ABSTRACT
Background & objectives: Malaria, an ancient human infectious disease caused by five species of Plasmodium, among them Plasmodium vivax is the most widespread human malaria species and causes huge morbidity to its host. Identification of genetic marker to resolve higher genetic diversity for an ancient origin organism is a crucial task. We have analyzed genetic diversity of P. vivax field isolates using highly polymorphic antigen gene merozoite surface protein-3alpha (msp-3α) and assessed its suitability as high-resolution genetic marker for population genetic studies. Methods: 27 P. vivax field isolates collected during chloroquine therapeutic efficacy study at Chennai were analyzed for genetic diversity. PCR-RFLP was employed to assess the genetic variations using highly polymorphic antigen gene msp-3α. Results: We observed three distinct PCR alleles at msp-3α, and among them allele A showed significantly high frequency (53%, χ2 = 8.22, p = 0.001). PCR-RFLP analysis revealed 14 and 17 distinct RFLP patterns for Hha1 and Alu1 enzymes respectively. Further, RFLP analysis revealed that allele A at msp-3α is more diverse in the population compared with allele B and C. Combining Hha1 and Alu1 RFLP patterns revealed 21 distinct genotypes among 22 isolates reflects higher diversity resolution power of msp-3α in the field isolates. Interpretation & conclusion: P. vivax isolates from Chennai region revealed substantial amount of genetic diversity and comparison of allelic diversity with other antigen genes and microsatellites suggesting that msp-3α could be a high-resolution marker for genetic diversity studies among P. vivax field isolates.
ABSTRACT
Background & objectives: Plasmodium falciparum is the leading cause of mortality and causes cerebral malaria associated with sequestration caused by cytoadherence of the trophozoite and schizont-infected erythrocytes to the endothelial cells of the deep vascular beds in the brain. Pathophysiology of malaria is complicated by rosetting. Rosetting is a process of binding of uninfected erythrocytes to the erythrocytes infected with mature asexual parasites and is controlled by expression of complement receptor 1 (CR1) on RBC surface. Various polymorphic forms of CR1 are known including molecular weight polymorphism, red blood cell expression levels/density polymorphism and Knops (KN) polymorphism. The Knops blood group includes several allelic pairs; Knops a and b (Kna and Knb), McCoy a and b (McCa, McCb), Swain-Langley (Sla), and Villien (Vil). Knops phenotype Sl (a–) has been found to rosette less effectively than Sl (a+) and hence suggested to be more protective. P. falciparum cases have not reduced much as compared to the reduction in the total number of malaria cases in the past few years. In addition, P. falciparum is the leading cause for all mortality and most of the morbidity in India. We, therefore, investigated the role of CR1 Knops polymorphism in the pathophysiology of malaria in Indian population. Methods: A case control approach was used for this study. CAPS (Cleaved amplified polymorphic sequence) methodology was adopted. A total of 100 normal individuals (free from any ailment) and 100 individuals suffering from P. falciparum infection (uncomplicated malaria) were recruited for this study. Results: We found that in Indian population (normal individuals and P. falciparum-infected individuals), only the wild type allele is present. Interpretation & conclusion: We concluded that the process of rosetting in the Indian context could be occurring independently of the effect of Knops polymorphism and in part could be controlled by other polymorphisms of the CR1 gene (density and structural polymorphism).
ABSTRACT
Present report deals with the genetic diversity existing among the field isolates of Plasmodium falciparum and P. vivax in India. Isoenzymes and molecular markers were used to analyse field isolates of P. falciparum and P. vivax. High level of length polymorphism was observed in repeat nucleotide sequences of MSP-1, MSP-2 and GLURP in P. falciparum isolates and CSP, GAM-1 and MSP-3 alpha in P. vivax isolates. In study populations a high proportion of isolates (up to 60%) were comprised of more than one genetically distinct parasite type--multiclonal. Presence of identical allelic forms of enzyme and DNA variations in different geographical areas and in different years suggest that isolates belong to a single random mating population of P. vivax and P. falciparum. Observed random combination of alleles in the field isolates suggest the unlinked nature of loci studied. Study supports the feasibility of using molecular markers for the identification of recrudescence in P. falciparum from fresh infection.