell growth, and cell differentiation (12, 13). It has been proposed that these enzymes might play a role in enhancing the intracellular survival of the invading bacteria by regulating the stress-induced dinucleoside oligophosphate levels during host cell invasion (6, 913). In this paper, we have identified homologous genes in several Rickettsia species. Among these, the R. prowazekii invA was expressed, and the purified protein was characterized to be a member of the dinucleoside pentaphosphate pyrophosphatase subfamily of Nudix hydrolases.



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FIG. 1. Alignment of the amino acid sequences of R. prowazekii InvA and homologous proteins of invasive bacteria in a BLAST search. The closest matches are to B. bacilliformis IalA, N. meningitidis putative Ap4A pyrophosphatase, H. pylori InvA, E. coli YgdP, S. typhimurium putative invasion protein, H. influenzae InvA, and P. aeruginosa invasion protein homolog. Identical amino acids and similar amino acids are indicated in dark shaded and framed boxes, respectively. Nudix motif sequences are underlined.

 

    MATERIALS AND METHODS
 TOP
 ABSTRACT
 MATERIALS AND METHODS
 RESULTS
 DISCUSSION
 REFERENCES
 
The R. prowazekii (Madrid E), Rickettsia typhi (Wilmington), Rickettsia rickettsii (Sheila Smith), Rickettsia akari (Kaplan), Rickettsia canada (CA410), and Rickettsia rhipicephali (CA871) were propagated in our laboratory (University of Maryland, Baltimore, MD). Primers utilized in this study were synthesized at the Biopolymer core facility, University of Maryland, Baltimore. The genomic DNA isolation kit was from Promega (Madison, WI). Enzymes used in standard cloning procedures were from Stratagene (La Jolla, CA) and Invitrogen. Calf intestinal alkaline phosphatase and inorganic pyrophosphatase were from Stratagene (La Jolla, CA). PCR 2.1 TA TOPO cloning vector and E. coli TOP10 competent cells were purchased from Invitrogen. The prokaryotic expression system, pET-24a(+) and E. coli DH5{alpha} and E. coli HMS174(DE3) hosts were obtained from Novagen (Madison, WI). The plasmid, pGroESL, containing the E. coli groEL and groES genes, a T7lac promoter, and a chloramphenicol resistance gene was a gift from George H. Lorimer (Dupont). All chemical reagents were purchased from Sigma. Sephadex G-100 was from Amersham Biosciences. A Centricon Plus-20 microconcentrator and a C18 reverse phase HPLC column were purchased from Millipore Co. (Bedford, MA) and YMC Inc. (Japan), respectively.

Propagation of Rickettsiae and Genomic DNA Isolation—
Rickettsiae were propagated in African green monkey kidney (Vero) cells (ATCC C1008) as described previously (14). 90–95% infected cells were harvested, and rickettsiae were purified by Renografin density gradient centrifugation (15). Genomic DNAs were isolated using a WizardTM DNA isolation kit and were quantified spectrophotometrically.

Cloning of Rickettsial invA Homolog—
To investigate whether members of typhus group and spotted fever group rickettsiae, both human pathogens and non-pathogens, contain the invA gene homolog, primers based on the R. prowazekii invA sequence were used in PCR reactions. 0.1 µg of genomic DNA of typhus group, R. typhi and spotted fever group rickettsiae, R. rickettsii, R. akari, R. canada, and R. rhipicephali were subjected to PCR. The amplified fragments were cloned into the TA TOPO cloning vector, PCR 2.1, and recombinant vectors were transformed into competent cells for propagation. Plasmid DNA was purified and sequenced. Alignments were compared through blastn searches from GenBankTM.

Construction of the Expression Vector—
Full-length R. prowazekii invA (GenBankTM accession number AJ235271) was amplified from 0.1 µg of R. prowazekii genomic DNA utilizing a forward primer incorporating an NdeI site (NdeI-invAF; nucleotide 12769–12736; 5' GCG CGC GCC ATA TGA GGA ATT CTT CTA ACA AAT) and a reverse primer incorporating a BamHI site (BamHI-invAR; nucleotide 12284–12320; 5' GCG CGC GGA TCC TTA CTG AAT TAA TGA TTC AAA). The amplicon was subcloned into PCR 2.1 TA TOPO cloning vector. The recombinant plasmid was transformed into E. coli TOP10 for propagation and sequenced to ensure the fidelity of the amplified gene. R. prowazekii invA was then excised from the TA cloning vector, gel-purified, and directionally cloned into the NdeI/BamHI sites of the pET-24a(+) expression vector. The resulting construct, pETinvA, was introduced into E. coli DH5{alpha} for further propagation, and the in-frame insertion of invA was confirmed by sequencing.

Expression and Purification of R. prowazekii InvA—
To obtain a high quantity of native InvA, it was necessary to use an enhancing expression protocol optimizing the production of soluble protein (9). In this procedure, the expression host, E. coli HMS174(DE3), was co-transformed with pETinvA and pGroESL expressing the chaperones GroEL and GroES. The transformed clones were recovered by double antibiotic selection (kanamycin and chloramphenicol resistance acquired from pETinvA and pGroESL, respectively). To express the recombinant InvA, two liters of prewarmed LB medium containing 30 µg/ml each of kanamycin and chloramphenicol was inoculated with 20 ml of an overnight culture of E. coli HMS174(DE3) carrying pETinvA and pGroESL. The culture was incubated at 37°C to an A600 of 0.3 and then transferred to 18°C. At an A600 of 0.8, the cells were induced with 0.5 mM isopropyl-ß-D-thiogalactopyranoside and incubated at 18°C overnight. The induced cells were harvested by centrifugation, washed with isotonic saline, and frozen at -80°C. To extract the protein, the frozen cells (4 g) were resuspended in 2.5 volumes of TED buffer (50 mM Tris-Cl, pH 7.5, 0.1 mM EDTA, 0.1 mM dithiothreitol) and ruptured by three repetitive freeze-thaw cycles. The cell debris was removed by centrifugation to obtain the crude extract (Fraction I). A solution of 10% streptomycin sulfate was slowly added to Fraction I to a final concentration of 1.5%. The precipitated nucleic acids were removed by centrifugation, and the supernatant, Fraction II, was adjusted to 55% saturation with solid ammonium sulfate. The precipitated protein was dissolved in a minimal volume of TED buffer (Fraction III), applied to a 2.5 x 60-cm Sephadex G-100 gel filtration column, and eluted with 100 mM sodium chloride in TED buffer. Fractions were assayed for enzymatic activity. The active fractions were pooled, concentrated by pressure filtration in a Centricon Plus-20 microconcentrator, and adjusted to 20% glycerol (Fraction IV) before storage at -80°C. Each step of the purification process was monitored by SDS-PAGE followed by Coomassie Blue staining. Protein concentration was measured according to Bradford (16).

Enzyme Assays and Product Identification—
Enzymatic activity of purified InvA was assayed as described previously (9). Briefly, this procedure measures the conversion of a phosphatase-resistant substrate to a phosphatase-sensitive product by determining the liberated Pi. Potential substrates (1 mM) were incubated for 15 min at 37°C with InvA and calf intestinal alkaline phosphatase (4 units) in 50 µl of a standard reaction mixture containing 50 mM Tris-HCl, pH 8.5, and 5 mM MgCl2. The reaction was terminated by adding 250 µl of 4 mM EDTA, and the released Pi was measured according to the colorimetric procedure of Ames and Dubin (17). One unit of InvA catalyzes the hydrolysis of 1 µmol of substrate per min under these conditions.

HPLC was used to identify the reaction products as described previously (9). An assay mixture (250 µl) containing 50 mM Tris-HCl, pH 8.5, 5 mM MgCl2, 250 nmol Ap5A, and 330 ng of InvA protein was incubated up to 20 min at 37°C. Samples collected at different time points were analyzed on a reverse phase column, and the peaks were identified by comparison to standards.


    RESULTS
 TOP
 ABSTRACT
 MATERIALS AND METHODS
 RESULTS
 DISCUSSION
 REFERENCES
 
Cloning of the Rickettsial invA
Using the polymerase chain reaction, full-length R. prowazekii invA (486 bp) was cloned, and its nucleotide sequence was identical to the published sequence. To determine whether invA homologs are present in other rickettsiae, PCR utilizing R. prowazekii invA gene-specific primers were performed on the genomic DNA of human pathogenic rickettsiae; R. typhi, R. rickettsii, R. akari, and the non-pathogenic Rickettsia species, R. canada and R. rhipicephali. Approximately 500 bp of PCR products were amplified (Fig. 2). The fragments were cloned and sequenced. Alignment analysis demonstrated that the nucleic acid sequences of the invA homologs in other rickettsiae were 96–98% identical to the published R. prowazekii invA.



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FIG. 2. Amplification of the invA homolog in Rickettsia species. A 1.5% ethidium bromide-stained agarose gel of the amplified fragments using invA gene-specific primers included the following: R. prowazekii (lane 1), R. typhi (lane 2), R. rickettsii (lane 3), R. akari (lane 4), R. canada (lane 5), R. rhipicephali (lane 6), and reagent control (lane 7). The invA fragment is indicated on the right. Lane M contains DNA size standards as indicated on the left.

 
Expression and Purification of the InvA Protein
Directional cloning of the full-length R. prowazekii invA into pET-24a(+) at the NdeI and BamHI sites allowed for the expression of unmodified protein under the control of the strong T7 promoter. When cells were grown and induced at 37°C, a large amount of InvA was produced; however, only a limited amount was present in the soluble fraction of the cell extract (Fig. 3). Similar yield was observed in InvA expression at 18 or 37°C in the presence of host chaperones (data not shown). The combination protocol, lowering the expression temperature and using a host overproducing chaperones, resulted in a substantial increase in the soluble, native form of R. prowazekii invA (Fig. 3). SDS-PAGE analysis of the soluble fraction of the crude cell extract revealed novel protein bands at 58, 19, and 10 kDa representing GroEL, InvA, and GroES, respectively (Fig. 3). Purification of InvA was aided by the observation that most of the enzyme was released from the cell by a freeze-thaw cycle. Using the protocol as described under "Materials and Methods," InvA was purified to near homogeneity as shown in Fig. 3.



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FIG. 3. Expression and purification of R. prowazekii InvA. In vitro expression was carried out overnight at 37°C, lanes 1 to 5, and 18°C, lanes 6 to 8. The samples containing 10 µg of protein were analyzed on a 4–20% SDS polyacrylamide gel stained with Coomassie Blue. Lanes 1 and 2, a crude extract of uninduced and induced E. coli/pET-24a(+). Lane 3, a crude extract of uninduced E. coli/pETinvA. Lanes 4 and 5, induced E. coli/pETinvA, insoluble and soluble fractions. Lane 6, a crude extract of uninduced E. coli/pETinvA/pGroESL. Lanes 7 and 8, induced E. coli/pETinvA/pGroESL, insoluble (5 µg) and soluble fractions. Lane 9, 1 µg of fraction IV of the purified enzyme. Proteins of interest are indicated on the right. Lane M represents molecular mass standards as indicated on the left.

 
Properties of the InvA Protein
Substrates—
Because alignment analysis of the primary sequence demonstrated high homology to the Nudix hydrolases, we tested a number of substrates shown previously to be hydrolyzed by members of the family. Little or no activity was seen with NADH, GDP-mannose or ADP-ribose (Table I). However, as with IalA and YgdP, the InvA protein catalyzes the hydrolysis of members of the dinucleoside oligophosphate family. As summarized in Table I, InvA preferentially degrades adenosine Ap5A. It has no activity on dinucleoside oligophosphates (n <= 4), whereas Bartonella IalA prefers Ap4A. The relative activity of InvA on ApnA and GpnG decreases significantly with decreasing phosphate chain length. This trend is also observed with IalA and YgdP.


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TABLE I Relative specificities of the dinucleoside oligophosphate pyrophosphatases

All substrates were present at a concentration of 1 mM in the standard assay. Results are expressed as % of the activity of each of the enzymes setting the favored substrate at 100. 100% represents an actual value of substrate hydrolyzed, 3.6 nmol of Ap5A for InvA, 12.3 nmol of Ap4A for IalA, and 3.3 nmol of Ap5A hydrolyzed for YgdP, respectively.

 
Reaction Products—
To identify the products from the hydrolysis of the preferred substrate, Ap5A, a standard reaction was scaled up omitting alkaline phosphatase. Aliquots were collected after incubation for 0, 5, 10, 15, and 20 min and subsequently analyzed by HPLC. There was a decrease in the Ap5A during the incubation and concomitant formation of ATP and ADP (Fig. 4). No fraction of adenosine tetraphosphate was observed throughout the course of the reaction. The stoichiometry of the hydrolytic reaction may be described by Equation 1,

(Eq. 1)



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FIG. 4. Identification of reaction products from hydrolysis of Ap5A by InvA. A reaction containing 250 nmol of Ap5A, 330 ng of InvA, 50 mM Tris buffer, pH 8.5, and 2.5 mM MgCl2 was incubated at 37°C. Aliquots of the incubation at different time points were applied to a C18 reverse phase chromatography column. Peaks were identified by the respective elution times. Shown are the 5- and 20-min intervals.

 
Kinetic Properties—
Kinetic parameters of Ap5A hydrolysis by InvA, along with those of YgdP, for comparison, are summarized in Table II. The maximum velocity of InvA is 3.8 units/mg leading to the catalytic constant, kcat, of 1.9 s-1 compared with 1.0 s-1 for YgdP.


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TABLE II Kinetic analysis of the diadenosine pentaphosphate pyrophosphatases

Rates are obtained under standard assay conditions by varying substrate (Ap5A) concentrations from 0.05 to 2.0 mM. Data were analyzed with the software package Enzyme Kinetics (Trinity Software, Fort Pierce, FL).

 
Other Properties of the Enzyme—
InvA elutes from the gel filtration column as a 19-kDa protein, behaving as a monomer in solution. Like most of the other characterized Nudix hydrolases, it prefers an alkaline pH, optimally at 8.5, and a divalent cation, Mg2+ or Zn2+, at 5 mM to be fully functional. Mn2+ did not support the hydrolytic activity of InvA whereas it is required for IalA and YgdP. A comparison of the properties of InvA and the other two characterized invasion proteins is presented in Table III.


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TABLE III Comparison of the dinucleoside oligophosphate pyrophosphatases

 

    DISCUSSION
 TOP
 ABSTRACT
 MATERIALS AND METHODS
 RESULTS
 DISCUSSION
 REFERENCES
 
One aspect of our research is to describe the molecular basis underlying rickettsial host cell invasion. We have initially focused on the functional characterization of the R. prowazekii invA and have shown that this gene is present and conserved among the pathogenic and non-pathogenic Rickettsia, members of the typhus and spotted fever groups. We hypothesize that this particular gene might be important for host cell invasion and/or establishing and maintaining the obligate intracellular parasitism shared by rickettsiae. To characterize its function, R. prowazekii InvA was expressed, purified, and evaluated for its enzymatic properties. Initial attempts to express R. prowazekii InvA as a histidine-tagged protein for convenient protein purification was unsuccessful because of an extremely low expression yield.2 Expression of InvA as a fusion protein with the 40-kDa maltose-binding protein resulted in a high quantity of soluble product; however, the purified maltose-binding protein-InvA fusion protein exhibited a specific enzyme activity 200-fold lower than that of the native protein.3 Similar observations have been reported previously for vaccinia virus deoxyuridine triphosphatase, in that the native protein had a specific activity 36-fold higher than that of the glutathione S-transferase fusion protein (18). Utilizing the pET system, in combination with the expression-enhancing protocol described here, allowed for the expression of high quality, stable, native InvA, which was suitable for biochemical characterization. Our data indicate that R. prowazekii invA encodes a dinucleoside pentaphosphate pyrophosphatase, identifying it as a member of the subfamily of the Nudix hydrolases. This finding is consistent with previous reports in which the invasion-associated genes, Bartonella ialA and E. coli K1 ygdP, were also shown to encode members of this subfamily (911).

Considering its enzymatic activity, how might InvA be involved in host cell invasion or enable its intracytoplasmic existence? The dinucleoside oligophosphates are byproducts of the aminoacyl-tRNA synthetase reaction, found in prokaryotic and eukaryotic cells in small amounts (12, 19). However, during cellular stresses such as heat shock or oxidative stress, the concentration of dinucleoside oligophosphates increases dramatically, up to several hundredfold (20, 21). Intracellular imbalance of these minor nucleotides results in diverse physiological effects such as induction of cell apoptosis and cell differentiation (22), induction of premature cell division (23), inhibition of ATP-sensitive K+ channels (24), and inhibition of adenylate kinase activity (25). To maintain its viability, the cell has to clean up this potentially hazardous environment. It has been proposed that the Nudix hydrolases have an important common physiological function in sanitizing the cell of toxic endogenous metabolites and in modulating the accumulation of certain intermediates in biochemical pathways. These enzymes might act as "house-cleaning" enzymes, thereby protecting the cell from harmful effects resulting from the imbalanced presence of potentially toxic compounds (6). In this scenario, the rickettsial invasion protein could play a role in decreasing the levels of intracellular dinucleoside oligophosphates that accumulate during the oxidative stress following bacterial invasion. Regulation of dinucleoside oligophosphates might be crucial for the intracellular survival of rickettsiae.

Interestingly, hydrolysis of diadenosine oligophosphates by Rickettsia and Bartonella, as well as E. coli K1 invasion proteins, results in ATP as one of the reaction products. This high energy molecule could serve as a readily available energy source for the bacterium. Furthermore, ADP, the other byproduct of Ap5A hydrolysis, could also be exchanged for ATP through the unique ADP-ATP translocase of rickettsiae (26). This may be an example of bacterial evolution in which rickettsiae have highly adapted to intracellular life by converting a potentially toxic molecule to a useful metabolite.

Aside from the enzymatic activity described here, other aspects of the biological function of InvA remain to be defined. For example, tracking the subcellular localization of InvA, as well as examining its expression profile during the invasion process, will provide insight as to how a dinucleoside oligophosphate pyrophosphatase and dinucleoside oligophosphates are involved in rickettsial infection. Toward these aims, studies including immunoelectron microscopy utilizing antibodies against purified InvA and quantitative real time reverse transcriptase PCR are currently underway.


    FOOTNOTES
 
Received, November 19, 2001, and in revised form, January 15, 2002.

Published, MCP Papers in Press, January 18, 2002, DOI 10.1074/mcp.M100030-MCP200

1 The abbreviations used are: Ap4A, adenosine (5')-tetraphospho-(5')-adenosine; Ap5A, adenosine (5')-pentaphospho-(5')-adenosine; HPLC, high performance liquid chromatography. Back

2 Unpublished data. Back

3 Gaywee, J., Radulovic, S., Bessman, M. J., Kim, K. S., and Azad, A. F. (2001) Poster B-262, presented at the 101st General Meeting, American Society for Microbiology, Orlando, FL (May 20–24, 2001). Back

* This work was supported in part by National Institutes of Health Grants AI 17828 (to A. F. A.) and GM 18649 (to M. J. B.). Predoctoral fellowship support was from the Royal Thai Army, Ministry of Defense, Thailand (to J. G.). The costs of publication of this article were defrayed in part by the payment of page charges. This article must therefore be hereby marked "advertisement" in accordance with 18 U.S.C. Section 1734 solely to indicate this fact. Back

To whom correspondence should be addressed: Dept. of Microbiology and Immunology, School of Medicine, University of Maryland, 655 West Baltimore St., Baltimore, MD 21201. Tel.: 410-706-3335; Fax: 410-706-0282; E-mail: aazad{at}umaryland.edu.


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