Molecular genetics of mosquito resistance to malaria parasites.

Malaria parasites are transmitted by the bite of an infected mosquito, but even efficient vector species possess multiple mechanisms that together destroy most of the parasites present in an infection. Variation between individual mosquitoes has allowed genetic analysis and mapping of loci controlling several resistance traits, and the underlying mechanisms of mosquito response to infection are being described using genomic tools such as transcriptional and proteomic analysis. Malaria infection imposes fitness costs on the vector, but various forms of resistance inflict their own costs, likely leading to an evolutionary tradeoff between infection and resistance. Plasmodium development can be successfully completed onlyin compatible mosquito-parasite species combinations, and resistance also appears to have parasite specificity. Studies of Drosophila, where genetic variation in immunocompetence is pervasive in wild populations, offer a comparative context for understanding coevolution of the mosquito-malaria relationship. More broadly, plants also possess systems of pathogen resistance with features that are structurally conserved in animal innate immunity, including insects, and genomic datasets now permit useful comparisons of resistance models even between such diverse organisms.

Fluorescent Plasmodium berghei sporozoites and pre-erythrocytic stages: a new tool to study mosquito and mammalian host interactions with malaria parasites.

To track malaria parasites for biological studies within the mosquito and mammalian hosts, we constructed a stably transformed clonal line of Plasmodium berghei, PbFluspo, in which sporogonic and pre-erythrocytic liver-stage parasites are autonomously fluorescent. A cassette containing the structural gene for the FACS-adapted green fluorescent protein mutant 2 (GFPmut2), expressed from the 5' and 3' flanking sequences of the circumsporozoite (CS) protein gene, was integrated and expressed at the endogenous CS locus. Recombinant parasites, which bear a wild-type copy of CS, generated highly fluorescent oocysts and sporozoites that invaded mosquito salivary glands and were transmitted normally to rodent hosts. The parasites infected cultured hepatocytes in vitro, where they developed into fluorescent pre-erythrocytic forms. Mammalian cells infected by these parasites can be separated from non-infected cells by fluorescence activated cell sorter (FACS) analysis. These fluorescent insect and mammalian stages of P. berghei should be useful for phenotypic studies in their respective hosts, as well as for identification of new genes expressed in these parasite stages.

Genes identified by an expression screen of the vector mosquito Anopheles gambiae display differential molecular immune response to malaria parasites and bacteria.

We performed a gene expression screen of the entire transcriptome of the major African malaria vector Anopheles gambiae for immune response genes in adult female mosquitoes, which is the developmental stage infected by malaria parasites. Mosquitoes were immune-stimulated for subtractive cloning by treatment with bacterial lipopolysaccharide, a potent and general elicitor of the innate immune response, and by injury. The screen yielded a highly enriched cDNA library in which more than half of the clones were immune responsive. In this paper, we describe 23 immune-regulated genes, including putative protease inhibitors, serine proteases, regulatory molecules, and a number of genes without known relatives. A molecule related to the protease inhibitor alpha-2-macroglobulin responded strongly to malaria parasite infection, but displayed little or no response to bacteria, whereas other genes exhibited the inverse pattern. These results indicate that the insect immune system discriminates between molecular signals specific to infection with bacteria and malaria parasites.

Identification of surface molecules on salivary glands of the mosquito, Aedes aegypti, by a panel of monoclonal antibodies.

Malaria transmission by the mosquito vector requires sporozoite invasion into mosquito salivary glands. Parasites probably enter the glands by specific receptor-ligand interactions with molecules on the surface of the glands. We have undertaken the characterization of salivary gland surface molecules of Aedes aegypti to identify candidate receptors for Plasmodium gallinaceum sporozoite invasion. Monoclonal antibodies (mAbs) were generated against antigen enriched for salivary gland membranes and basal lamina. A panel of 44 mAbs were generated that bound to surface molecules of mosquito tissues. Twenty-four mAbs bound exclusively to salivary glands, six bound to salivary glands and ovaries, one bound to salivary gland and midgut, and 13 bound to all tissues tested. We present data on the immunolocalization and biochemical characteristics of the antigens. Many of the salivary gland-specific mAbs bound preferentially to the median and distal lateral lobes of the salivary glands, indicating that there are anatomical region-specific biochemical differences on the gland surface. These lobes of the salivary glands are the preferential sites of malaria sporozoite invasion. Therefore, antigens specific for these regions are promising candidate receptors for sporozoite invasion. The present identification of surface molecules of mosquito salivary glands by means of monoclonal antibodies represents the first description of individual molecules on the mosquito salivary gland surface. This work lays the basis for further studies on the molecular mechanisms involved in malaria sporozoite invasion of mosquito salivary glands.

Plasmodium gallinaceum: a novel morphology of malaria ookinetes in the midgut of the mosquito vector.

Malaria ookinetes invade midgut epithelial cells of the mosquito vector from the bloodmeal in the lumen of the mosquito midgut, but the cellular interactions of ookinetes with the mosquito vector remain poorly described. We describe here a novel morphology of Plasmodium gallinaceum ookinetes in which the central portion of the ookinete is an elongated narrow tube or stalk joining the anterior and posterior portions of the parasite. We propose that the previously undescribed stalkform ookinete may be an adaptation to facilitate parasite locomotion through the cytoplasm of mosquito midgut epithelial cells.

Complexities in the genetic structure of Anopheles gambiae populations in west Africa as revealed by microsatellite DNA analysis.

Chromosomal forms of Anopheles gambiae, given the informal designations Bamako, Mopti, and Savannah, have been recognized by the presence or absence of four paracentric inversions on chromosome 2. Studies of karyotype frequencies at sites where the forms occur in sympatry have led to the suggestion that these forms represent species. We conducted a study of the genetic structure of populations of An. gambiae from two villages in Mali, west Africa. Populations at each site were composed of the Bamako and Mopti forms and the sibling species, Anopheles arabiensis. Karyotypes were determined for each individual mosquito and genotypes at 21 microsatellite loci determined. A number of the microsatellites have been physically mapped to polytene chromosomes, making it possible to select loci based on their position relative to the inversions used to define forms. We found that the chromosomal forms differ at all loci on chromosome 2, but there were few differences for loci on other chromosomes. Geographic variation was small. Gene flow appears to vary among different regions within the genome, being lowest on chromosome 2, probably due to hitchhiking with the inversions. We conclude that the majority of observed genetic divergence between chromosomal forms can be explained by forces that need not involve reproductive isolation, although reproductive isolation is not ruled out. We found low levels of gene flow between the sibling species Anopheles gambiae and Anopheles arabiensis, similar to estimates based on observed frequencies of hybrid karyotypes in natural populations.

Gametocyte infectivity by direct mosquito feeds in an area of seasonal malaria transmission: implications for Bancoumana, Mali as a transmission-blocking vaccine site.

Infectivity of gametocytemic volunteers living in Bancoumana, a village 60 km from Bamako, Mali, was determined by direct feeds of laboratory-reared Anopheles gambiae s. l. Gametocytemic adolescents (10-18 years old) were as infectious to mosquitoes as younger volunteers and appear to be a more suitable population for testing transmission-blocking efficacy as compared with adults (> 18 years old). To begin to validate the membrane-feeding assay, sera collected from these same volunteers were subjected to a standard membrane-feeding assay. The data suggest that areas with intense but seasonal transmission might be feasible sites for testing transmission-blocking vaccines because of the high gametocytemic rates, high mosquito infectivity rates, and lack of pre-existing humoral-mediated transmission-blocking activity. The differences observed between field-based direct mosquito feeds and laboratory-based membrane feeding assays suggests that caution be used in interpreting Phase I study results in which laboratory-based membrane-feeding assays are used as a surrogate for vaccine efficacy.

A novel class of supercoil-independent nuclease hypersensitive site is comprised of alternative DNA structures that flank eukaryotic genes.

The cell makes a fundamental distinction between genes and non-gene sequences, which mechanistically underlies the process of gene regulation. Here, we describe the properties of a novel class of genetic sites that reproducibly flank and delineate the coding regions of the eukaryotic genes tested. Defined in vitro reaction conditions that include altered solvation and elevated temperature rendered the sites hypersensitive to nuclease cleavage. Consequently, the complete coding regions of the Drosophila genes tested were quantitatively excised from genomic DNA or genomic clones by this treatment. Identical reaction products were generated from linear or supercoiled DNA substrates. Chemical modification and fine-structure analysis of several cleavage sites flanking Drosophila genes showed that the cleavage sites were stable nucleic acid structures that contained specific arrangements of paired and unpaired nucleotides. The locations and properties of the cleavage sites did not correspond to previously known nuclease hypersensitive sites nor to known alternative DNA structures. Thus, they appear to represent a new class of genetic site. In a deletion analysis, the minimal sequence information necessary to direct in vitro nuclease cleavage 3' to the Drosophila GART gene co-localized with the signal required for termination of transcription in vivo. The data suggest that a novel class of DNA site with distinct structural properties encodes biological information by marking the boundaries of at least some gene expression units in organisms as diverse as Plasmodium and Drosophila.

Short report: simultaneous detection by polymerase chain reaction of mosquito species and Plasmodium falciparum infection in Anopheles gambiae sensu lato.

Total RNA purified from Anopheles gambiae mosquitoes can be used for detection of both 1) infection by Plasmodium falciparum using a reverse transcriptase-polymerase chain reaction (RT-PCR) assay specific for P. falciparum ribosomal RNA (rRNA) of sporogonic stage parasites, and 2) mosquito species using a PCR assay that distinguishes members of the Anopheles gambiae complex.

Quantification of Plasmodium falciparum sporozoites by ribosomal RNA detection.

We used sequences specific to the small subunit ribosomal RNA (SSU rRNA) of the sporogonic stages of Plasmodium falciparum to design a reserve transcriptase-polymerase chain reaction (RT-PCR) assay that can detect 0.1 sporozoites in total RNA purified from potentially infected mosquitoes. We made a synthetic RNA that is amplified in the RT-PCR by the same primers as the parasite SSU rRNA and that serves as an internal control and competitive quantitation standard. We calibrated the assay for quantitation of sporozoites by making a standard curve with RNA from purified and counted sporozoites. The assay accurately measured sporozoite number with a linear range of at least three orders of magnitude in a single reaction. Some application and limitations of the assay are discussed.

Plasmodium: a quantitative molecular assay for detection of sporogonic-stage malaria parasites.

We present a molecular assay to detect malaria parasites during sporogonic development in the mosquito host. Specific primers for Plasmodium-specific small-subunit ribosomal RNA sequences not present in mosquito RNA were used in a reverse transcriptase-polymerase chain reaction (RT-PCR) assay. A synthetic RNA quantitative competitor was made which included targets for two primers and a target sequence for a hybridization probe which is also present in the natural parasite ribosome. The heterobifunctional Tth polymerase was used to carry out both reverse transcription and DNA-dependent polymerase chain reaction in a single reaction tube. Ookinetes and sporozoites, the stages from the beginning and end of sporogonic development, respectively, were both recognized in the assay. The assay was calibrated for quantitation of sporozoites by making a standard curve with counted sporozoites. The linear range of the calibrated assay allowed accurate quantitation of parasite number over at least two orders of magnitude, from 10 to 1000 sporozoites, in each RT-PCR reaction.

Plasmodium gallinaceum: sporozoite invasion of Aedes aegypti salivary glands is inhibited by anti-gland antibodies and by lectins.

There is evidence which suggests that malaria sporozoites recognize mosquito salivary glands by specific receptor-ligand interactions. We are interested in identifying the putative salivary gland receptor(s) for sporozoite invasion. We used an in vivo bioassay for sporozoite invasion of salivary glands. In this assay, purified sporozoites from mature oocytes of Plasmodium gallinaceum were injected into Aedes aegypti mosquitoes and salivary glands were dissected at different time points after injection. One half of the maximum invasion of salivary glands by sporozoites occurred by 6 hr, and salivary gland sporozoite load did not increase further after 24 hr postinjection. This assay was used to determine the effect of experimental treatments with antibodies and lectins at 24 hr postinjection. We raised a rabbit polyclonal antiserum against female Ae. aegypti salivary glands which recognized tissue-specific determinants in the basal lamina of salivary glands. Purified IgG antibody fraction of the immune serum blocked sporozoite invasion in vivo. We tested a panel of 19 lectins and found 7 which bound to salivary glands. Of these 7, succinylated wheat germ agglutinin and wheat germ agglutinin completely blocked sporozoite invasion; Pisum sativum agglutinin and soybean agglutinin partially blocked; and concanavalin A, Dolichos biflorus agglutinin, and Phaseolus vulgaris erythroagglutinin did not block. Our results suggest that sporozoites interact with glycosylated salivary gland surface molecules which serve as receptors for invasion, and which may be in the salivary gland basal lamina. Because the putative sporozoite receptors contain immunogenic determinants, it is feasible to identify them by an immunological strategy.

Plasmodium gallinaceum: a refractory mechanism of ookinete killing in the mosquito, Anopheles gambiae.

We have identified a mechanism for refractoriness to a bird malaria, Plasmodium gallinaceum, in the African vector of human malaria, Anopheles gambiae. Oocysts fail to develop in the refractory mosquitoes as a result of ookinete death which occurs within 27 hr of midgut invasion. Ultrastructural studies showed that parasite death occurs while the ookinete lies free in the midgut epithelial cell cytosol, usually surrounded by an organelle-free zone that consists of finely fibrillar material. The mechanism of parasite killing does not involve a previously described refractory mechanism of parasite encapsulation. We selected genetic lines which are refractory and susceptible to midgut infection. Genetic crossing of the lines suggests that the refractory trait is inherited as a single dominant genetic locus. Other loci probably influence oocyst number in susceptible mosquitoes. Intracellular ookinete killing appears to involve a previously unrecognized host defense mechanism against malaria parasites that involves direct destruction of the invading organism.

Microsatellite DNA and isozyme variability in a west African population of Anopheles gambiae.

Microsatellites are defined as tracts of tandemly repeated short DNA sequences. Polymorphisms in this class of DNA are currently being used to generate a genetic map of the mosquito Anopheles gambiae. In the present study we explore the potential of microsatellites as a tool for studying the genetic structure of natural populations of this malaria vector. Genetic polymorphism at twenty enzyme coding gene loci and eleven microsatellite DNA loci was surveyed in a population of An. gambiae from Mali, West Africa. All of the microsatellite loci surveyed were polymorphic, as compared to 40% of the isozyme loci. The mean heterozygosity for the isozyme loci was only 0.097 (+/- 0.0035), but for the microsatellite loci it was 0.732 (+/- 0.060). The pattern of variability was very different between isozymes and microsatellites. Typically, at an isozyme locus a single allele occurred at a frequency > or = 0.75, whereas at microsatellite loci the most common allele had a frequency < 0.50. We conclude that microsatellites provide a rich source of genetic polymorphisms for the study of the population genetics of An. gambiae and are in many ways superior to isozymes for this purpose. We discuss the potential for utilizing genetically mapped microsatellite loci to explore the effect of chromosomal inversions on the distribution of genetic polymorphisms in An. gambiae.

A general system of resistance to malaria infection in Anopheles gambiae controlled by two main genetic loci.

Genetic analysis of a system of Plasmodium refractoriness in Anopheles gambia suggests that the joint action of 2 unlinked genetic loci substantially controls expression of the susceptible and refractory phenotypes. One genetic component, here named Pif-B (for Plasmodium infectivity factor), is closely linked or identical to a polymorphic autosomal esterase locus which can be visualized by gel electrophoresis. This locus exerts the major controlling effect on susceptibility to Plasmodium cynomolgi B. The other genetic component is independent of esterase and exerts major control over refractoriness to the P. cynomolgi Ceylon strain parasite. Genetic assortment of the esterase-independent component suggests that it is controlled by 1 principal locus, here named Pif-C. The 2 genetic components of Plasmodium refractoriness appear to contribute to the same phenotype through physiologically independent means.

Association of a Plasmodium-refractory phenotype with an esterase locus in Anopheles gambiae.

In a genetically selected strain of the malaria vector Anopheles gambiae, most species of Plasmodium parasites are surrounded by melanized capsules and killed in the wall of the mosquito midgut. Genetic studies demonstrate a significant association between the refractory response to Plasmodium cynomolgi B strain and the Est A allele at an autosomal esterase locus. Increased susceptibility to parasites is associated with an alternate Est C allele. Lines selected to be homozygous for the Est A and Est C alleles show enhanced levels of refractoriness and susceptibility when compared to the unselected parental stock. Expression of the refractory phenotype is reduced much more than the susceptible phenotype at high parasite density, suggesting that refractoriness may be due to a positive effector.

Mung bean nuclease exhibits a generalized gene-excision activity upon purified Plasmodium falciparum genomic DNA.

A novel set of reaction conditions for mung bean nuclease has been described in which Plasmodium genes were specifically excised as intact fragments from purified DNA. We have now determined that under the new conditions mung bean nuclease cleaves precisely at sites outside of the coding region of every P. falciparum gene for which the extent of the protein coding region in genomic DNA is known. We conclude that this enzyme activity is probably a general one for P. falciparum genes. Introns are not specifically cleaved, although one gene contained a cleavage site within an intron. There is no direct relationship between dA.dT-richness and sites of cleavage under these conditions. Also contrary to the expectations of a model based on cleavage at denaturation bubbles, there was no general relationship between the concentration of the DNA denaturant, formamide, and the size of the resulting gene-containing fragments. Thus, the data strongly suggest the involvement of an altered DNA structure near gene boundaries in determining the recognition sites for this enzyme activity.

Genetic hypervariability of telomere-related sequences is associated with meiosis in Plasmodium falciparum.

Sequences related to those near chromosome telomeres in the human malaria parasite, Plasmodium falciparum, were extremely unstable during a genetic cross between two different clonal genotypes. Many progeny of the heterologous cross displayed telomere-homologous restriction fragments found in neither parent. A significant number of the new fragments resulted from rearrangements at chromosome-internal locations which were bounded by more complex tracts of DNA sequence. The same instability was not seen to arise during an inbreeding cross, nor during mitotic replication of parasites. Thus, a form of genetic hypervariability results from molecular events which occur during meiotic reduction and is apparent only in a cross between heterologous strains of parasite. Since other sequences were entirely stable under the same conditions, it appears that chromosome-internal blocks of telomeric sequences in the P. falciparum genome may designate conditionally unstable chromosomal domains. We discuss some potential implications of these findings for the population biology of P. falciparum.

The genetics and expression of an esterase locus in Anopheles gambiae.

The main polymorphic system of esterase isoenzymes in adults of the G3 laboratory strain of Anopheles gambiae consists of two to five major bands of activity per individual. The bands are designated 5S, 5F, 13, 14, and 15. In genetic crosses, the genes which coded for the bands assorted as three codominant alleles, Est A, Est B, and Est C, at a single autosomal locus. Homozygotes for the Est C allele were significantly underrepresented among backcross progeny. The developmental pattern of esterase expression was examined. Esterase gene expression in embryos was first detectable between 2 and 12 hr after oviposition. The initiation or termination of expression of some of the bands corresponded to boundaries between developmental stages. Most of the esterase fractions were not specifically localized within the tissues tested, with the exception of a series of bands which were restricted largely to adult male testes.

The genome of Plasmodium cynomolgi is partitioned into separable domains which appear to differ in sequence stability.

The genome of Plasmodium cynomolgi is partitioned into at least 7 distinct genetic domains. Each domain is apparently uniform in DNA density and is separable from the others by CsCl density centrifugation in the presence of Hoechst dye. The protein-encoding genes that were tested are localized in the two heaviest density domains (isochores). The ribosomal genes are in two lighter isochores as well as in one of the isochores that contains protein encoding genes. Telomeric sequences are mainly, if not exclusively, in the lightest isochores, indicating that position with regard to chromosome ends may correlate with density. Blocks of a tandemly-repeating sequence which mark genetically hypervariable chromosome regions in malaria parasites are located in all isochores. However, the rate of change associated with the blocks of sequence is much slower in some isochores than in others. This indicates that the rate of genetic change in these parasites may differ with isochore and chromosomal position. These results may also have more general biological implications since they suggest that the genetic instability often noted for tandem repeat sequences in the eukaryotic genome may be limited to only a distinct subset of the genomic complement of such sequence blocks.