Vivax Circumsporozoite Protein Research Articles

Antigenicity and immunogenicity of multiple antigen peptides (MAP) containing P. vivax CS epitopes in Aotus monkeys.

Using linear synthetic peptides corresponding to the Plasmodium vivax circumsporozoite (CS) protein of the common type, we have identified several T and B-cell epitopes recognized by human individuals. Three T-cell epitopes studied (p6) from the amino, (p11) from the central and (p25) from the carboxyl regions, were widely recognized by lymphocytes of immune donors. A series of six peptides, in addition to p11, representing the central repeat domain of the CS(p11-p17) protein were used in ELISA assays to map the B-cell epitopes of this region. P11 was the peptide most frequently recognized by sera containing antibodies to the homologous CS protein as determined by IFAT. The sequences corresponding to peptides p6, p11 and P25 as well as that representing a universal T-cell epitope derived from the tetanus toxin were used to assemble eight different Multiple Antigen Peptides (MAP). The immunogenicity of these MAP was analysed in Aotus monkeys. Groups of two animals were immunized with each MAP and both antibody response, T-lymphocyte proliferation and in vitro gamma-IFN production were evaluated. Two MAPs containing the same B-cell epitope and either a promiscuous CS-protein derived T-cell epitope (p25) or the tetanus toxin epitope (p-tt30) proved to be the most immunogenic and induced high levels of anti-peptide antibodies that recognized the native protein. Except for animals immunized with MAP VII, there was no correlation between antibody levels, lymphocyte proliferation or gamma-IFN production in vitro. The broad recognition of these epitopes by individuals which had been exposed to malaria, the capacity of these MAPs to induce antibodies, recognize the cognate protein, and in vitro gamma-IFN production encourages further analyses of the potential of these proteins as malaria vaccine candidates for human use.

Induction of protective antibodies in Saimiri monkeys by immunization with a multiple antigen construct (MAC) containing the Plasmodium vivax circumsporozoite protein repeat region and a universal T helper epitope of tetanus toxin

Previous attempts in inducing protective immunity against Plasmodium vivax in human volunteers and nonhuman primates with recombinant circumsporozoite (CS) proteins have been unsuccessful, largely due to the failure of generating antibodies against the protective B epitope AGDR in the CS protein repeat region. We report here an immunization study in Saimiri monkeys with a multiple antigen construct (MAC) containing the P. vivax CS protein repeat region and a T helper epitope of tetanus toxin formulated in different adjuvants. Monkeys immunized three times with MAC in copolymer P1005, copolymer P1005 plus RaLPS, or MF-75 had titers of antibodies against CS repeat, sporozoites and the protective B epitope AGDR significantly higher than those immunized with MAC in alum or PBS ( P<0.05). Antibody levels in animals that received P1005 were maintained at high level for 7 months after the last immunization. Upon challenge with 10000 sporozoites 2 weeks after the last immunization, 75% (three of four) of monkeys from the alum group, 50% (three of six) of moneys from the P1005 plus RaLPS group, 40% (two of five) of monkeys from the P1005 group, 33% (two of six) of monkeys from the MF-75 group, and 17% (one of six) of monkeys from the MAC alone group were fully protected. When immunized animals were challenged again with 30000 sporozoites 22 weeks after the last immunization, 40% (two of five) monkeys from the P1005 group were fully protected. The remaining (three) in this group developed low parasitemia (<2000 parasites mm −3 of blood) after significantly longer prepatent period ( P<0.05). In addition, 17% (one of six) of monkeys each from the P1005 plus RaLPS and MF-75 groups were also fully protected. Protected animals had higher levels of prechallenge anti-AGDR antibody titers than unprotected (1933 vs 281 for the first challenge, P>0.05; 21527 vs 196 for the rechallenge, P<0.05). Anti-AGDR antibody titers were positively correlated with the prepatent period of infected animals ( r=0.42 for the first challenge, P>0.05; r=0.60 for the rechallenge, P<0.05) and negatively correlated with the peak parasitemia ( r=−0.39 for the first challenge, P<0.05; r=−0.50 for the rechallenge, P<0.05). The results suggested that when combined with the use of potent adjuvants and T helper epitopes, MAC subunit vaccines may potentially offer protection against malaria infection.

Antibodies to epitopes on merozoite and sporozoite surface antigens as serologic markers of malaria transmission: studies at a site in the dry zone of Sri Lanka.

Antibodies against repetitive epitopes on Plasmodium falciparum and P. vivax circumsporozoite (CS) proteins and epitopes on the 45-kD and 185-200-kD P. falciparum merozoite surface antigens were measured by radioimmunoassay in Weheragala, a malaria-endemic site in the dry zone of Sri Lanka. Antibodies were measured in sera collected in February at the end of the main malaria transmission season and three months later in May during the low transmission period. Ninety-seven percent of the sample population had antibodies to the P. falciparum CS repeat in February and a significant proportion possessed antibodies directed against all epitopes tested. Concentrations and prevalence of antibodies to the CS repeats decreased with time after the end of malaria transmission in adults and children. Similar temporal changes were observed with antibodies to the epitopes on merozoite surface antigens. Children 7-15 years of age had lower antibody concentrations against most epitopes than adults. Antibody concentrations to two different epitopes within the same merozoite surface antigen showed significant association as did antibody levels against the P. falciparum CS repeat and the predominant P. vivax CS repeat. However, antibody concentrations did not correlate with the presence of blood-stage malaria infections.

A Study of Polymorphism in the Circumsporozoite Protein of Human Malaria Parasites

We have characterized the circumsporozoite (CS) gene sequences of Plasmodium malariae China-1 CDC, isolated recently from a person who was infected 50 years ago in China, and P. vivax Chesson, isolated 48 years ago from a patient who had returned from New Guinea. These protein sequences were compared with the CS protein sequences of recently isolated P. vivax and P. malariae parasites. In a similar manner, we compared the previously characterized CS protein gene of P. falciparum clone 7G8, derived from a Brazilian isolate collected in 1980, with the CS protein genes of recent P. falciparum field isolates. In the case of the P. malariae CS protein gene, with the exception of an additional copy of major (NAAG) and minor (NDAG) repeat sequences and the presence of one copy of NDEG sequence, the China-1 CDC P. malariae parasite is similar to the Uganda-1 CDC isolate of 1982. In the nonrepeat region, changes were noted in two amino acid residues, one of which is also seen in a closely related monkey malaria parasite, P. brasilianum. In the case of P. vivax CS proteins, the nonrepeat region of the protein in Chesson strain shares identity with nearly 71% of the CS clones characterized from field isolates. In the P. falciparum CS proteins, the 7G8 CS protein sequence is identical to 75% of the genes of recent field isolates in the Th1R-N1 region. In the Th2R and Th3R regions, 34% and 55% of the CS clones analyzed, respectively, had changes at two amino acid residues.(ABSTRACT TRUNCATED AT 250 WORDS)

Immunogenicity of multiple antigen peptides containing Plasmodium vivax CS epitopes in BALB/c mice

Multiple antigen peptide systems (MAPs) allow the incorporation of various epitopes in to a single synthetic peptide immunogen. We have characterized the immune response of BALB/c mice to a series of MAPs assembled with different B and T cell epitopes derived from the Plasmodium vivax circumsporozoite (CS) protein. A B-cell epitope from the central repeat domain and two T-cell epitopes from the amino and carboxyl flanking regions were used to assembled eight different MAPs. An additional universal T cell epitope (ptt-30) from tetanus toxin protein was included. Immunogenicity in terms of antibody responses and in vitro T lymphocyte proliferation was evaluated. MAPs containing B and T cell epitopes induced high titers of anti-peptides antibodies, which recognized the native protein on sporozoites as determined by IFAT. The antibody specificity was also determined by a competitive inhibition assay with different MAPs. A MAP containing the B cell epitope (p11) and the universal epitope ptt-30 together with another composed of p11 and the promiscuous T cell epitope (p25) proved to be the most immunogenic. The strong antibody response and specificity for the cognate protein indicates that further studies designed to assess the potential of these proteins as human malaria vaccine candidates are warranted.

Plasmodium vivax VK247 and VK210 circumsporozoite proteins in Anopheles mosquitoes from Andoas, Peru.

Anopheles mosquitoes captured in Andoas, Peru, a Plasmodium vivax-endemic area in the Peruvian Amazon region, contained both VK210 and VK247 P. vivax circumsporozoite (CS) proteins. Approximately 0.9% of the 4,403 mosquitoes tested by enzyme-linked immunosorbent assay were positive; 28% and 72% of the positive mosquitoes contained VK210 and VK247 CS proteins, respectively. These findings correlate strongly with a recent report of the presence of antibodies in residents of this area that recognize the VK210 and VK247 repeats, clearly indicating that both P. vivax CS protein polymorphs are common in the region.

Humoral and Cellular Immune Responses to the Circumsporozoite Protein of Plasmodium vivax in Madagascar

Plasmodium vivax malaria is prevalent during the rainy season in the central highlands of Madagascar. In April 1991, we investigated the cellular and antibody immune responses of 53 inhabitants of Manarintsoa, a village in this area, to four antigens corresponding to B and T cell epitopes of the P. vivax circumsporozoite (CS) protein. Cellular responses were assessed by lymphocyte proliferation assay as well as by detection of interferon-gamma and interleukin-2 production in vitro. Cell culture was performed with two overlapping synthetic peptides (CSVTCGVGVRVRSRVNA [amino acids 311-326]) and VRVRSRVNAANKKPED [amino acids 319-334]) from the vicinity of the highly conserved region II of the CS protein. In at least one of the three assays, cells from seven subjects showed a positive response to CSVTCGVGVRVRSRVNA, while cells form 14 subjects responded to VRVRSRVNAANKKPED. Antibodies directed against the two recombinant antigens, NS1(81)V20 and rPvCS-2, both of which contain the entire central repeat region of the P. vivax CS protein, plus regions I and II in the case of rPvCS-2, were measured by the Falcon assay screening test-enzyme-linked immunosorbent assay. Eight and nine subjects had antibodies to NS1(81)V20 and rPvCS-2, respectively. The presence of antibody responses to both recombinant antigens was related (P = 0.02, by Fisher's exact test), but was not related to the presence of a cellular response to peptides from vicinity of region II (P > 0.1, by Fisher's exact test).(ABSTRACT TRUNCATED AT 250 WORDS)

Low immunogenicity of a Plasmodium vivax circumsporozoite protein epitope bound by a protective monoclonal antibody.

The repeat region of the Plasmodium vivax circumsporozoite (CS) protein contains 20 copies of the nine-amino acid sequence DRA A/D GQPAG. A monoclonal antibody that passively protects monkeys against sporozoite challenge recognizes a four-amino acid linear sequence AGDR included within this nonamer, but when monkeys were immunized with a vaccine, NS1(81)V20, which contains 20 copies of the nonamer, they failed to produce antibodies to AGDR. To determine if natural exposure to sporozoites induces antibodies to AGDR, we tested sera from 176 individuals from a malaria-endemic area in Flores, Indonesia. Seventy-one percent of the adults had antibodies to the P. vivax repeat region; only 18% had detectable antibodies to AGDR. None of the subjects had antibodies to the P. vivax variant repeat ANGAGNQPG. We next tested sera from six human volunteers immunized with NS1(81)V20 and found that the vaccine, despite inducing antibodies against the nonamer, as it did in the monkeys, did not induce antibodies against AGDR. To further test our ability to raise anti-AGDR antibodies using synthetic peptides, we immunized Aotus monkeys and BALB/c mice with AGDR. Sera from the mice reacted strongly with both AGDR and a recombinant protein containing the 20 copies of the nonamer. Sera from the monkeys reacted only minimally with a protein (VIVAX-1) that contains monomeric AGDR within its sequence. Sera from the mice also bound air-dried P. vivax sporozoites, while sera from the monkeys did not.(ABSTRACT TRUNCATED AT 250 WORDS)

Malaria entomological inoculation rates in western Venezuela

Over 61 000 anophelines collected between January 1988 and October 1989 in three villages in western Venezuela were assayed by ELISA for Plasmodium vivax circumsporozoite (CS) protein. The six specimens confirmed positive belonged to three species: Anopheles ( Nyssorhynchus) nuneztovari Gabaldón, 1940, A. albitarsis Arribalzaga, 1878 sensu lato and A. oswaldoi (Peryassu, 1922). The estimated CS protein rate for all species combined was 0.01% (95% confidence limits 0.004-0.02%). This CS protein rate and the mean number of bites received by the collectors indicated a sporozoite inoculation rate of about 10.5 infective bites per person per year. From this value and the number of human malaria cases reported it was estimated that only 0.32% of bites by CS-positive mosquitoes led to a malaria infection. The CS protein rate is so low that this parameter would not be a practical indicator of the efficacy of control campaigns in this area.

The population dynamics in mosquitoes and humans of two Plasmodium vivax polymorphs distinguished by different circumsporozoite protein repeat regions.

The population dynamics of two Plasmodium vivax polymorphs were studied over a two-year period in a village in a hyperendemic area of Papua New Guinea in both the mosquito and human populations. Strains of P. vivax were distinguished by different circumsporozoite (CS) protein repeats, the VK210 (classic) and the VK247 (variant) polymorphs. In 1986, 34% of P. vivax CS protein-positive mosquitoes were of the VK247 type. Although the proportion of P. vivax sporozoite antigen-positive mosquitoes compared with all sporozoite-positive mosquitoes did not change from 1986 to 1987, the proportion of P. vivax-positive mosquitoes of the VK247 polymorph decreased significantly from 34% to 11% (5 of 45) in 1987. In 1986, 61% (47 of 77) of humans tested had IgGs that recognized the VK247 CS repeat, while only 26% (22 of 84) had IgGs that recognized the VK210 CS repeat. The observed fluctuation in the proportion of the two P. vivax CS protein polymorphs recorded in the mosquito population from 1986 to 1987 is consistent with a hypothesis of selection by humoral immune pressure on the VK247 strain.

Polymorphism in the circumsporozoite protein of the human malaria parasite Plasmodium vivax

The circumsporozoite (CS) protein that covers the surface of infectious sporozoites is a candidate antigen in malaria vaccine development. To determine the extent of B- and T-epitope polymorphism and to understand the mechanisms of antigenic variability, we have characterized the CS protein gene of Plasmodium vivax from field isolates representing geographically distant regions of Papua New Guinea (PNG) and Brazil. In the central repeat region of the CS protein, in addition to variation in the number of repeats, an array of mutations was observed which suggests that point mutations have led to the emergence of the variant CS repeat sequence ANGA(G/D)(N/D)QPG from GDRA(D/A)GQPA. Outside the repeat region of the protein, the nonsilent nucleotide substitutions of independent origin are localized in three domains of the protein that either harbor known T-cell determinants or are analogous to the Plasmodium falciparum immunodominant determinants, Th2R and Th3R. We have found that, with the exception of one CS clone sequence that was shared by one P. vivax isolate each from PNG and Brazil, the P. vivax CS protein types can be grouped into Papuan and Brazilian types. These results suggest that an in-depth study of parasite population dynamics is required before field trials for vaccine formulations based on polymorphic immunodominant determinants are conducted.

Binding of malarial circumsporozoite protein to sulfatides [Gal(3-SO 4)β1-Cer] and cholesterol-3-sulfate and its dependence on disulfide bond formation between cysteines in region II

Region II of the malaria circumsporozoite (CS) protein is highly conserved between the CS proteins of different species of malaria. Amino acid sequences homologous to that of region II are found in thrombospondin, properdin, von Willebrand factor and a few other proteins. We show here that the native CS protein from the rodent parasite Plasmodium berghei, and recombinant Plasmodium vivax and Plasmodium falciparum CS proteins containing region II, but not recombinant proteins lacking region II, specifically bind to sulfatides and cholesterol-3-sulfate. The binding is abolished following reduction and alkylation of the proteins. Region II contains 2 cysteines separated by only 3 amino acids, S(N), V, T, and these are the only cysteines present in our recombinant proteins. Therefore, our findings strongly suggest that the region II cysteines are linked by a disulfide bond forming a small peptide loop. We also present evidence that the recognition of sulfatides, cholesterol-3-sulfate, or other cross-reactive sulfated macromolecules by region II may be required during sporozoite invasion of liver cells. Antibodies to a peptide representing region II react with live sporozoites and with sporozoites fixed with glutaraldehyde, indicating that this region is exposed on the surface of the parasites. Furthermore, we have found that the sulfatide and cholesterol-3-sulfate recognition by the CS proteins, and the invasion of hepatocytes by P. berghei sporozoites, are specifically inhibited by dextran sulfate.

Human recognition of T cell epitopes on the Plasmodium vivax circumsporozoite protein.

In order to identify T cell epitopes recognized by human in the Plasmodium vivax circumsporozoite protein, 28 overlapping synthetic peptides spanning the entire circumsporozoite protein were tested for their ability to stimulate proliferation of PBMC from 22 adults living in a malaria-endemic area of the Colombian Pacific Coast and from four individuals who never had a history of malaria infection. In addition, BALB/c mice were immunized with pools of peptides, and their lymph node cells were stimulated in vitro with individual peptides. Four epitopes were recognized by human lymphocytes but not all of them by mice. One of the epitopes was located inside the central repetitive B cell immunodominant domain. Several of the variants of the repeats were recognized by about one-third of the studied individuals. Another T cell epitope was located in the amino terminus and the other two in the carboxyl region. Peptides were recognized by both immune and nonimmune donors. Some of them were frequently recognized suggesting a lack of genetic restriction, whereas some others were recognized by only a few individuals but induced strong proliferation. These epitopes may be of potential value for a malaria subunit vaccine.

Prevalence of antibody to the variant repeat of the circumsporozoite protein of Plasmodium vivax in Peru.

Individuals living in a malaria-endemic area in northern Peru were found to have antibodies to the variant repeat sequence of the circumsporozoite (CS) protein of Plasmodium vivax. The presence of IgG antibody to the predominant repeat sequence GDRAA/DGPA represented by the recombinant protein NS1(81) V20 (V20), and the variant repeat sequence ANGAGNQPG contained in the synthetic peptide Pvk247, was determined by enzyme-linked immunosorbent assay. IgG antibodies to the repeats were present in 78 (26%) of 298 serum samples; 56% of the positive serum samples had antibodies to V20 and 60% had antibodies to Pvk247. These findings stress the importance of considering the variant epitope in designing a vaccine based on the repeat region of the vivax CS protein. In a malaria-endemic area such as the one in this study, in which exposure to the variant repeat epitope may be as frequent as exposure to the predominant repeat, a vaccine based solely on the predominant repeat epitope may be ineffective against the variant form.

Antibody response to the circumsporozoite protein of Plasmodium vivax in naturally infected humans.

The circumsporozoite (CS) protein of Plasmodium vivax consists of a central repeat region flanked by highly conserved non-repeat regions. Serum samples from 33 individuals with naturally acquired infections of P. vivax were tested for antibodies to four antigens representing the vivax CS protein. Three recombinant proteins containing different overlapping sequences in the non-repeat regions and either the entire central repeat region (vivax-1 and vivax-2) or two of the repeat sequences (vivax-3) were used as antigens in an enzyme-linked immunosorbent assay (ELISA). Antibodies to two other proteins, one (NS1(81)V20) containing the entire predominant repeat region (GDRAA/DGQPA) and the other (Pvk247) containing the variant repeat sequence (ANGAGNQPG) that was recently reported from Thailand were also measured by ELISA. Immunoglobulin G antibodies to the antigen representing the predominant repeat were present in 15% of the patients on the first day of treatment (day 0) and in 24% of the patients two weeks later (post-treatment). Six and 12% of the patients had IgG antibodies to the antigen containing the variant repeat on day 0 and post-treatment, respectively. A larger proportion of the sera had antibodies to the three antigens containing the non-repeat sequences; on the first day of treatment and two weeks later, 79 and 97% of the patients, respectively, had antibodies to vivax-1, vivax-2, and vivax-3. In this sample of Peruvians naturally infected with P. vivax, the most prevalent antibody responses were targeted to epitopes in the non-repeat region of the CS protein rather than to epitopes in the repeat region.(ABSTRACT TRUNCATED AT 250 WORDS)

Safety and Immunogenicity of a Recombinant Sporozoite Malaria Vaccine against Plasmodium Vivax

A recombinant Plasmodium vivax circumsporozoite (CS) antigen representing approximately 70% of the CS protein was expressed in yeast and adsorbed onto aluminum hydroxide for use as a malaria vaccine. In a study of safety and immunogenicity, 30 volunteers were divided into four groups of 5, 5, 10, and 10 individuals, and inoculated intramuscularly with 50, 100, 200, or 400 micrograms of vaccine, respectively. Primary vaccinations were followed by two booster immunizations at six weeks and six months. Overall, the vaccine was well tolerated. Following the third vaccination, one volunteer developed acute hepatitis of uncertain etiology that resolved without sequelae. All volunteers in the 400-micrograms group, and six of 10 in the 200-micrograms group generated IgG against P. vivax CS protein, as determined by Western blot using recombinant CS protein. However, the magnitude of the antibody response measured by indirect immunofluorescence of intact sporozoites or enzyme-linked immunosorbent assay against the recombinant protein was low, and responses could not be boosted. Antigen-driven replication studies using peripheral blood lymphocytes failed to detect proliferative responses specific to peptide sequences represented in the recombinant vaccine, except in one volunteer. Minimal humoral and cell-mediated immune responses developed in most recipients who received this recombinant CS vaccine.

Wide distribution of the variant form of the human malaria parasite Plasmodium vivax.

We have found polymorphism in the repetitive and nonrepetitive regions of the sporozoite vaccine antigen, the circumsporozoite (CS) protein, in Plasmodium vivax malaria parasites from two geographically distant malaria endemic regions of the world. Like the recently described variant repeat sequence of P. vivax from Thailand, the CS protein repeat sequence of the variant P. vivax parasites from Papua New Guinea and Brazil is ANGA(G/D)(N/D)QPG, which differs from the previously identified CS repeat sequence, GDRA(D/A)GQPA, of P. vivax parasites from South America, Central America, and North Korea. Comparison of the P. vivax CS protein outside the repeat region revealed restricted polymorphism in regions that have exhibited T-cell immune function and sequence heterogeneity in the CS protein of Plasmodium falciparum. Our results show that P. vivax malaria parasites with the variant CS repeat sequences are widespread in nature and that the polymorphism in the CS protein of P. vivax is also present in the nonrepeat region.

Antibody response of humans to the circumsporozoite protein of Plasmodium vivax

We studied the interaction of sera from residents of an area in northern Peru where vivax malaria is endemic with four recombinant DNA-derived circumsporozoite (CS) proteins of Plasmodium vivax. The antigens used in the enzyme-linked immunosorbent assay included one Escherichia coli-produced and three Saccharomyces cerevisiae-produced recombinant proteins. Three of the proteins (NS1(81)V20, Vivax-1, and Vivax-2) contain the entire central repeat region of the P. vivax CS protein, and one protein (Vivax-3) contains only two repeat sequences. Vivax-1, Vivax-2, and Vivax-3 contain different lengths of sequences flanking the repeats. A higher percentage of the sera had antibodies to Vivax-2 and Vivax-3, the two proteins containing the longest nonrepeat sequences, than to NS1(81)V20 or Vivax-1. Children less than 5 years of age did not have immunoglobulin G antibodies to NS1(81)V20; however, they had antibodies to Vivax-1, Vivax-2, and Vivax-3. The finding that individuals living in a malaria-endemic area produce antibodies to peptides containing nonrepeat regions of the CS protein emphasizes the need to characterize the immune response to these regions in naturally exposed and experimentally immunized humans.

Significance of circumsporozoite-specific antibody in the natural transmission of Plasmodium falciparum, Plasmodium vivax, and Plasmodium malariae in an aboriginal (Orang Asli) population of central peninsula Malaysia.

Two hundred and seventy-five Orang Asli volunteers living in nine villages in the Pos Legap Valley of Perak State, peninsular Malaysia, participated in a prospective study designed to characterize the epidemiological, parasitological, and entomological characteristics of Plasmodium falciparum, P. vivax, and P. malariae malaria transmission. Prevalence rates for the three plasmodial species at initiation of the study ranged from 56% in the 0-4-year-old age group to 0% in individuals over the age of 40. Entomological surveys were conducted, enabling us to determine mosquito salivary gland-positive rates and entomological inoculation rates of 1.2 infectious mosquito bites per person per month for P. falciparum, 2.4 for P. vivax, and 0.3 for P. malariae. Cumulative incidence rates over the 16 weeks of the study, following radical cure of all volunteers, were 22.5% for P. falciparum, 12.7% for P. vivax, and 1.5% for P. malariae. The median baseline antibody titer against the immunodominant repetitive B cell epitope of P. falciparum or P. vivax circumsporozoite protein was significantly higher for volunteers who did not become parasitemic. Volunteers were selected for further study if they had evidence of being challenged with P. falciparum sporozoites during the study, based on a two-fold or greater increase in antibody titer against the immunodominant repetitive B cell epitope of the circumsporozoite protein. Resistance to infection was seen in six of 10 individuals who had high (greater than 25 OD units) baseline ELISA titers, compared with only three of 24 individuals who had low baseline ELISA titers (chi 2 P less than 0.02). A similar analysis for P. vivax did not show a significant correlation.

Inhibitory Activity against Plasmodium Vivax Sporozoites Induced by Plasma from Saimiri Monkeys Immunized with Circumsporozoite Recombinant Proteins or Irradiated Sporozoites

Two Saimiri monkey vaccine trials have been conducted comparing four recombinant Plasmodium vivax circumsporozoite proteins and irradiated sporozoites. Only a small number of animals immunized with certain recombinants or irradiated sporozoites became fully protected against sporozoite challenge. Preimmunization and postimmunization plasma samples obtained from 30 monkeys on the day of challenge were tested in an in vitro assay based on sporozoite development into exoerythrocytic stages in primary cultures of Saimiri monkey hepatocytes. The percentage of inhibition was determined by comparison of the number of exoerythrocytic stages developing from sporozoites preincubated with a preimmunization and a postimmunization plasma sample of each animal. The plasma samples of the day of challenge of nearly all the immunized animals had a variable, but significant inhibitory effect, when compared with the corresponding preimmunization sample. We found no correlation between the degree of in vitro inhibition of liver stage development, and the in vivo protection against sporozoite challenge of individual animals. The variable results of the incubation of sporozoites with "normal" plasma of different animals indicates that the in vitro results were affected by plasma factors unrelated to anti-sporozoite antibodies.