- Research article
- Open Access
A novel tetratricopeptide repeat (TPR) containing PP5 serine/threonine protein phosphatase in the malaria parasite, Plasmodium falciparum
© Dobson et al; licensee BioMed Central Ltd. 2001
- Received: 19 September 2001
- Accepted: 28 November 2001
- Published: 28 November 2001
The malarial parasite, Plasmodium falciparum (Pf), is responsible for nearly 2 million deaths worldwide. However, the mechanisms of cellular signaling in the parasite remain largely unknown. Recent discovery of a few protein kinases and phosphatases point to a thriving reversible phosphorylation system in the parasite, although their function and regulation need to be determined.
We provide biochemical and sequence evidence for a protein serine/threonine phosphatase type PP5 in Plasmodium falciparum, and named it PfPP5. The 594-amino acid polypeptide was encoded by a 1785 nucleotide long intronless gene in the parasite. The recombinant protein, expressed in bacteria, was indistinguishable from native PfPP5. Sequencing comparison indicated that the extra-long N-terminus of PfPP5 outside the catalytic core contained four tetratricopeptide repeats (TPRs), compared to three such repeats in other PP5 phosphatases. The PfPP5 N-terminus was required for stimulation of the phosphatase activity by polyunsaturated fatty acids. Co-immunoprecipitation demonstrated an interaction between native PfPP5 and Pf heat shock protein 90 (hsp90). PfPP5 was expressed in all the asexual erythrocytic stages of the parasite, and was moderately sensitive to okadaic acid.
This is the first example of a TPR-domain protein in the Apicomplexa family of parasites. Since TPR domains play important roles in protein-protein interaction, especially relevant to the regulation of PP5 phosphatases, PfPP5 is destined to have a definitive role in parasitic growth and signaling pathways. This is exemplified by the interaction between PfPP5 and the cognate chaperone hsp90.
- Okadaic Acid
- Catalytic Core
- Tetratricopeptide Repeat
- Nickel Chelation Affinity Chromatography
- Asexual Erythrocytic Stage
On the basis of sequence homo logy and similarity of three-dimensional structures, phosphoprotein phosphatases (PPases) have been classified into three families designated PPP, PPM, and PTP [reviewed in [1–3]. The PPP and PPM families are comprised of phosphoserine- and phosphothreonine-specific enzymes whereas the PTP family consists of phosphotyrosine-specific and dual-specificity enzymes . The major members of the PPP family are PP1, PP2A, and PP2B (calcineurin) class of phosphatases. Protein phosphatase 5 (PP5), a newer member of the PPP family, differs from the other Ser/Thr phosphatases in that it contains regulatory and (sub)cellular targeting functions within a single polypeptide [5–7]. While its catalytic core exhibits strong similarity to those of the other members of this family, its N-terminus consists of three tetratricopeptide repeats (TPRs) that are unique to the PP5 class. TPR domains consist of a series of antiparallel amphipathic α helices that bundle together through hydrophobic interactions to form a cradle-shaped groove, postulated to be involved in binding a number of proteins of regulatory importance such as heat shock protein 90, a major cellular chaperone [8–10].
The Apicomplexan family of parasites, exemplified by Plasmodia, are major disease agents of humans. As the causative agent of malaria, Plasmodia sp. alone infects about 300 million people globally and results in an annual death toll of nearly 2 million . Plasmodium falciparum (Pf) is the most virulent of all and causes fatal cerebral malaria. Because of the continual emergence of drug-resistant parasites throughout the world, a need for a fundamental knowledge of the signaling pathways of the parasite has been recognized. In the recent past, this has led to the identification of a number of Plasmodium protein phosphatases, some putative [12, 13], others experimentally demonstrated [e.g., [14–16]]. Most of these phosphatases resembled the classical mammalian PP1, PP2A, PP2B and PP2C enzymes [12, 14, 16], and some were potentially novel Ser/Thr phosphatases [13, 15, 16].
In this report, we describe the cloning and characterization of a novel PP5 phosphatase from Pf (PfPP5) that contains an unusually long N-terminal extension that contained four putative TPR motifs and played an important role in fatty acid-mediated activation of the enzyme. The structural and biochemical properties of PfPP5 described herein are hallmarks of the PP5 class, and thus establish PfPP5 as a likely player in parasitic signal transduction, and hence a potential target for antimalarial drug design.
Identification of PfPP5 cDNA and gene
Recombinant expression of PfPP5
The deletion mutant, ΔTPR-PfPP5, was similarly cloned by PCR using a primer corresponding to the internal sequence, and purified by nickel chelation affinity chromatography. The deletion mutant starts with Met-273, as described in Fig. 1.
Identification of native parasitic PP5
Primary structure of PfPP5
When the predicted primary structure of PfPP5 was aligned with known PP5 sequences (Fig. 1), the following features were obvious. First, PfPP5 contained the catalytic core found in all Ser/Thr phosphatases of the PPP family, including the signature motifs such as GDXHGQ, GDFVDRG, RGNHE, HGLL, and SAPNYCD, to name a few [22, 23]. Site-directed mutagenesis and structural studies in PP 1 and PPλ have previously established the roles of specific amino acid residues in these domains in the various aspects of catalysis, such as metal ion binding, phosphate recognition, and co-ordination of water molecules [24–26].
While the catalytic core is generally necessary and sufficient for the phosphohydrolase activity of PPP enzymes, the residues outside the core play critical roles in binding accessory proteins or small molecules that modulate the catalytic activity [25–29]. Specifically in the PP5 class, the N-terminus has been shown to contain three TPR motifs [5–8], the three-dimensional structure of which is now also available . Interestingly, the N-terminal sequence of PfPP5 was the longest of all, and seemed to contain four TPR motifs instead of three (Fig. 2). Thus, in comparing the full sequences of the PP5s, only three of the four PfPP5 TPRs were aligned with the others, and the second TPR of PfPP5 was left out. A detailed sequence analysis of all the PfPP5 TPRs is offered below.
The TPR motif is a degenerate, 34-amino acid repeat that is often found in tandem arrays, sometimes separated by spacer sequences . We propose such a 22-residue spacer between the first two TPRs of PfPP5 (Fig. 1). Although no single amino acid is absolutely invariant in all TPRs, they do contain a largely conserved pattern of amino acid similarity in terms of size, hydrophobicity, and spacing [8, 9]. Eight amino acid residues are critically placed on the same face of their respective helices: 4, 8, and 11 on the first helix, and 20, 24, and 27 on the second [8, 9]. As shown in Fig. 2, residues that are identical or have similar hydrophobicity are found in all four proposed TPRs of PfPP5 in the correct relative spacing. Moreover, secondary structure prediction suggested that each PfPP5 TPR also has the potential to form the two conserved helices (A and B), as marked in Fig. 2. Thus, all the TPRs of PfPP5 may satisfy the structural requirements of a TPR motif.
An approximately 34-residue stretch following the last TPR of PP5 (Fig. 1) shows weak similarity to a TPR motif. However, alpha-helix prediction and structure determination have shown that it is a single long helix that extends out of the TPR domain . Thus, this region may not represent a typical TPR and therefore, is simply marked as "helix" in Fig. 1.
Auto-inhibitory role of PfPP5 TPR: activation by polyunsaturated fatty acids
To test the role of TPR region in this activation, a TPR deletion mutant of PP5 (ΔTPR-PfPP5) starting at the Met-273 was expressed with an N-terminal (His)6 tag. The recombinant protein was expressed from pET-15b clone and purified by Ni-chelation chromatography (Fig. 3, lane 6). In SDS-PAGE analysis, ΔTPR-PfPP5 exhibited a Mr of approximately 40 k as expected (predicted size of 37,098 for the PP5 part plus about 2,000 for the His6 tag). Interestingly, the specific activity of the ΔTPR-PfPP5 enzyme was about 3-times that of the full-length PfPP5 without arachidonic acid (580 ± 35 nmoles of 32P per minute per mg enzyme; Fig. 5). Moreover, unlike the full-length enzyme, ΔTPR-PfPP5 was not activated by arachidonic acid, suggesting that the TPR region is required for the activation.
These results are reminiscent of similar studies done in other PP5 enzymes in which mutational inactivation of the TPR domain resulted in an elevated basal activity and concomitant reduced response to unsaturated fatty acids . Such studies led to the proposal that TPR domains regulate the PP5 catalytic region in a negative manner and that the interaction of arachidonic acid with TPR relieves this auto-inhibition. This was further supported by the demonstration that trypsin cleaved PP5 in the "hinge" sequence connecting the TPR region and catalytic domain, and that such cleavage produced a highly active enzyme which was refractory to further activation by fatty acids [18, 20, 21]. To test whether this is also true of PfPP5, we digested recombinant PfPP5 with trypsin, which resulted in the production of a trypsin-resistant fragment that was very similar in size to ΔTPR-PfPP5 (Fig. 3, lane 7). When assayed for phosphatase activity in vitro, the trypsin-digested PfPP5 indeed behaved like ΔTPR-PfPP5 in that it was about 3-fold more active than the full-length enzyme and was not activated by arachidonic acid any further (Fig. 5). Together these results suggest a role of PfPP5 TPR in auto-inhibition and in fatty acid-mediated activation.
Okadaic acid sensitivity of PfPP5
PfPP5 binds Pf heat shock protein 90 (hsp90)
We provide biochemical and molecular evidence for a PP5 protein Ser/Thr phosphatase of P. falciparum that has the catalytic core of the PPP superfamily and four tetratricopeptide (34-residue) repeat (TPR) domains (Fig. 1, 2). We have therefore, tentatively named this enzyme PfPP5. To our knowledge, PfPP5 is the only TPR-containing Plasmodium protein reported at this time. These domains, and the associated properties such as activation by unsaturated fatty acids are by far the most noteworthy features of PfPP5.
Recently, a PP5 phosphatase was identified in Trypanosoma that contained the prototype PP5 primary structure, including three TPR domains at the N-terminus. While mammalian PP5 is activated 10–40 fold by arachidonic acid, the Trypanosoma PP5, like its Plasmodium counterpart (Fig. 5), was also activated only modestly, about 3-fold. Although the reason behind the lower activation potential is unknown, at least in PfPP5 it correlates with a similar fold activation following loss of the TPR domains through either mutagenesis or proteolytic cleavage (Fig. 3, 5). Thus, it appears that the TPR domains of the primitive parasitic PP5 may be less auto-inhibitory that those of their higher eukaryotic counterparts. Recent mutational analysis of recombinant PP5 has identified sequences important in autoinhibition . Mutation of Glu-76 (underlined in the human PP5 in Fig. 1) whose side chain projects away from the TPR groove, resulted in a 10-fold elevation of basal activity, and this Glu is conserved in both Pf and Trypanosoma PP5 (Fig. 1). A role of the C-terminal end in autoinhibition was conjectured based on the finding that mutation of Gln-495 (underlined in Fig. 1) elevated basal activity by 10-fold . This residue is also found in Pf (Gln-592) although it is not conserved in a number of other PP5 sequences (Fig. 1). Clearly, detailed mutational analysis of these domains should shed light on the mechanism of PfPP5 autoinhibition and the role of polyunsaturated fatty acids in preventing it.
The TPR motif was originally identified as a protein interaction module in the cell division cycle (CDC) proteins in yeast [36, 37] but has since been shown to occur in proteins with diverse functions in a variety of species . The number of the TPR domains, the spacing between them, and their placement in the primary structure of the protein appear variable, and the relative contribution of the individual TPRs in a given protein has not been studied. At least four major kinds of macromolecular complexes have been identified that involve TPR domains. These include complexes involved in anaphase promotion, transcription repression, protein import, and molecular chaperoning [9, 10]. Yeast two-hybrid analysis and in vitro interaction studies have shown that the TPR domain of PP5 interacts with the TPR domains of CDC16 and CDC27, which may be important in recruiting PP5 to the anaphase promoting complex (APC) and to the mitotic spindles during cell division (38). Interaction of PP5 with heat shock protein 90, a chaperone, has received special attention because of its potential to regulate a variety of pathways. For example, PP5 is a major component of mature glucocorticoid receptor complexes of higher eukaryotes and appears to regulate glucocorticoid receptor function in vivo [ and references therein]. Such observations suggest that PP5 may act as a co-chaperone for hsp90 and raise the possibility that protein dephosphorylation may play an important regulatory role in protein folding [33, 34]. Interestingly, recent studies have identified a few residues of mammalian PP5 critically important for its interaction with hsp90 . As marked on the human PP5 TPR (underlined in Fig. 1) the corresponding residues are: Lys-32, Lys-97, and Arg-101. It is notable that the corresponding residues are also conserved in PfPP5 TPR. The availability of full-length and TPR-deleted recombinant PfPP5 clones will now allow us to further investigate the exact nature of the PfPP5-Pfhsp90 complexes, and map the interacting PfPP5 residues through site-directed mutagenesis. Clearly, the discovery of PfPP5 and its interaction with homologous hsp90 will open up new directions in parasitic protein/ gene regulation and signaling, and may lead to specific drug targets.
PfPP5 represents the first TPR-containing protein discovered in the Apicomplexan parasites. In view of the essential role of TPR domains in protein-protein interaction, further studies of PfPP5 and its TPR domain will shed new light on phosphatase regulation and the role of PP5 in these clinically important parasites. As with mammalian PP5, PfPP5 may also play an important role in cell division through its interaction with parasitic CDC proteins. Interaction between the Plasmodium PP5 and heat shock protein 90 may reflect a mutual relationship between protein phosphorylation and protein folding in this parasite. The role of TPR in this interaction can be addressed through structure-function analysis of the recombinant proteins.
PCR and other procedures
The following oligodeoxynucleotide primers were designed against the putative PfPP5 sequence found on chromosome 13 (AL049185; Plasmodium falciparum chr13_002073): ATGTTACACAACCATGATGTAGAAGAAG;TAAATGTTTTGATACAAATTATGAGC. These primers were used to amplify the PfPP5 gene or the cDNA using the Pf3D7 genomic DNA or Dd2 total RNA as template with PCR and RT-PCR, respectively. The RT reaction was performed using AMV reverse transcriptase, and all PCRs were performed with a 15:1 mixture of Taq:Pfu polymerase. The products were cloned into pGEM-T and confirmed by sequencing. The genomic and cDNA sequences were identical. This sequence was then subcloned into the XhoI and BamHI sites of the pET-15b vector by designing similar primers but containing the respective restriction sites. The TPR deletion mutant, starting at Glu-274 (bold in Fig. 1), was also amplified in a similar manner using specific primers, and then cloned. Introduction of the plasmids into E. coli BL21(DE3) cells containing the compatible RIG plasmid , induction of the proteins with IPTG, and purification through Ni-chelation chromatography were performed using the His-Bind kit reagents and procedure (Novagen).
Antibodies against PP5 and hsp90 were raised in rabbit and mouse, respectively, using standard procedures . Fatty acids were purchased from Sigma (St. Louis, MO). SDS-PAGE and Western blot using chemiluminescence-based detection were performed essentially as described . Immunoprecipitation of PfPP5 complexes followed by immunoblot analysis of the precipitate were carried out essentially as described .
Growth of Plasmodium and purification of PfPP5
P. falciparum (3D7 or Dd2) was grown in human A-positive erythrocytes and infected cells were harvested at about 15% parasitemia and lysed by the saponin method essentially as described [14, 15]. PfPP5 was partially purified using published procedures . In brief, the parasites were resuspended in buffer A (50 mM Tris-Cl, pH 7.5, 10% glycerol, 1 mM DTT) plus 20 mM NaCl, 1% Triton X-100, leupeptin (1 μg/ml), and aprotinin (1 μg/ml) at an approximate protein concentration of 10 mg per ml. The suspension was sonicated and the lysate centrifuged at 100,000 × g for 30 min. The supernatant, called "total extract", was subjected to 45%–60% ammonium sulfate fractionation. The pellet was resuspended in 10 ml of buffer B (20 mM HEPES, pH 8.5, 1 mM EDTA, 1 mM DTT), desalted on a Sephadex G-25 column equilibrated with buffer B, then subjected to sequential chromatography on a 5 ml HiTrap heparin column (Pharmacia) and then a 5 ml HiTrap Q column (Pharmacia). PP5 activity was followed during the purification by assaying trypsin-stimulated pNPPase activity. The fractions were further confirmed by Western blot using anti-PfPP5 antibody. Parasite culture was synchronized essentially as described earlier .
Phosphatase activity against pNPP or phosphohistone substrates was determined essentially as described previously. Standard assays were performed in buffer A containing 1 mM EDTA, and additional activators or inhibitors were added only where mentioned. Reactions were incubated at 37°C. 32P-labeled phosphohistone was made as described [14, 15, 18]. When using phosphohistone as substrate, reactions were carried out in 80 μl followed by quantification of the liberated 32Pi by phosphomolybdate extraction assay [14, 15, 18]. Reactions were followed with time, and results were corrected by subtraction of the corresponding values from an enzyme-free reaction. When p-nitrophenylphosphate was used as substrate (at 10 mM), the reaction was scaled up to 200 μl, and the liberated p-nitrophenol was quantitated by measurement of absorbance at 415 nm [14, 23]. Phosphatase reactions were routinely initiated with the addition of substrate. Dephosphorylation was kept to less than 10 % of the total phosphorylated substrate, and the reaction was linear with respect to enzyme concentration and time. When using potential activators (e.g., fatty acids) or inhibitors (e.g., okadaic acid), they were added to the enzyme mixture 10 minutes prior to initiating the reaction with the addition of substrate .
S. B. is a recipient of a Burroughs Wellcome New Initiatives in Malaria Research Award. This research was supported in part by NIH grant AI45803 from the National Institute of Allergy and Infectious Diseases (to S. B.). We thank Anja Oldenburg for assistance in phosphatase assays, Drs. Richard E. Honkanen and Michael Chinkers for helpful advice, Dr. Debopam Chakrabarti (University of Central Florida) for the stage-specific Pf extracts, and Titus Barik for help in sequence analysis.
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