Thomas F. McCutchan

A histidine-rich protein gene marks a linkage group favored strongly in a genetic cross of Plasmodium falciparum

Two histidine-rich protein genes in Plasmodium falciparum are related by an ancestral duplication and interchromosomal transposition. We have followed the inheritance of these genes in a cross between two clones of P. falciparum. Examination of progeny shows that one gene, encoding the protein HRP-II, behaves as expected and may be inherited from either parent. The other gene, encoding HRP-III, has been found to derive from one parent in all progeny examined. We conclude the linkage group marked by HRP-III is favored strongly in the cross. This linkage group spans a region at one end of chromosome 13. Growth studies suggest the favored inheritance is explained by rapid expansion of progeny possessing the HRP-III marker relative to slower growth of progeny without it.

INHIBITION OF PLASMODIUM FALCIPARUM PROTEIN SYNTHESIS : TARGETING THE PLASTID-LIKE ORGANELLE WITH THIOSTREPTON

The human malaria parasite Plasmodium falciparum has two extrachromosomal DNAs associated with organelles whose function is unclear. Both genomes encode ribosomal RNAs (rRNAs) that are distinct from the nuclear-encoded rRNAs. Secondary structure analysis of all the P. falciparum rRNAs indicates that only the large subunit (LSU) rRNA encoded by the plastid-like genome is the target for thiostrepton. Indeed we find that thiostrepton inhibits growth of the parasite in the micromolar range which is 10-fold below concentrations with observable effects on total protein synthesis. We have further examined selective effects of thiostrepton on the plastid function by comparing differential effects of the drug on cytoplasmic and organellar encoded transcripts. Treatment with either thiostrepton or rifampin, an inhibitor of organellar and eubacterial RNA polymerase, both showed disappearance of organellar-encoded RNA transcripts within 6 h of treatment while transcripts of a nuclear-encoded mRNA remained constant for at least 8 h of treatment. Hence, we show a selective effect on organelle function that is suggestive of interference in the protein synthesis apparatus of the plastid. Sensitivity of P. falciparum to thiostrepton confirms that the plastid-like genome is essential for the erythrocytic cycle and presents a novel therapeutic site for this class of antibiotics.

The genome of Schistosoma mansoni: Isolation of DNA, its size, bases and repetitive sequences

DNA has been prepared from adults and cercariae of Schistosoma mansoni utilizing a technique that involves centrifugation through cesium chloride. The DNA isolated from S. mansoni adults and that isolated from cercariae were found to be indistinguishable in all analyses. No modified bases were detected by chromatography or comparative endonuclease restriction. Cot analysis demonstrated that the haploid genome of S. mansoni is 0.26 pg (2.7 X 10(8) base pairs) and that the genome contains both moderately and highly repeated components. Some of the repetitive fraction of DNA consists of tandemly repeated ribosomal genes of which there are 500-1000 copies per genome (1.8-3.6% of the total DNA). Four other non-ribosomal repetitive sequences (comprising at least a further 2.0% of the total DNA) have been isolated from a DNA clone bank and their arrangement within the S. mansoni genome investigated by restriction and Southern blot analysis. These cloned segments of DNA appear in many different locations within the genome and thus are reminiscent of the interspersed DNA sequences described in higher eukaryotic organisms.

Evidence for Different Mechanisms of Chloroquine Resistance in 2 Plasmodium Species That Cause Human Malaria

Chloroquine (CQ)-resistant Plasmodium vivax malaria was first reported 12 years ago, nearly 30 years after the recognition of CQ-resistant P. falciparum. Loss of CQ efficacy now poses a severe problem for the prevention and treatment of both diseases. Mutations in a digestive vacuole protein encoded by a 13-exon gene, pfcrt, were shown recently to have a central role in the CQ resistance (CQR) of P. falciparum. Whether mutations in pfcrt orthologues of other Plasmodium species are involved in CQR remains an open question. This report describes pfcrt homologues from P. vivax, P. knowlesi, P. berghei, and Dictyostelium discoideum. Synteny between the P. falciparum and P. vivax genes is demonstrated. However, a survey of patient isolates and monkey-adapted lines has shown no association between in vivo CQR and codon mutations in the P. vivax gene. This is evidence that the molecular events underlying P. vivax CQR differ from those in P. falciparum.

Primary sequences of two small subunit ribosomal RNA genes from Plasmodium falciparum

We have determined the complete sequence of two structurally distinct 18S ribosomal RNA genes from the malarial parasite Plasmodium falciparum. S1 nuclease analyses demonstrate that only one of the genes is represented in stable rRNA populations isolated from blood-stage parasites. Comparisons of homologous rRNA genes from Plasmodium berghei and P. falciparum reveal that they are identical at 86% of their positions. From comparisons of the Plasmodium genes to that of humans, it was possible to design genus-specific as well as species-specific oligonucleotide probes that can be used to distinguish the parasite 18S ribosomal RNA from that of its host. The utilization of these probes as diagnostic reagents is discussed.

Disruption of a Plasmodium falciparum Multidrug Resistance-associated Protein (PfMRP) Alters Its Fitness and Transport of Antimalarial Drugs and Glutathione

ATP-binding cassette transporters play an important role in drug resistance and nutrient transport. In the human malaria parasite Plasmodium falciparum, a homolog of the human p-glycoprotein (PfPgh-1) was shown to be involved in resistance to several drugs. More recently, many transporters were associated with higher IC50 levels in responses to chloroquine (CQ) and quinine (QN) in field isolates. Subsequent studies, however, could not confirm the associations, although inaccuracy in drug tests in the later studies could contribute to the lack of associations. Here we disrupted a gene encoding a putative multidrug resistance-associated protein (PfMRP) that was previously shown to be associated with P. falciparum responses to CQ and QN. Parasites with disrupted PfMRP (W2/MRPΔ) could not grow to a parasitemia higher than 5% under normal culture conditions, possibly because of lower efficiency in removing toxic metabolites. The W2/MRPΔ parasite also accumulated more radioactive glutathione, CQ, and QN and became more sensitive to multiple antimalarial drugs, including CQ, QN, artemisinin, piperaquine, and primaquine. PfMRP was localized on the parasite surface membrane, within membrane-bound vesicles, and along the straight side of the D-shaped stage II gametocytes. The results suggest that PfMRP plays a role in the efflux of glutathione, CQ, and QN and contributes to parasite responses to multiple antimalarial drugs, possibly by pumping drugs outside the parasite.

Developmental regulation of stage-specific ribosome populations in Plasmodium.

THE Plasmodium parasites are so far unique in biology in possessing develop mentally regulated ribosomal RNA gene units1. Two different genes encode their small subunit rRNAs: one gene (A) yields transcripts predominant in the asexual blood-stage parasites, and the other (C) is mainly transcribed in the sporozoite forms that develop in the mosquito1, 2. Developmental control of events allowing a switch in the complement of ribosomes must coordinate the production of the new class with selective inactivation and removal of the old. We show here that in P. falciparum the switch from A to C gene expression involves the control of rRNA processing, allowing accumulation of precursor C-gene transcripts in gametocytes. These precursor molecules are processed to mature size in the zygote and the early ookinete, where both transcription and processing of the C-gene rRNA seem to be accelerated. As the C-gene precursor rRNA appears, a defined and limited pattern of breakdown of the dominant A-gene rRNA occurs, in which conserved, functionally active sequences involved in the termination of translation and elongation are targeted. By the late oocyst stage1, the A-gene transcripts are virtually replaced by mature C-gene transcripts.

Molecular factors and biochemical pathways induced by febrile temperature in intraerythrocytic Plasmodium falciparum parasites.

ABSTRACT Intermittent episodes of febrile illness are the most benign and recognized symptom of infection with malaria parasites, although the effects on parasite survival and virulence remain unclear. In this study, we identified the molecular factors altered in response to febrile temperature by measuring differential expression levels of individual genes using high-density oligonucleotide microarray technology and by performing biological assays in asexual-stage Plasmodium falciparum parasite cultures incubated at 37°C and 41°C (an elevated temperature that is equivalent to malaria-induced febrile illness in the host). Elevated temperature had a profound influence on expression of individual genes; 336 of approximately 5,300 genes (6.3% of the genome) had altered expression profiles. Of these, 163 genes (49%) were upregulated by twofold or greater, and 173 genes (51%) were downregulated by twofold or greater. In-depth sensitive sequence profile analysis revealed that febrile temperature-induced responses caused significant alterations in the major parasite biologic networks and pathways and that these changes are well coordinated and intricately linked. One of the most notable transcriptional changes occurs in genes encoding proteins containing the predicted Pexel motifs that are exported into the host cytoplasm or inserted into the host cell membrane and are likely to be associated with erythrocyte remodeling and parasite sequestration functions. Using our sensitive computational analysis, we were also able to assign biochemical or biologic functional predictions for at least 100 distinct genes previously annotated as “hypothetical.” We find that cultivation of P. falciparum parasites at 41°C leads to parasite death in a time-dependent manner. The presence of the “crisis forms” and the terminal deoxynucleotidyltransferase-mediated dUTP-biotin nick end labeling-positive parasites following heat treatment strongly support the notion that an apoptosis-like cell death mechanism might be induced in response to febrile temperatures. These studies enhance the possibility of designing vaccines and drugs on the basis of disruption in molecules and pathways of parasite survival and virulence activated in response to febrile temperatures.

Local Adaptation and Vector-Mediated Population Structure in Plasmodium vivax Malaria

Plasmodium vivax in southern Mexico exhibits different infectivities to 2 local mosquito vectors, Anopheles pseudopunctipennis and Anopheles albimanus. Previous work has tied these differences in mosquito infectivity to variation in the central repeat motif of the malaria parasites circumsporozoite (csp) gene, but subsequent studies have questioned this view. Here we present evidence that P. vivax in southern Mexico comprised 3 genetic populations whose distributions largely mirror those of the 2 mosquito vectors. Additionally, laboratory colony feeding experiments indicate that parasite populations are most compatible with sympatric mosquito species. Our results suggest that reciprocal selection between malaria parasites and mosquito vectors has led to local adaptation of the parasite. Adaptation to local vectors may play an important role in generating population structure in Plasmodium. A better understanding of coevolutionary dynamics between sympatric mosquitoes and parasites will facilitate the identification of molecular mechanisms relevant to disease transmission in nature and provide crucial information for malaria control.

The cytoplasmic ribosomal RNAs of Plasmodium spp

Plasmodium spp maintain several structurally distinct sets of ribosomal RNA genes whose expression is developmentally regulated. This feature sets them apart from all other eukaryotes studied to date. In this review, Thomas McCutchan, Jun Li, Glenn McConkey, John Rogers and Andy Waters give an account of the progress in our understanding of this unusual phenomenon as it relates to the biology of the parasite. They also outline an interesting turnabout in scientific direction involving the use of the parasite as an important new model for the study of the eukaryotic ribosome.