Correlation of plasma butyrylcholinesterase concentration with Acethylcholinesterase H353N polymorphism in the inflammatory response of Chagas disease patients.

Trypanosoma cruzi infection triggers an intense production of pro-inflammatory cytokines mediated by T helper 1 lymphocytes, inducing the anti-inflammatory reflex of acetylcholine (ACh). The ACh concentration modulation is associated to the two major esterases, the acetylcholinesterase (AChE) and butyrylcholinesterase (BuChE). AChE H353N protein polymorphism is related to low Chagas chronic disease prognostic. In order to evaluate the correlation of plasmatic BuChE concentration and the presence of AChE H353N polymorphism in Chagas disease patients and healthy individuals, we studied two groups of individuals, one of 61 Chagas disease patients and another of 74 healthy individuals. Plasma concentration of BuChE was measured by the chemiluminescent method and AChE H353N polymorphism was investigated by PCR-RFLP and sequencing of the respective encoding AChE gene fragment. The BuChE concentration was statistically higher in Chagas disease patients, with no AChE genotype significant influence. AChE genotypes YT*A/YT*A, YT*A/YT*B and YT*B/YT*B, respectively, were expressed in 53 (86.88%), 7 (11.46%) and one (1.64%) chagasic patients, and in 68 (91.89%), 6 (8.10%) and none healthy individuals. BuChE activity may represent an important marker for chronic Chagas disease inflammatory process and prognostic. Lower BuChE concentration correlated with AChE YT*B allele, although without statistical power.

Primary structure of the Plasmodium vivax crk2 gene and interference of the yeast cell cycle upon its conditional expression.

The cdc2 gene product, a 34-kDa protein kinase, plays a universal role in the M phase of the eukaryotic cell cycle. To study the cell cycle regulation in malarial parasites, we have characterized a cdc2-related gene from the most widely distributed human malaria, Plasmodium vivax (Pvcrk2). The full-length Pvcrk2 revealed 90--99% homology with Crk2 proteins from other Plasmodium species and approximately 60% homology with p34(cdc2) proteins from higher eukaryotes. We used the temperature-sensitive Schizosaccharomyces pombe cdc2 mutant (cdc2-33(ts)) for gene complementation studies. Expression of the full-length 33-kDa PvCrk2 protein, a truncated 27-kDa version, and two chimeric proteins in which we exchanged the N- and C-terminal regions of PvCrk2 with their S. pombe counterparts at the restrictive temperature in the mutant cdc2-33(ts) did not complement the cell cycle defect. However, conditional expression of the Pvcrk2 genes or the chimera containing the C terminus from Spcdc2 in mutant cdc2-33(ts) cells produced cell-cycle-arrested phenotypes only in the induced state and at the permissive temperature. Our results thus provide the first compelling genetic evidence that the plasmodial Crk2 gene product(s) is capable of interfering with the well-conserved eukaryotic cell cycle machinery.

Characterisation of the Cdc2-related kinase 2 gene from Plasmodium knowlesi and P. berghei.

The complete sequence of the cdc2-related kinase 2 (CRK2) gene from Plasmodium knowlesi and from P. berghei was determined. In both species, the CRK2 gene is closely linked to an elongation factor 1 alpha gene. The two CRK2 proteins are highly homologous to the P. falciparum PfPK5 protein. The CRK2 gene of both species is expressed at a low level during the asexual cell-cycle within the host erythrocytes. The P. berghei CRK2 mRNA is also present in gametocytes and in stages during development in the mosquito, suggesting a role of this protein in different parts of the life cycle. A conserved sequence located in the 5' untranslated region immediately upstream of the initiator ATG has the potential to form a stem-loop structure. Although the CRK2 protein possesses most of the domains that are conserved among cdc2-proteins, neither a recombinant P. knowlesi CRK2 protein nor a recombinant P. berghei protein was able to complement a yeast cdc28ts mutant. Furthermore and in contrast to the P. falciparum PfPK5 protein, a recombinant monomeric P. knowlesi CRK2 protein showed no kinase activity.

Malaria parasites contain two identical copies of an elongation factor 1 alpha gene.

Elongation factor 1alpha (EF-1alpha) is an abundant protein in eukaryotic cells, involved chiefly in translation of mRNA on the ribosomes, and is frequently encoded by more than one gene. Here we show the presence of two identical copies of the EF-1alpha gene in the genome of three malaria parasites, Plasmodium knowlesi, P. berghei and P. falciparum. They are organized in a head-to-head orientation and both genes are expressed in a stage specific manner at a high level, indicating that the small intergenic region contains either two strong promoters or a single bidirectional one. Both genes are expressed at the same time during erythrocytic development of the parasite. This expression pattern and the 100% similarity of the two genes excludes the possibility that the duplicated genes developed in accordance to the different types of ribosomes in Plasmodium. It is more likely that the duplication reflects a gene dosage effect. Comparison of codon usage in the Cdc2-related kinase genes (CRK2) of Plasmodium, which are expressed at a very low level, with the EF-1alpha genes indicates the existence of a codon bias for highly expressed genes, as has been shown in other organisms.

Comparison of introns in a cdc2-homologous gene within a number of Plasmodium species.

The first three introns of CRK2, a cdc2-homologous gene, have been compared in a total of seven Plasmodium species. The introns were located at conserved sites, suggesting an ancestral origin. Interspecific comparison of intron sequences agreed with the previously inferred evolutionary relationships of the malaria parasites. Unlike the introns in the rodent malaria species, the similarity of the CRK2 introns was regionalized between the human parasite P. vivax and the simian parasite P. knowlesi: the central region of all three introns showed markedly less interspecific similarity than the 5' and 3' regions. This was also in contrast with the organisation and composition of homologous intron pairs from other genes of the same two species. No conservation at the level of secondary structure could be detected, even between highly similar introns. A database search for intron-containing Plasmodium genes was performed. All introns obtained in this way plus the additional CRK2 introns were scanned for the presence of putative branching site consensus sequences. For P. falciparum, we present an update of the 5' and 3' splice-site consensus.

Characterization of naturally acquired human IgG responses against the N-terminal region of the merozoite surface protein 1 of Plasmodium vivax.

The primary structure of the merozoite surface protein 1 of Plasmodium vivax (PvMSP-1) revealed the existence of conserved and polymorphic blocks of the protein among different Plasmodium species. To characterize the naturally acquired IgG antibody responses to the PvMSP-1 molecule, the entire N-terminal portion of this protein was expressed as 10 overlapping glutathione S-transferase fusion proteins. The affinity-purified recombinant products were tested by enzyme-linked immunosorbent assay and Western blot against the sera of malaria patients from the state of Rondonia, Brazil. We found that the majority of these sera did not contain IgG antibodies recognizing recombinant proteins expressing exclusively interspecies conserved blocks of the molecule. In contrast, a high proportion of these same sera reacted against recombinant products expressing interspecies polymorphic regions of this protein. The poor B cell immunogenicity of the interspecies conserved blocks of the PvMSP-1 molecule most likely reflects important and unknown structural or functional features of these regions.