The genetic basis of diversity in malaria parasites

Humanized Mice and the Rebirth of Malaria Genetic Crosses

The first experimental crosses carried out with the human malaria parasite Plasmodium falciparum played a key role in determining the genetic loci responsible for drug resistance, virulence, invasion, growth rate, and transmission. These crosses relied on splenectomized chimpanzees to complete the liver stage of the parasite's life cycle and the subsequent transition to asexual blood stage culture followed by cloning of recombinant progeny in vitro. Crosses can now be routinely carried out using human-liver-chimeric mice infused with human erythrocytes to generate hundreds of unique recombinant progeny for genetic linkage mapping, bulk segregant analysis, and high-throughput 'omics readouts. The high number of recombinant progeny should allow for unprecedented power and efficiency in the execution of a systems genetics approach to study P. falciparum biology.

Co-transmission of the non-transmissible South African Babesia bovis S24 vaccine strain during mixed infection with a field isolate

The South African Babesia bovis live blood vaccine, originating from a field isolate attenuated by 23 serial syringe passages in splenectomized calves, has lost the ability to infect the natural vector Rhipicephalus (Boophilus) microplus. In this study, infection with mixed parasites from the vaccine strain and a field isolate, resulted in transmission of both genotype populations. Comparing the field isolate and transmitted combination indicated no significant difference in their virulence, while challenge of vaccinated cattle with these isolates showed the ability of the vaccine to protect against both. Limiting dilution of the transmitted combination, followed by infection of splenectomized cattle (n=34) yielded no single infections for the vaccine strain genotype, seven clonal lines of the field isolate and one mixture of vaccine strain and field isolate. Only one of two field isolate clonal lines selected for vector transmission study was transmitted. Showing that B. bovis isolates can contain both tick transmissible and non-transmissible subpopulations. The findings of this study also indicate the probability of vaccine co-infection transmission occurring in the field, which may result in new genotype populations of B. bovis. However, the impact of this recombination with field isolates is considered negligible since a genotypically diverse population of B. bovis is already present in South Africa.

Strain theory of malaria: the first 50 years

From the 1920s to the 1970s, a large body of principles and evidence accumulated about the existence and character of 'strains' among the Plasmodium species responsible for human malaria. An extensive research literature examined the degree to which strains were autonomous, stable biological entities, distinguishable by clinical, epidemiological or other features, and how this knowledge could be used to benefit medical and public health practice. Strain theory in this era was based largely on parasite phenotypes related to clinical virulence, reactions to anti-malarial drugs, infectivity to mosquitoes, antigenic properties and host immunity, latency and relapse. Here we review the search for a definition of 'strain', suggest how the data and discussion shaped current understandings of many aspects of malaria and sketch a number of specific connections with perspectives from the past 30 years.

Species concepts and malaria parasites: detecting a cryptic species of Plasmodium

Species of malaria parasite (phylum Apicomplexa: genus Plasmodium) have traditionally been described using the similarity species concept (based primarily on differences in morphological or life-history characteristics). The biological species concept (reproductive isolation) and phylogenetic species concept (based on monophyly) have not been used before in defining species of Plasmodium. Plasmodium azurophilum, described from Anolis lizards in the eastern Caribbean, is actually a two-species cryptic complex. The parasites were studied from eight islands, from Puerto Rico in the north to Grenada in the south. Morphology of the two species is very similar (differences are indistinguishable to the eye), but one infects only erythrocytes and the other only white blood cells. Molecular data for the cytochrome b gene reveal that the two forms are reproductively isolated; distinct haplotypes are present on each island and are never shared between the erythrocyte-infecting and leucocyte-infecting species. Each forms a monophyletic lineage indicating that they diverged before becoming established in the anoles of the eastern Caribbean. This comparison of the similarity, biological and phylogenetic species concepts for malaria parasites reveals the limited value of using only similarity measures in defining protozoan species.

Plasmodium chabaudi-infected erythrocytes adhere to CD36 and bind to microvascular endothelial cells in an organ-specific way

Adherence of erythrocytes infected with Plasmodium falciparum to microvascular endothelial cells (sequestration) is considered to play an important role in parasite virulence and pathogenesis. However, the real importance of sequestration for infection and disease has never been fully assessed. The absence of an appropriate in vivo model for sequestration has been a major barrier. We have examined the rodent malaria parasite Plasmodium chabaudi chabaudi AS in mice as a potential model. Erythrocytes infected with this parasite adhere in vitro to purified CD36, a critical endothelium receptor for binding P. falciparum-infected erythrocytes. P. c. chabaudi-infected erythrocytes adhere in vitro to endothelial cells in a gamma interferon-dependent manner, suggesting the involvement of additional adhesion molecules in the binding process, as is also the case with P. falciparum-infected cells. Furthermore, plasma or sera from infected and hyperimmune mice, respectively, have the ability to block binding of infected erythrocytes to endothelial cells. In vivo, erythrocytes containing mature P. c. chabaudi parasites are sequestered from the peripheral circulation. Sequestration is organ specific, occurring primarily in the liver, although intimate contact between infected erythrocytes and endothelial cells is also observed in the spleen and brain. The results are discussed in the context of the use of this model to study (i) the relationship between endothelial cell activation and the level of sequestration and (ii) the primary function of sequestration in malaria infection.

Unstable malaria in Sudan: the influence of the dry season. Clone multiplicity of Plasmodium falciparum infections in individuals exposed to variable levels of disease transmission

Studies of infection and immunity to malaria often take little account of the fact that the amount of infectious challenge individuals receive is very variable. Classic studies in areas of holoendemic transmission showed that clinical immunity develops quite rapidly during childhood, although the processes through which increasing levels of resistance to infection are acquired are still not understood. However, holoendemic transmission is one end of the spectrum of malaria epidemiology and the development of clinical immunity is also affected by factors such as the infection rate and the local parasite species composition. An exceptionally simple type of malaria transmission occurs during the short, autumnal malaria outbreaks of the Sudanese sahel-savannah belt, where a sparse 200-500 mm of rain falls in 2-3 summer months, Plasmodium falciparum causes > 95% of malaria cases in most areas, and the entomological inoculation rate (EIR) is very low by African standards; thus the population dynamics of malaria parasites are less affected by super-infection. A comparison of certain features of parasite genetic diversity, particularly the average number of parasite clones present in infections in the Sudanese sahel and in malaria study sites with different levels of transmission, is presented. It is proposed that increasing EIRs are associated with progressively smaller increases in the average number of malaria parasite clones per host and the implications of this relationship for studies on malaria infection and immunity are discussed.

Molecular genetic approaches to parasite identification: their value in diagnostic parasitology and systematics

A wide range of approaches is available to parasitologists to aid in specific parasite identification and to formulate phylogenetic relationships. This review emphasises the usefulness of molecular genetic techniques, especially DNA-based procedures, in addressing problems of identification, characterisation and phylogeny of parasites. It should be stressed that an understanding of the various DNA approaches, techniques and target genes most likely to be effective in addressing key issues in diagnostic parasitology and systematics is still developing. Nevertheless, DNA methods clearly have great potential with regard to specificity and sensitivity, and applications will increase further with technological advance. Indeed, because of the minimal requirements for material, PCR-based methods especially should prove of immense value in future studies with parasites.

Plasmodium falciparum: In vitro characterization and human infectivity of a cloned line

The culture-adapted NF54 isolate of Plasmodium falciparum was subjected in vitro to three sequential limiting dilution titrations and the resulting clone was given the designation CVD1. DNA sequence analysis of the gene encoding the circumsporozoite (CS) protein revealed differences between CVD1 and the published NF54 CS gene. CVD1 had 1191 bp, 397 amino acids, and 42 repeat units while NF54 had 1218 bp, 405 amino acids, and 44 repeat units. The CVD1 clone was more sensitive to chloroquine than was the parental line, in vitro. Anopheles stephensi mosquitoes were infected equally by the cloned and uncloned parasites. Volunteers were readily infected by NF54 and CVD1 following infectious mosquito bites. The availability of a well-characterized, chloroquine-sensitive clone which safety infects humans should facilitate performance of experimental challenge studies to assess vaccine efficacy.

A study of the genomic diversity of Plasmodium falciparum in Senegal. 2. Typing by the use of the polymerase chain reaction

The genomic polymorphism of Plasmodium falciparum was investigated in a series of samples collected in Senegal during one transmission season. PCR analysis was performed on several genes coding for blood-stage antigens: the gene for the major merozoite surface antigen P190, the gene for the second merozoite surface antigen MSA2 and the gene coding for antigen 96tR/GBP130. In each case, several distinct forms of the genes studied were observed. Both the MAD20 and K1 allelic families of P190 genes were observed. PCR analysis of a single variable region did not differentiate each isolate. However, when the data obtained for several markers are combined, each isolate had a specific genotype. Thus, using PCR to study in parallel several loci is a useful tool to genetically type strains.

A study of the genomic diversity of Plasmodium falciparum in Senegal. 1. Typing by Southern blot analysis

The genomic polymorphism of Plasmodium falciparum was investigated in a series of samples collected in Senegal during one transmission season. Restriction site polymorphism was studied by Southern blot analysis using six different probes. The patterns of the ribosomal RNA genes and of the gene coding for antigen 2L indicated a limited genomic polymorphism. Sequences hybridizing to the repeats of the Palo Alto/Wellcome serotype of S-antigen were found in one out of twelve isolates examined. This strain was shown to express the Palo Alto serotype. Restriction fragment length polymorphism was observed for the 332 gene and the 11.1 locus. The hybridization patterns showed that each sample had a distinct 11.1 locus. A comparison of three probes (332, 11.1 and rep20) detecting fragment length polymorphism indicated that maximum sensitivity was obtained using the subtelomeric repeats rep20; less sensitive patterns were observed using the 11.1 27 bp repeat probe. By using these three probes it was found that all samples were genetically distinct.

Wild isolates of Plasmodium falciparum show extensive polymorphism in T cell epitopes of the circumsporozoite protein

Variation in the immunodominant T cell epitopes Th2R and Th3R of the Plasmodium falciparum circumsporozoite protein has been analysed from Gambian clinical isolates using the polymerase chain reaction. The degree of polymorphism in these epitopes is more extensive than that found in several geographically diverse laboratory isolates. These findings strongly suggest that it will not be feasible to include all variants in a polyvalent subunit sporozoite vaccine.

Chromosomes of malaria parasites

The advent of pulsed field gradient electrophoresis has proved remarkably useful for studying chromosomes of the genetically intractable malaria parasite Plasmodium falciparum. Advances include determination of the karyotype, a linkage map and restriction maps of individual chromosomes that enable the ordering of genes. The structural basis underlying a frequently occurring form of chromosome size polymorphism is now understood and other polymorphisms are providing tantalizing clues to the mechanisms underlying drug resistance.

The use of a DNA probe for the differentiation of rodent malaria strains and species

A clone, PCsv4, derived from a partial genomic library of the rodent malaria Plasmodium chabaudi chabaudi AS strain, contains an insert which when used as a probe at low stringency in Southern blotting of genomic DNA from a variety of strains, subspecies and species of rodent malaria parasites, results in a pattern of hybridisation which is specific to each of the DNA samples used, thus providing an accurate method to define a rodent malaria line. The insert only hybridises to DNA derived from malaria parasites of rodent species. The insert also hybridises to a small number of RNA transcripts.

Plasmodium vivax: karyotype polymorphism of field isolates

Pulse-field gradient electrophoresis (PFG) has been applied to the karyotype analysis of Plasmodium vivax isolates obtained directly from infected patients in Sri Lanka. Detection of separated chromosomes was performed either by ethidium bromide staining of gels or by hybridization with a telomer specific probe. Each of the 15 different isolates examined exhibited a different chromosome migration pattern, indicating that a high level of polymorphism prevailed in wild populations of P. vivax. Chromosome size variation was further confirmed using a P. vivax chromosome-specific probe which also demonstrated that, in each isolate, the parasite population appeared to be homogeneous. These observations were made directly on parasites from infected blood, without the necessity for culture amplification, indicating that PFG can be used on a large scale for the epidemiological analysis of wild parasite populations.

Plasmodium falciparum: analysis of karyotype polymorphism using chromosome-specific probes

Chromosome size variation in Plasmodium falciparum has been examined using a double heterogenous pulse field gradient electrophoresis apparatus and a series of chromosome-specific probes. In the 11 different isolates analyzed the chromosomal markers always hybridized to the corresponding chromosome, indicating that translocations do not significantly contribute to chromosome size variations. Furthermore, despite probes specific for chromosomes 5 and 6 no evidence was obtained to support the hypothesis of a chromosome duplication involving these chromosomes. The double heterogenous electric field combined with longer pulse times allowed the genome to be resolved into a larger number of chromosomal bands and as a result permitted the more precise mapping of cloned genes.

Malaria vaccines: immunogen selection and epitope mapping

In recent years major efforts have been made to characterize parasite antigens thought to be suitable candidates for malaria vaccines. Many of the relevant plasmodial antigens have been found to contain extensive areas of short amino acid sequences organized in tandem repeats. These are usually strongly antigenic, forming linear epitopes seen by antibodies of the infected host. Several such epitopes have been identified and subunit vaccines are being designed in which synthetic peptides or gene constructs serve as immunogens. However, as an efficient malaria vaccine should give rise to anamnestic T-dependent antibody responses following reinfection after vaccination as well as to antibody independent cell-mediated immunity, efforts are now also being made to identify T-cell epitopes on the vaccine candidate antigens. In this paper the current Plasmodium falciparum sporozoite vaccines and the merozoite antigen Pf155/RESA, a possible candidate for a P. falciparum blood stage vaccine, serve as examples to illustrate recent advances made in this area as well as some of the problems remaining to be resolved.

Chromosome size variation in the malaria parasite of rodents, Plasmodium chabaudi

Pulsed field gradient gel electrophoresis has been used to identify at least 10 large DNA fragments in the genome of the rodent malaria species Plasmodium chabaudi. The fragments range in size from approximately 650 to 5000 kb. All the fragments contain sequences homologous to a P. berghei telomere probe, suggesting that they represent intact chromosomes. Ribosomal RNA genes and P. chabaudi cDNA sequences have been mapped to specific fragments. The fragments vary in size in different cloned isolates of the parasite. In a cross between two cloned parasites differing in the sizes of chromosomes 4 and 5, independent segregation of each chromosome occurred during meiosis.

The polymorphic 11.1 locus of Plasmodium falciparum

Clone pPF11.1 encodes a Plasmodium falciparum antigen expressed during the intraerythrocytic cycle and containing tandem repeats of a 9 amino acid unit. We report here an analysis of the genomic region specific for 11.1, which extends over 30 kb. It contains two blocks of repeats, spanning 13 kb and 9 kb. The restriction map suggests that the locus may result from a gene duplication. The 11.1 region is present in all P. falciparum strains examined so far. Southern analysis of 8 distinct isolates indicates that the locus is highly polymorphic. Thus the pPF11.1 repeats constitute a sensitive and discriminating probe to type P. falciparum strains.

Genetic analysis of the human malaria parasite Plasmodium falciparum

Malaria parasites are haploid for most of their life cycle, with zygote formation and meiosis occurring during the mosquito phase of development. The parasites can be analyzed genetically by transmitting mixtures of cloned parasites through mosquitoes to permit cross-fertilization of gametes to occur. A cross was made between two clones of Plasmodium falciparum differing in enzymes, drug sensitivity, antigens, and chromosome patterns. Parasites showing recombination between the parent clone markers were detected at a high frequency. Novel forms of certain chromosomes, detected by pulsed-field gradient gel electrophoresis, were produced readily, showing that extensive rearrangements occur in the parasite genome after cross-fertilization. Since patients are frequently infected with mixtures of genetically distinct parasites, mosquito transmission is likely to provide the principal mechanisms for generating parasites with novel genotypes.

Babesia bovis: molecular and biological characteristics of cloned parasite lines

An in vivo limiting dilution technique was used to produce several Babesia bovis cloned lines with which to study the basis of virulence and immunogenicity in this parasite. DNA hybridization using a cloned DNA fragment from the BabR locus demonstrated that the cloned lines were a more restricted genetic population than the parent strain. Biosynthetic labeling and immunoprecipitation studies indicated that the cloned lines differed from each other and from the parentals in the expression of a small number of polypeptides and antigens. Animal trials with three of the lines demonstrated that the parental line contains both virulent and avirulent parasite populations, at least three of which are not tick transmissible, and that while the lines do provide significant protection against heterologous challenge, they may not give as effective protection as the parental line. These experiments demonstrated the existence of subpopulations with distinctive molecular and biological properties, providing evidence that the attenuation process is based on the selection of preexisting parasite subpopulations combined with the ability of these parasites to vary genetically.

Karyotype comparison between P. chabaudi and P. falciparum: analysis of a P. chabaudi cDNA containing sequences highly repetitive in P. falciparum

The molecular karyotypes of P. chabaudi and P. falciparum have been compared by pulse field gradient electrophoresis. P. chabaudi has 3 extra chromosomes in the 750-2000 Kb range although the overall number appears to be 14 as is the case for P. falciparum. The chromosomal location of the rRNA genes has been determined for P. chabaudi together with that of a 24 Kd antigen gene. The corresponding cDNA 443 may code for a protein unusually rich in tyrosine and contains sequences highly repetitive in P. falciparum.

Characterization of species and strains of Theileria

A variety of methods is now available for characterizing species and strains of Theileria. For many practical purposes involving field control of theileriosis, characterization on a broad basis may be sufficient, but in other areas much more precise characterization is required. Such precision can be usefully exploited only when cloned parasite populations are involved, and methods to improve parasite characterization and parasite cloning should be developed concurrently. The current methods of immunization against theileriosis involve the use of live parasite populations which are generally poorly defined and, in addition, have the capacity to undergo biological change (by selection, mutation or genetic recombination) within hosts and vectors. Such changes may be difficult to define and identify, but could have profound effects on immunization strategies. Improved methods of parasite characterization and selection, which are now becoming available, will enable parasite stocks for immunization to be identified and selected more precisely, and any biological changes that occur can be monitored. Improved methods of parasite characterization will also open the way to a better understanding of Theileria genetics and the mechanisms of heritability, which appear to differ in some fundamental ways from patterns of Mendelian inheritance. Controlled matings between selected and defined populations of parasites can be envisaged, with the aim of producing hybrid parasites for immunization. In addition, the prospects of modifying the theilerial genome by genetic manipulation become very real: transfection vectors tailored by restriction enzymes could be used to insert or modify gene sequences to develop parasites with appropriate sets of characters. It may also be possible to identify parasite genes which trigger the cytotoxic response which is so important in immunity (Eugui and Emery, 1981; Emery et al., 1981; Preston et al., 1983). Such genes might then be transfected into bovine host lymphocytes to generate immunity against the whole parasite (Iams, 1985). The gene products which are responsible for stimulating immune responses could also be synthesized artificially and used for vaccination. Methods of characterizing Theileria range from Giemsa's staining to DNA hybridization; all have a role to play, and by judicious selection of appropriate methods for particular circumstances, it is becoming possible to characterize theilerial parasites very precisely. Improved methods of characterization can, in turn, lead to a better understanding of parasite biology and to the development of improved methods of immunization and control.

Research toward malaria vaccines

Malaria exacts a toll of disease to people in the Tropics that seems incomprehensible to those only familiar with medicine and human health in the developed world. The methods of molecular biology, immunology, and cell biology are now being used to develop an antimalarial vaccine. The Plasmodium parasites that cause malaria have many stages in their life cycle. Each stage is antigenically distinct and potentially could be interrupted by different vaccines. However, achieving complete protection by vaccination may require a better understanding of the complexities of B- and T-cell priming in natural infections and the development of an appropriate adjuvant for use in humans.

Chromosome size polymorphisms in Plasmodium falciparum can involve deletions and are frequent in natural parasite populations

A comparison of independent cultured isolates of Plasmodium falciparum revealed that while chromosome number was constant, the sizes of analogous chromosomes varied widely. We show here that chromosome size polymorphisms are not generated during differentiation of the asexual blood stages, as the molecular karyotype of a cloned parasite line is constant through this part of the life cycle. Experiments using whole P. falciparum chromosomes as hybridization probes to examine polymorphisms within two independent parasite populations indicate that the polymorphisms observed here are not the consequence of large-scale interchromosomal exchanges, and imply that deletions/duplications represent one mode of generating chromosome length polymorphisms. Although the deletions probably involve repetitive DNA, we show here that structural genes for P. falciparum antigens can also be lost. Furthermore, these dramatic size polymorphisms occur not only in cultured lines of P. falciparum, but with surprising frequency in natural malarial infections.

The Wellcome Trust lecture. Genes for antigens of Plasmodium falciparum

Sporozoites ofP. falciparumand other Plasmodia appear to be fairly simple antigenically, in that there is a dominant antigen, the circumsporozoite (CS) protein that forms the sporozoite surface coat (Potocnjak, Yoshida, Nussenzweig & Nussensweig, 1980; Santoroet al.1983). Consequently, the CS protein and the gene encoding it have now been studied in considerable detail (Elliset al.1983; Godsonet al.1983; Ozakiet al.1983; Dameet al.1984; Eneaet al.1984). In contrast to sporozoites, the asexual blood stagesof P. falciparumare antigenically complex. Two-dimensional gel analyses of immunoprecipitated, biosynthetically labelled antigens indicate that repeated infection withP. falciparumresults in the synthesis of antibodies against a large number of distinct antigens (Perrin & Dayal, 1982; Brownet al.1981, 1983). In further contrast to the sporozoite, the asexual blood stages of differentP. falciparumisolates exhibit a high degree of antigenic heterogeneity (Brownet al.1983; Hallet al.1983; McBride, Walliker & Morgan, 1982). Much of this antigenic diversity is no doubt due to allelic differences but clonal populations of parasites may also have the capacity to undergo antigenic variation (Hommel, David & Oligino, 1983).

Isoenzyme variation in schizonts of Plasmodium vivax from Burma

Fifteen isolates of blood containing Plasmodium vivax were collected from hospital in-patients in Rangoon and the schizonts were harvested for starch gel electrophoresis of the following parasite isoenzymes--glucose phosphate isomerase (GPI) (EC.5.3.1.9), NADP-dependent glutamate dehydrogenase (GDH) (EC.1.4.1.4), lactate dehydrogenase (LDH) (EC.1.1.1.27) and 6-phosphogluconate dehydrogenase (6PGD) (EC.1.1.1.43). Variation was found only in GPI. The other three isoenzymes appeared to be invariant in all the isolates. Forms of GPI were recorded in two isolates of P. vivax which differed from those reported for P. falciparum; these new forms were designated GPI-4 and GPI-5.

Size variation in chromosomes from independent cultured isolates of Plasmodium falciparum

The complexity of the life cycle of the protozoan malaria parasite Plasmodium falciparum has hindered genetic analysis; even the number of chromosomes in P. falciparum is uncertain. The blood stages of rodent malaria parasites are haploid and hybridization with cloned complementary DNAs similarly suggests a haploid genome in P. falciparum blood stages (ref. 4 and our unpublished results). A novel approach to karyoptic and linkage analysis in P. falciparum has been provided recently by the technique of pulsed-field gradient (PFG) gel electrophoresis, which allows the fractionation of DNA molecules of 30-3,000 kilobases (kb), a range including the sizes of intact chromosomal DNA molecules from eukaryotes such as yeast and trypanosomatids. We describe here the fractionation by PFG electrophoresis of chromosomal DNA molecules from P. falciparum into at least seven discrete species which vary in size by up to 20% between different isolates. Several genes for P. faciparum antigens which contain repetitive sequences are located on different chromosomes. Surprisingly, two of the chromosomes seem to contain the same sequences.

Polymorphism of a high molecular weight schizont antigen of the human malaria parasite Plasmodium falciparum

Intraspecies antigenic diversity in the blood stages of the human malaria parasite Plasmodium falciparum was investigated using a collection of murine monoclonal antibodies and clones of the parasite. The results were as follows: (a) The schizont and merozoite stages of the parasite express on their surface clonally restricted antigens detectable by strain-specific antibodies in indirect immunofluorescence tests. (b) These restricted antigens are phenotypically stable characteristics of clones grown in vitro. (c) The molecules carrying the specific antigens were isolated by immunoprecipitation and were found to be parasite proteins ranging in size from Mr 190,000 to 200,000 between clones. (d) Comparative immunoprecipitation and peptide mapping of these molecules showed that each parasite clone expresses a protein that is antigenically and structurally distinct from the equivalent products of several other clones. (e) The different clonal products are, however, immunologically interrelated, since they possess determinants in common with all tested isolates of the parasite. (f) These polymorphic molecules are closely related to a previously described schizont protein of P. falciparum that is posttranslationally cleaved into fragments located on the merozoite surface. These findings show the existence of a family of related polymorphic schizont antigens (PSA) of P. falciparum, whose expression is clonally restricted, and indicate that these proteins have regions of constant and variable antigenicity. We propose that a system of immunological classification of the parasite can be developed based on the polymorphism of these proteins.

Reversal of knob formation on Plasmodium falciparum-infected erythrocytes

The human malarial parasite Plasmodium falciparum can produce surface protrusions (knobs) on infected erythrocytes; however, long-term culturing of the parasite results in the appearance of knobless cells. In this study it was found that a knob-producing clone lost the ability to produce knobs in vitro. Furthermore, a clone not producing knobs derived from the knob-producing clone regained the capacity to produce knobby cells in vitro. Certain parasite proteins were associated with the knobby phenotype but not with the knobless type. These results indicate that the parasites change in vitro in a spontaneous and reversible manner independent of immunological selection.

Studies of antigens in Plasmodium yoelii. II. Inheritance and recombination of antigenic characters

The inheritance of an antigen designated Py-1 in the rodent malaria parasite Plasmodium yoelii has been investigated. A cross was made between 2 lines differing in the electrophoretic mobility and quantity of Py-1 detected by crossed immunoelectrophoresis. In 10 clones isolated from the progeny of the cross the level of Py-1 always correlated with the virulence of the infection and it was concluded that these characters were different phenotypic effects of the same gene mutation. The electrophoretic mobility of Py-1 segregated independently of the virulence character and was therefore controlled by a different gene. These two antigenic markers also recombined with isoenzyme and drug-sensitivity characters distinguishing the parent lines.