Stage-specific and species-specific antigens of Plasmodium vivax and Plasmodium ovale defined by monoclonal antibodies.

Monoclonal antibodies (MAbs) were produced against the asexual blood stages of Plasmodium vivax and Plasmodium ovale and used to define antigens of plasmodial parasites in an indirect fluorescent antibody assay. The anti-P. vivax MAbs produced two distinct patterns in the indirect fluorescent antibody assay. Four patterns were found with the anti-P. ovale MAbs. Species-specific epitopes were defined for P. vivax and P. ovale; epitopes shared among all four species of human malaria parasites were also defined. Some of the anti-P. vivax MAbs reacted only with mature stages, and others reacted with all asexual stages. No asexual blood-stage specificity could be found with the anti-P. ovale antibodies. Five of the anti-P. vivax MAbs and three of the anti-P. ovale MAbs also reacted with sporozoites.     

Antibodies to malaria vaccine candidates Pvs25 and Pvs28 completely block the ability of Plasmodium vivax to infect mosquitoes

Transmission-blocking vaccines are one strategy for controlling malaria, whereby sexual-stage parasites are inhibited from infecting mosquitoes by human antibodies. To evaluate whether the recently cloned Plasmodium vivax proteins Pvs25 and Pvs28 are candidates for a transmission-blocking vaccine, the molecules were expressed in yeast as secreted recombinant proteins. Mice vaccinated with these proteins adsorbed to aluminum hydroxide developed strong antibody responses against the immunogens, although for Pvs28, this response was genetically restricted. Antisera against both recombinant Pvs25 and Pvs28 recognized the corresponding molecules expressed by cultured sexual-stage parasites isolated from patients with P. vivax malaria. The development of malaria parasites in mosquitoes was completely inhibited when these antisera were ingested with the infected blood meal. Pvs25 and Pvs28, expressed in Saccharomyces cerevisiae, are as yet the only fully characterized transmission-blocking vaccine candidates against P. vivax that induce such a potent antiparasite response.     

Identification of four species of human malaria parasites by fast PCR

Malaria is one of the most prevalent infectious diseases in the world. Accurate identification of four species of human malaria parasite is essential for appropriate treatment. Here, we developed a simple and rapid method of identifying Plasmodium species using a fast polymerase chain reaction (PCR) assay. Based on the previous literature, we amplified small subunit ribosomal RNA genes of four human malaria parasites. To establish a minimum detection limit, a blood sample with a known number of P. falciparum parasites (parasitemia: 3%) was diluted serially(from 0.03% to 0.000003%). We compared the detection limits between single (one-step) PCR and nested (two-step) PCR. Other clinical blood samples, which were infected with P. falciparum (parasitemia: 2.8%), P. vivax (parasitemia: 0.13%), P. ovale (parasitemia: 0.04%), respectively, were also tested by our PCR system. The PCR findings were compared to those of blood film Giemsa staining and rapid diagnostic tests (RDT). The sensitivity of our method is less than one parasite in 1 microl of blood(estimated parasitemia: 0.000003%) for both single PCR and nested PCR, though an increased number of cycles (40 cycles) was required for single PCR. Using clinical samples, it was proven that amplified products by single PCR could clearly distinguish between P. falciparum, P. vivax, and P. ovale. To detect P. vivax and P. ovale, the PCR system was more sensitive than RDT. The total required time for our method was within three to four hours from DNA extraction to PCR detection. Taken together, our method is easier and faster than the previously reported PCR-based malaria parasite identification systems, and is also useful for cases in which diagnosis by Giemsa staining and RDT is difficult.     

Comparison of the OptiMAL Test with PCR for Diagnosis of Malaria in Immigrants

The OptiMAL test (Flow Inc., Portland, Oreg.), which detects a malaria parasite lactate dehydrogenase (pLDH) antigen, has not been evaluated for its sensitivity in the diagnosis of malaria infection in various epidemiological settings. Using microscopy and a PCR as reference standards, we performed a comparison of these assays with the OptiMAL test for the detection of Plasmodium falciparum and Plasmodium vivax infection in 550 immigrants who had come from areas where malaria is endemic to reside in Kuwait, where malaria is not endemic. As determined by microscopy, 125 (23%) patients had malaria, and of these, 84 (67%) were infected with P. vivax and 36 were infected with P. falciparum; in 5 cases the parasite species could not be determined due to a paucity of the parasites. The PCR detected malaria infection in 145 (26%) patients; 102 (70%) of the patients had P. vivax infection and 43 had P. falciparum infection. Of the five cases undetermined by microscopy, the PCR detected P. falciparum infection in two cases, P. vivax infection in two cases, and mixed (P. falciparum plus P. vivax) infection in one case. Correspondingly, the OptiMAL test detected malaria infection in 95 patients (17%); of these, 70 (74%) had P. vivax infection and 25 were infected with P. falciparum. In this study, 61 (49%) of the 125 malaria cases, as confirmed by microscopy, had a degree of parasitemia of <100 parasites per microl, and 23 (18%) of the cases had a degree of <50 parasites per microl. Our results show that the sensitivity of the OptiMAL test is high (97%) at a high level of parasitemia (>100 parasites/microl) but drops to 59% when the level is <100 parasites/microl and to 39% when it is <50 parasites/microl. In addition, the OptiMAL test failed to identify four patients whose blood smears contained P. falciparum gametocytes only. We conclude that the sensitivity and specificity of the OptiMAL test are comparable to those of microscopy in detecting malaria infection at a parasitemia level of >100 parasites/microl; however, the test failed to identify more than half of the patients with a parasitemia level of <50 parasites/microl. Thus, the OptiMAL test should be used with great caution, and it should not replace conventional microscopy in the diagnosis of malaria infection.     

检测滤纸干血滴中间日疟原虫(英文)

从滤纸干血滴上用Chelex处理洗脱下的疟原虫DNA,经套式PCR扩增间日疟原虫SSUrRNA基因特异性121bp片段,分析该方法的敏感性和特异性。37例血样检测结果全部阳性,当原虫密度低至25个原虫/uL血时仍可成功检测到该特异条带,且其它三种人疟原虫(恶性疟原虫,三日疟原虫和卵形疟原虫)血样均为阴性。提示滤纸干血滴与PCR扩增技术相结合,是疟疾诊断或流行病学调查的实用工具。     

套式PCR检测滤纸干血滴中间日疟原虫

从滤纸干血滴上用Ｃｈｅｌｅｘ处理洗脱下的疟原虫ＤＮＡ,经套式ＰＣＲ扩增间日疟虫ＳＳＵｒＲＮＡ基因特异性１２１ｂｐ片段,分析该方法的敏感性和特异性。３７例血栓检测结果一部阳性,当原虫密度低全２５个原虫／ｕＬ血时仍可成功检测到该特异条带,且其它三种人疟原虫（恶性疟虫,三日疟原虫和卵疟原虫）血样均为阴性。提示滤纸干血滴与ＰＣＲ扩增技术相结合,是疟疾诊断或流行病学调查的实用工具。     

Antifolate screening using yeast expressing Plasmodium vivax dihydrofolate reductase and in vitro drug susceptibility assay for Plasmodium falciparum

The presence of homologous point mutations in the dhfr gene in Plasmodium vivax and Plasmodium falciparum is associated with resistance to antifolate drugs. The spread of antifolate resistance encouraged research for novel antifolate drugs active against both wild-type and dhfr-mutant strains of malaria parasites. Because P. vivax cannot be easily maintained in culture, we transformed a Saccharomyces cerevisiae DHFR-deleted mutant to express wild-type P. vivax dhfr gene and its mutant forms. Twenty-five dicyclic and tricyclic 2,4-diaminopyrimidine derivatives were screened. Six quinazoline compounds showed selective inhibition of yeast transformants expressing P. vivax dhfr genes. The 50% inhibitory concentration (IC(50)) of these six compounds was determined against field isolates of P. falciparum. Our results suggest that a close relationship between the yeast assay based on expression of P. vivax dhfr genes and the in vitro test using P. falciparum parasites in culture is a promising initial step for drug screening.     

Detection of four Plasmodium species by genus- and species-specific loop-mediated isothermal amplification for clinical diagnosis

Loop-mediated isothermal amplification (LAMP), a novel nucleic acid amplification method, was developed for the clinical detection of four species of human malaria parasites: Plasmodium falciparum, P. vivax, P. malariae, and P. ovale. We evaluated the sensitivity and specificity of LAMP in comparison with the results of microscopic examination and nested PCR. LAMP showed a detection limit (analytical sensitivity) of 10 copies of the target 18S rRNA genes for P. malariae and P. ovale and 100 copies for the genus Plasmodium, P. falciparum, and P. vivax. LAMP detected malaria parasites in 67 of 68 microscopically positive blood samples (sensitivity, 98.5%) and 3 of 53 microscopically negative samples (specificity, 94.3%), in good agreement with the results of nested PCR. The LAMP reactions yielded results within about 26 min, on average, for detection of the genus Plasmodium, 32 min for P. falciparum, 31 min for P. vivax, 35 min for P. malariae, and 36 min for P. ovale. Accordingly, in comparison to the results obtained by microscopy, LAMP had a similar sensitivity and a greater specificity and LAMP yielded results similar to those of nested PCR in a shorter turnaround time. Because it can be performed with a simple technology, i.e., with heat-treated blood as the template, reaction in a water bath, and inspection of the results by the naked eye because of the use of a fluorescent dye, LAMP may provide a simple and reliable test for routine screening for malaria parasites in both clinical laboratories and malaria clinics in areas where malaria is endemic.     

Malaria transmission-blocking immunity induced by natural infections of Plasmodium vivax in humans.

Immunity to malarial infections in human populations is known to affect the development of the asexual blood stages of the parasites in the human host and to be capable of conferring significant protection against morbidity and mortality due to the disease. In this study we show that during acute infection with Plasmodium vivax malaria, one of the two main malarial pathogens of humans, most individuals also develop immunity that suppresses the infectivity of the sexual stages of the parasite to mosquitoes. The immunity is antibody mediated and is directed against the parasites in the mosquito midgut shortly after ingestion of blood by a mosquito. This immunity could be expected to have significant effects on the natural transmission of P. vivax malaria.     

Demonstration of antigenic polymorphism in Plasmodium vivax malaria with a panel of 30 monoclonal antibodies.

A panel of 30 monoclonal antibodies was established against asexual erythrocytic stages of Plasmodium vivax and used to investigate the antigenic composition of the parasite. At least 38 different antigenic polypeptides of P. vivax were characterized by the Western blot technique. The possible location of these antigens, as well as their stage and species specificity, was determined on the basis of the staining patterns produced by these antibodies on air-dried parasites in the indirect immunofluorescence test. Immunofluorescence performed with 30 different monoclonal antibodies on 50 different isolates of P. vivax obtained from patients showed that a high level of antigenic polymorphism prevailed in P. vivax. Only six monoclonal antibodies reacted with epitopes that were represented in more than 80% of parasite isolates, and therefore, appeared to be relatively conserved among different isolates. The other 24 monoclonal antibodies reacted with only 20 to 70% of parasite isolates.     

Comparison between conventional and QBC methods for diagnosis of malaria

Stained blood film examination is a widely used technique for the diagnosis of malaria. Comparison of this technique was made with the QBC method, which is based on fluorescent staining of the blood cells and parasites. Of the 1435 blood samples studied, 57 (3.97%) samples were positive for malarial parasites by QBC method, while only 44 (3.07%) samples were positive by the blood film examination. Plasmodium vivax was detected in 27 (47.37%), P. falciparum in 26 (45.61%) and mixed infection of P. vivax and P. falciparum in 4 (7.02%) cases. Samples with low levels of parasitaemia (QBC grades 1+ and 2+) were often found to be negative by blood film examination. QBC method was easy to perform, had a higher sensitivity and could be interpreted rapidly, as compared to the Leishman stained blood film examination.     

Detection and species determination of malaria parasites by PCR: comparison with microscopy and with ParaSight-F and ICT malaria Pf tests in a clinical environment

A rapid procedure for the diagnosis of malaria infections directly from dried blood spots by PCR amplification was evaluated with samples from 52 patients. Plasmodium infections were identified with a genus-specific primer set, and species differentiation between Plasmodium falciparum and Plasmodium vivax was analyzed by multiplex PCR. The PCR test with any of the three primer sets was able to detect as few as four parasites per microliter by gel electrophoresis or by nonisotopic paper hybridization chromatography. The diagnoses obtained by PCR correlated closely with those obtained by Giemsa staining except for two samples observed to have mixed P. falciparum-P. vivax infections. These were initially missed by microscopic analysis. In comparison with antigen-capture assays for P. falciparum, the PCR assays were able to detect three infections that were missed by the ParaSight-F test. The PCR test was negative for nine ParaSight-F-positive samples and one ICT Malaria Pf-positive sample, and these were confirmed to be false-positive results. The PCR thus gave no false-negative or false-positive results. Patients undergoing antimalarial therapy were also monitored by the PCR assay. Four of seven patients who were PCR positive for P. vivax at the time of discharge were later readmitted to the hospital with a recurrence of P. vivax infection. We would like to propose that PCR is a sensitive and easy method that can serve as a useful addition to microscopy for the diagnosis and the clinical monitoring of treatment of malaria.     

Human T cell proliferative responses to Plasmodium vivax antigens: evidence of immunosuppression following prolonged exposure to endemic malaria

Human T cell proliferative responses, of 33 adult Sri Lankans convalescing from Plasmodium vivax infections, to several P. vivax antigens (i.e. a soluble extract of asexual erythrocytic stage parasites and two cloned antigens that are potential vaccine candidates PV200 and GAM-1) were assessed. The peripheral blood mononuclear cell proliferative responses to the soluble extract of P. vivax, as assessed by studying both the proportion of responders and the degree of the response, were significantly lower in a group of individuals resident in a malaria endemic area in Sri Lanka than in another group that did not have a life-long exposure to malaria but had acquired the disease on a visit to an endemic region. Individuals of both groups responded equally well to mitogen. The responses to a non-malarial antigen such as purified protein derivative of tuberculin were only marginally lower in residents of the malaria-endemic region. These findings suggest that exposure to endemic P. vivax malaria leads to a specific immunosuppression to P. vivax antigens. Immunosuppression of a much lower degree was evident to a non-malarial antigen.     

Evaluation of rapid immunocapture assays for diagnosis of Plasmodium vivax in Korea

The rapid immunocapture assays, OptiMal and ICT, were evaluated from 87 individuals for the diagnosis of malaria infections directly from whole blood. A total of 87 individuals was examined for malaria parasites by microscopic examination of Giemsa-stained blood smears, and 65 cases were positive for Plasmodium vivax by microscopy. Correspondingly, the OptiMal test identified malaria infection in 45 cases (69.2%) of microscopy positive cases. Of these, two cases were misinterpreted as Plasmodium falciparum, whereas ICT detected P. vivax infection in 29 (44.6%) patients. We would like to propose that rapid immuno capture assays are an easy method that can serve as a useful tool in addition to microscopy for the diagnosis of malaria, but sensitivity is not yet satisfactory for diagnosis of P. vivax in Korea.     

Atypical forms of Plasmodium vivax. Apropos of a case]

In one case of human malaria imported from Gabon, abnormal forms of Plasmodium vivax are described; severe multiple infections of the host erythrocytes are noticed (up to 6 amoeboid trophozoites in a single red blood cell). Attention is drawn to the numerous morphologically abnormal intra-erythrocytic stages of P. vivax: severe multiple infections of red cells, parasites "ressembling" P. ovale, mature schizonts of small size, with reduced number of merozoites... The geographical distribution of P. vivax in Central Africa is discussed, with reflections on the factors allowing the importation of few P. vivax cases from this area.     

Malaria rapid diagnostic devices: performance characteristics of the ParaSight F device determined in a multisite field study

Microscopic detection of parasites has been the reference standard for malaria diagnosis for decades. However, difficulty in maintaining required technical skills and infrastructure has spurred the development of several nonmicroscopic malaria rapid diagnostic devices based on the detection of malaria parasite antigen in whole blood. The ParaSight F test is one such device. It detects the presence of Plasmodium falciparum-specific histidine-rich protein 2 by using an antigen-capture immunochromatographic strip format. The present study was conducted at outpatient malaria clinics in Iquitos, Peru, and Maesod, Thailand. Duplicate, blinded, expert microscopy was employed as the reference standard for evaluating device performance. Of 2,988 eligible patients, microscopy showed that 547 (18%) had P. falciparum, 658 (22%) had P. vivax, 2 (0.07%) had P. malariae, and 1,750 (59%) were negative for Plasmodium. Mixed infections (P. falciparum and P. vivax) were identified in 31 patients (1%). The overall sensitivity of ParaSight F for P. falciparum was 95%. When stratified by magnitude of parasitemia (no. of asexual parasites per microliter of whole blood), sensitivities were 83% (>0 to 500 parasites/microl), 87% (501 to 1,000/microl), 98% (1,001 to 5,000/microl), and 98% (>5,000/microl). Device specificity was 86%.     

Random mating of natural Plasmodium populations demonstrated from individual oocysts.

DNA amplified from individual Plasmodium vivax oocysts, produced by feeding mosquitoes directly on naturally infected humans in Thailand, was used to study cross-mating of 2 polymorphs of the circumsporozoite (CS) gene, VK 210 and VK 247. Alleles were detected in matched blood parasites, sporozoites, and individual oocysts with oligoprobes specific to characteristic repeat units. Oocysts developing from 3 cases in which mixed alleles were present in the blood parasites had genotype frequencies, including hybrids, consistent with the Hardy-Weinberg equilibrium. There was apparently no barrier to hybridization of the 2 alleles nor a bias, as has been found in some laboratory experiments, favoring hybrid formation. These are the first measurements of cross-mating frequencies directly from natural Plasmodium infections and the first observations of genetic hybridization in P. vivax.     

Anti-parasite effects of cytokines in malaria

Cytokines induced during natural malaria infections, e.g., at crisis of a blood infection of Plasmodium cynomolgi, and during clinical paroxysms in human Plasmodium vivax infections, mediate killing of intra-erythrocytic blood stage malaria parasites. These cytokines, TNF and IFN-gamma, require additional, yet unidentified complementary factors that are present in "crisis" and "paroxysm" serum to kill intra-erythrocytic blood stage parasites. In contrast, cytokines, (mainly IFN-gamma) are able to effect killing of intra-hepatic stages of the parasite by themselves independent of serum complementary factors, suggesting that the mechanisms of killing may be different with respect to the two parasite stages. Cytokines also appear to be critical intermediates in mechanisms of clinical disease in malaria. Serum cytokine (TNF) levels and killing effects on blood stage malaria parasites were lower in patients who were exposed to endemic P. vivax malaria who had partial clinical immunity, than in non-immune patients. Evidence suggest that individuals acquire natural immunity to the disease by avoiding the induction of high levels of cytokines and complementary factors.     

Apropos of the origin of some diseases raging in Madagascar

Madagascar had been separated from african continent since 5 millions years and, if flora and fauna are endemic (40 species of lemuriens) all of parasites and humans populations are imported, from africa with respect to P. falciparum, P. malariae, S. mansoni and S. haematobium (but snails are endemic ), Fasciola gigantica (imported with zebus) and perhaps P. vivax, and from Asia with respect to W. bancrofti, N. americanus, C. cellulosae (imported with pigs) and perhaps P. vivax, chromoblastomycosis is autochthonous and of high frequency. Malagasy were natives of Indonesia, Africa, Arabia and Europe.     

A quantitative analysis of the microvascular sequestration of malaria parasites in the human brain.

Microvascular sequestration was assessed in the brains of 50 Thai and Vietnamese patients who died from severe malaria (Plasmodium falciparum, 49; P. vivax, 1). Malaria parasites were sequestered in 46 cases; in 3 intravascular malaria pigment but no parasites were evident; and in the P. vivax case there was no sequestration. Cerebrovascular endothelial expression of the putative cytoadherence receptors ICAM-1, VCAM-1, E-selectin, and chondroitin sulfate and also HLA class II was increased. The median (range) ratio of cerebral to peripheral blood parasitemia was 40 (1.8 to 1500). Within the same brain different vessels had discrete but different populations of parasites, indicating that the adhesion characteristics of cerebrovascular endothelium change asynchronously during malaria and also that significant recirculation of parasitized erythrocytes following sequestration is unlikely. The median (range) ratio of schizonts to trophozoites (0.15:1; 0.0 to 11.7) was significantly lower than predicted from the parasite life cycle (P < 0.001). Antimalarial treatment arrests development at the trophozoite stages which remain sequestered in the brain. There were significantly more ring form parasites (age < 26 hours) in the cerebral microvasculature (median range: 19%; 0-90%) than expected from free mixing of these cells in the systemic circulation (median range ring parasitemia: 1.8%; 0-36.2%). All developmental stages of P. falciparum are sequestered in the brain in severe malaria.