The role of Y84 on domain 1 and Y87 on domain 2 of Paragonimus westermani taurocyamine kinase: Insights on the substrate binding mechanism of a trematode phosphagen kinase.

The two-domain taurocyamine kinase (TK) from Paragonimus westermani was suggested to have a unique substrate binding mechanism. We performed site-directed mutagenesis on each domain of this TK and compared the kinetic parameters Km(Tc) and Vmax with that of the wild-type to determine putative amino acids involved in substrate recognition and binding. Replacement of Y84 on domain 1 and Y87 on domain 2 with R resulted in the loss of activity for the substrate taurocyamine. Y84E mutant has a dramatic decrease in affinity and activity for taurocyamine while Y87E has completely lost catalytic activity. Substituting H and I on the said positions also resulted in significant changes in activity. Mutation of the residues A59 on the GS region of domain 1 also caused significant decrease in affinity and activity while mutation on the equivalent position on domain 2 resulted in complete loss of activity.

Phosphagen kinases of parasites: unexplored chemotherapeutic targets.

Due to the possible emergence of resistance and safety concerns on certain treatments, development of new drugs against parasites is essential for the effective control and subsequent eradication of parasitic infections. Several drug targets have been identified which are either genes or proteins essential for the parasite survival and distinct from the hosts. These include the phosphagen kinases (PKs) which are enzymes that play a key role in maintenance of homeostasis in cells exhibiting high or variable rates of energy turnover by catalizing the reversible transfer of a phosphate between ATP and naturally occurring guanidine compounds. PKs have been identified in a number of important human and animal parasites and were also shown to be significant in survival and adaptation to stress conditions. The potential of parasite PKs as novel chemotherapeutic targets remains to be explored.

[Study on molecular phylogeny of Schistosoma bovis based on mitochondrial DNA sequence and gene order].

OBJECTIVE: To determine the nucleotide sequence of the partial mitochondrial (mt) genome and the order of the mitochondrial protein-coding genes for Schistosoma bovis for analysis of possible phylogenetic position of this species in the genus Schistosoma. METHODS: The genomic DNA of adult worms were extracted by the GNT-K method. The target regions were amplified by PCR using a degenerated primer and specific primer. The PCR products were purified before ligating into the pGEM1 T-vector system. Recombinant plasmids were amplified in Escherichia coli, extracted and purified using routine methods. The nucleotide sequences were determined with an ABI PRISM 3100-Avant DNA sequencer using a BigDye Terminators v3.1 Cycle Sequencing Kit (Applied Bio-systems, CA, U.S.A.) with two T-vector specific primers (T7 and SP6). Positive colonies were sequenced with two internal specific primers to obtain the full sequence of each fragment on both strands by means of primer walking. Sequences of related schistosomes were retrieved from GenBank and aligned with our data. Gene trees were constructed using neighbor joining methods. RESULTS: The nucleotide sequence was determined and the gene order of this region in S. bovis was found as follows: NADHdehydrogenase4 (nad4)-trnQ (Gln)-trnK(Lys)-NADH dehydrogenase 3(nad3)-trnD (Asp)-NADH dehydrogenase 1(nad1). The gene order covering such region of S. bovis was similar to that of the African Schistosoma species, but strikingly different from the Asian species. Phylogenetic trees inferred from the alignment including partial nad4, nad3, partial nad1 and partial nad4+nad3+nad1 sequence for other 8 Schistosoma spp., respectively, revealed that S. bovis is placed proximally to S. haematobium in the African sub-group, which is identical with those placed by gene order in the African clade. CONCLUSION: The mtDNA analysis based on mitochondrial DNA sequence and the gene order strongly support the hypothesis that S. bovis belongs to the African schistosome clade rather than the Asian Schistosoma species.

A preliminary evaluation of a locally produced biotinylated polyclonal anti-rabies antibody for direct rapid immunohistochemical test (DRIT) in the Philippines.

Rabies is a fatal zoonotic disease endemic in developing countries of Asia and Africa. Recently, the direct rapid immunohistochemical test (DRIT) was recommended by the World Health Organization (WHO) and the World Organization for Animal Health (OIE) as a diagnostic test for rabies. Therefore, a biotinylated polyclonal antibody (pAb) against the rabies lyssavirus (RABV) nucleoprotein was developed using a plasmid cDNA vaccine derived from a challenge virus standard 11 strain. A preliminary evaluation on the efficacy of this reagent in recognizing the Philippine RABV strain was tested using banked canine hippocampal tissue samples with DRIT and the results were compared to dFAT. The effects of acetone and formalin fixation on DRIT were also assessed through immunoreactivity scores of the specimens. Of the 142 samples examined, 104 tested positive and 38 negative using both dFAT and DRIT, showing 100% agreement between the two diagnostic procedures. Moreover, no false positive or false negative results were observed using acetone and formalin fixation. Thus, locally prepared biotinylated pAb from plasmid cDNA can be used for DRIT, especially in resource-limited laboratories in the Philippines. However, these results should be confirmed with a more thorough evaluation of this technique, and the range of detection needs to be further evaluated in a larger panel of animal samples and on other lyssaviruses.

Intron sequence of the taurocyamine kinase gene as a marker to investigate genetic variation of Paragonimus species in Japan and the origins of triploidy in P. westermani.

BACKGROUND: Paragonimiasis is a foodborne parasitic infection caused by lung flukes of the genus Paragonimus. Several species of Paragonimus are endemic in Japan: P. westermani (diploid and triploid) P. miyazakii, P. ohirai and P. iloktsuenensis. The taxonomic status and genetic variability of these lung flukes remains poorly understood. METHODS: The second intron of domain 1 of the taurocyamine kinase gene (TKD1int2) region was used to explore genetic variation and differentiation of diploid and triploid P. westermani, as well as P. miyazakii, P. ohirai and P. iloktsuenensis originating from Japan. RESULTS: We found high levels of intraspecific variation in P. westermani, but only low levels of variation within the other species studied. Haplotype network and phylogenetic tree analyses demonstrated the sister-group relationship of P. ohirai and P. iloktsuenensis and the phylogenetically distant relationship of P. westermani with the other species. All individuals except for triploid P. westermani were homozygous. Each triploid contained at least one allele similar to that seen in most diploids from Chiba and one allele resembling that seen in diploids from Oita. One triploid contained three different sequences. CONCLUSIONS: Our findings suggested that the TKD1int2 region is a suitable marker for use in studying the genetic variation and phylogenetics of Paragonimus species, as well as providing clues to the origins of triploidy in P. westermani.

Phosphagen kinase in Schistosoma japonicum: II. Determination of amino acid residues essential for substrate catalysis using site-directed mutagenesis.

Phosphagen kinases (PKs) play major roles in the regulation of energy metabolism in animals. Creatine kinase (CK) is the sole PK in vertebrates, whereas several PKs are present in invertebrates. We previously identified a contiguous dimer taurocyamine kinase (TK) from the trematode Schistosoma japonicum (Sj), a causative agent of schistosomiasis. SjTK contiguous dimer is comprised of domain 1 (D1) and domain 2 (D2). In this study, we used SjTK contiguous dimer (SjTKD1D2) or truncated single-domain constructs (SjTKD1 or SjTKD2) and employed site-directed mutagenesis to investigate the enzymatic properties of TK mutants. Mutation in SjTKD1 or SjTKD2 (D1E222G or D2E225G) caused complete loss of activity for the substrate taurocyamine. Likewise, a double mutant (D1E222GD2E225G) in the contiguous dimer (D1D2) exhibited complete loss of activity for the substrate taurocyamine. However, catalytic activity in the contiguous dimer remained in both of D1 inactive mutant (D1D2D1E222G) and D2 inactive mutant (D1D2D2E225G), suggesting that efficient catalysis of SjTKD1D2 is dependent on the activity of D1 and D2. The catalytic efficiency of the mixture of both single domains (WTD1+WTD2) showed same enzymatic properties (Km(Tauro)=0.68;Vmax/Km(Tauro)=137.04) to WTD1D2 (Km(Tauro)=0.47; Vmax/Km(Tauro)=144.30). This result suggests that the contiguous dimeric structure is not essential for the catalytic efficiencies of both domains of SjTK. Vmax/Km(Tauro) of the mixture of wild-type and inactivated domains (78.02 in WTD1+D2E225G and 128.24 in D1E222G+WTD2) were higher than the corresponding mutants (47.25 in D1D2D1E222G and 46.77 in D1D2D2E225G). To identify amino acid residues that are critical for taurocyamine binding, we performed alanine scanning mutagenesis at positions 57-63 on the guanidino specificity (GS) region of the SjTKD1, which is considered to be involved in guanidino-substrate recognition. R63A and R63Y mutants lost activity for taurocyamine, suggesting that these residues are associated with taurocyamine binding. In addition, we investigated the role of Tyr84 in D1 and found an association with substrate alignment. The Y84 residue was replaced with R, H, K, I, A, and G. Although the activities of each mutant were decreased (Vmax=2.36-67.50µmolPi/min/mgprotein), Y84 mutants possess binding affinity for taurocyamine (Km(Tauro)=3.19-10.04mM). The D1Y84R, D1Y84H, D1Y84K, and D1Y84A mutants exhibited low activity for taurocyamine, whereas the D1Y84I and D1Y84G mutants exhibited slightly decreased activity compared with the other Y84 mutants. The D1Y84K mutant lost substrate synergy between taurocyamine and ATP, suggesting that this mutation moves the position of the GS loop, similar to that of lombricine kinase (LK), and interferes with taurocyamine binding. This is the first comprehensive investigation of essential amino acid residues for substrate catalysis in trematode TK.

Phosphagen kinase in Schistosoma japonicum: characterization of its enzymatic properties and determination of its gene structure.

Phosphagen kinases (PKs) play a major role in the regulation of energy metabolism in animals. Creatine kinase (CK) is the sole PK in vertebrates, whereas several PKs are present in invertebrates. Here, we report the enzymatic properties and gene structure of PK in the trematode Schistosoma japonicum (Sj). SjPK has a unique contiguous dimeric structure comprising domain 1 (D1) and domain 2 (D2). The three states of the recombinant SjPK (D1, D2, and D1D2) show a specific activity for the substrate taurocyamine. The comparison of the two domains of SjPK revealed that D1 had a high turnover rate (kcat=52.91) and D2 exhibited a high affinity for taurocyamine (Km(Tauro) =0.53±0.06). The full-length protein exhibited higher affinity for taurocyamine (Km(Tauro) =0.47±0.03) than the truncated domains (D1=1.30±0.10, D2=0.53±0.06). D1D2 also exhibited higher catalytic efficiency (kcat/Km(Tauro) =82.98) than D1 (40.70) and D2 (29.04). These results demonstrated that both domains of SjTKD1D2 interacted efficiently and remained functional. The three-dimensional structure of SjPKD1 was constructed by the homology modeling based on the transition state analog complex state of Limulus AK. This protein model of SjPKD1 suggests that the overall structure is almost conserve between SjPKD1 and Limulus AK except for the flexible loops, that is, particularly guanidino-specificity (GS) region, which is associated with the recognition of the corresponding guanidino substrate. The constructed NJ tree and the comparison of exon/intron organization suggest that SjTK has evolved from an arginine kinase (AK) gene. SjTK has potential as a novel antihelminthic drug target as it is absent in mammals and its strong activity may imply a significant role for this protein in the energy metabolism of the parasite.

Gene structure of the two-domain taurocyamine kinase from Paragonimus westermani: evidence for a distinct lineage of trematode phosphagen kinases.

Taurocyamine kinase (TK) is an enzyme that catalyzes the reversible transfer of a phosphate between ATP and taurocyamine. Annelid TKs were suggested to have evolved from a CK ancestor. However, TKs from the lung fluke Paragonimus westermani comprised another lineage. Construction of phylogenetic tree and comparison of exon/intron organization showed that P. westermani TK and other trematode TKs evolved from a molluscan arginine kinase (AK) gene. Exon shuffling probably caused the changes in amino acid sequence thereby changing the affinity from AK to TK. The present study provides new insights on the evolution of phosphagen kinases found in trematodes.

Molecular cloning and characterization of taurocyamine kinase from Clonorchis sinensis: a candidate chemotherapeutic target.

BACKGROUND: Adult Clonorchis sinensis lives in the bile duct and causes endemic clonorchiasis in East Asian countries. Phosphagen kinases (PK) constitute a highly conserved family of enzymes, which play a role in ATP buffering in cells, and are potential targets for chemotherapeutic agents, since variants of PK are found only in invertebrate animals, including helminthic parasites. This work is conducted to characterize a PK from C. sinensis and to address further investigation for future drug development. METHODOLOGY/PRINCIPAL FINDINGS: [corrected] A cDNA clone encoding a putative polypeptide of 717 amino acids was retrieved from a C. sinensis transcriptome. This polypeptide was homologous to taurocyamine kinase (TK) of the invertebrate animals and consisted of two contiguous domains. C. sinensis TK (CsTK) gene was reported and found consist of 13 exons intercalated with 12 introns. This suggested an evolutionary pathway originating from an arginine kinase gene group, and distinguished annelid TK from the general CK phylogenetic group. CsTK was found not to have a homologous counterpart in sequences analysis of its mammalian hosts from public databases. Individual domains of CsTK, as well as the whole two-domain enzyme, showed enzymatic activity and specificity toward taurocyamine substrate. Of the CsTK residues, R58, I60 and Y84 of domain 1, and H60, I63 and Y87 of domain 2 were found to participate in binding taurocyamine. CsTK expression was distributed in locomotive and reproductive organs of adult C. sinensis. Developmentally, CsTK was stably expressed in both the adult and metacercariae stages. Recombinant CsTK protein was found to have low sensitivity and specificity toward C. sinensis and platyhelminth-infected human sera on ELISA. CONCLUSION: CsTK is a promising anti-C. sinensis drug target since the enzyme is found only in the C. sinensis and has a substrate specificity for taurocyamine, which is different from its mammalian counterpart, creatine.

Molecular characterization and kinetic properties of a novel two-domain taurocyamine kinase from the lung fluke Paragonimus westermani.

Taurocyamine kinase (TK) was previously reported to be restricted to certain marine annelids; however, the present study has proven otherwise. The lung fluke Paragonimus westermani has a contiguous two-domain TK with a mass of 80216 Da consisting of 713 amino acid residues sharing higher sequence identity with molluscan arginine kinase (AK). Both domains of P. westermani TK have significant activity for the substrate taurocyamine and exhibited synergism during substrate binding. Since TK plays a key role in energy metabolism and is not present in mammals, inhibitors against P. westermani TK could be effective novel chemotherapeutic agents and could be utilized for the development of specific diagnostic tools for the detection of paragonimiasis.