Red blood cell defects and malaria.

Malaria is a major cause of childhood death throughout much of the tropical world. As a result, it has exerted a powerful force for the evolutionary selection of genes that confer a survival advantage. Identifying which genes are involved, and how they affect malaria risk, is a potentially useful way of exploring the host-parasite relationship. To date, some of the best-described malaria-protective polymorphisms relate to genes that affect the structure or function of red blood cells (RBC). Recent years have seen significant advances in our understanding of the importance of some of these genes, including glycophorin C (GYPC); complement receptor 1 (CR1); band 3 (SLC4A1); pyruvate kinase (Pklr); and the genes for alpha-(HBA) and beta-globin (HBB). The challenge for the future must be to convert these advances into fresh approaches to the prevention and treatment of malaria.

The Haldane malaria hypothesis: facts, artifacts, and a prophecy.

Heterozygous thalassemia and sickle cell disease produce mild hematological symptoms but provide protection against malaria mortality and severe malaria symptoms. Two explanations for resistance are considered in the literature - impaired growth of the parasite or enhanced removal by the host immune cells. A critical overview of studies that connect malaria resistance with impaired intra-erythrocytic growth is presented. All studies are fraught with two kinds of bias. The first one resides in the impossibility of reproducing the in vivo situation in the simplified model in vitro. The second stems from the generalized use of RPMI 1640 culture medium. RPMI 1640 has critically low levels of several amino acids; is devoid of hypoxanthine (essential for parasite growth) and adenine; and is low in reduced glutathione. Analysis of representative studies indicates that impaired parasite growth in heterozygous red blood cells (RBCs) may derive from nutrient limitations and, therefore, possibly be of artefactual origin. This conclusion seems plausible because studies were performed with RPMI 1640 medium at relatively high hematocrit and for prolonged periods of time. Mutations considered are particularly sensitive to nutrient deprivation because they have higher metabolic demands due to permanent oxidant stress related to unpaired globin chains, sickle hemoglobin and high levels of membrane-free iron. In addition, non-parasitized AS- and thalassemic-RBCs are dehydrated and microcytic. Thus, the number of metabolically active elements per unit of blood volume is remarkably larger in mutant RBCs compared to normocytes. The latter point may represent a confirmation of Haldane's prophetic statement: 'The corpuscles of the anaemic heterozygotes are smaller than normal, and more resistant to hypotonic solutions. It is at least conceivable that they are also more resistant to attacks by the sporozoa which cause malaria.'

Ultrastructural assessment of Plasmodium falciparum in age-fractionated thalassaemic erythrocytes.

Culture of Plasmodium falciparum in age-fractionated thalassaemic red blood cells (RBC) has shown evidence of parasite damage on light microscopy in older cells during the third culture cycle (96-144 h). In this report, parasites growing in thalassaemic trait and normal RBC were examined ultrastructurally from 96 to 144 h. All parasite stages in old thalassaemic RBC showed evidence of damage worsening with culture duration. There were cytoplasmic alterations with ribosomal damage, and parasite cytoplasm became increasingly loose and grainy, with multiple fissures. Discontinuity of the nuclear membrane with an abnormal nucleolus was seen at l20 h. Cytosomes remained normal, but damage to the food vacuole and shrunken disintegrating parasites were observed at 144 h. These changes are compatible with cellular degeneration and developmental retardation and would account for the schizont maturation arrest and reduced reinvasion rates previously reported. Increased free radicals associated with thalassaemic erythrocytes would explain these changes, further supporting the role for oxidant stress in the protective mechanism.

Unrestricted growth of Plasmodium falciparum in microcytic erythrocytes in iron deficiency and thalassaemia.

The mechanism(s) underlying the apparent resistance to malaria in certain inherited red cell disorders and iron deficiency anaemia remain poorly understood. The possibility that microcytic erythrocytes might inhibit parasite development, by physical restriction or reduced supply of nutrients, has been considered for many years, and never formally investigated. We sought to determine whether in vitro growth studies of P. falciparum could provide evidence to suggest that small red cell size contributes to malaria resistance in those red cell disorders in which microcytosis is a characteristic feature. Invasion and development of P. falciparum in iron deficient red cells (mean values for mean cell volume [MCV] 66 fl, mean cell haemoglobin [MCH] 19 pg) and in the red cells of two gene deletion forms of alpha-thalassaemia (mean MCV 71 fl, MCH 22 pg) were normal, assessed both morphologically, and by 3H-hypoxanthine incorporation. Although parasite appearances were normal in all cell types, morphological abnormalities were noted in iron deficient and thalassaemic cells parasitized by mature stages of P. falciparum, notably cellular ballooning and extreme hypochromia of the red cell cytoplasm. Using electron microscopy, the red cell cytoplasm in parasitized thalassaemic cells showed reduced electron density and abnormal reticulation. Normal invasion rates were observed following schizogony in microcytic cells of both types. Our findings indicate that whilst minor morphological abnormalities may be detected in parasitized iron deficiency and thalassaemic erythrocytes, development of P. falciparum in these conditions is not limited by small erythrocyte size.

Malaria in beta-thalassemic mice and the effects of the transgenic human beta-globin gene and splenectomy.

To investigate the protective effects of beta-thalassemia against malaria, rodent malaria parasites were studied in C57BL/6J mice with beta-thalassemia, in mice in which the thalassemia had been transgenically corrected with the human beta A-globin gene, and in hematologically normal mice. In thalassemic mice, Plasmodium chabaudi adami infection was inhibited and peak parasitemia was variably delayed. In transgenically corrected mice, infection proceeded as in normal mice. Plasmodium berghei infection proceeded more rapidly in thalassemic mice, but survival was not different. Splenectomized normal mice displayed high-level parasitemia that peaked twice and persisted as a low-level parasitemia for more than 20 days after normal intact mice were free of all parasites. Splenectomized thalassemic mice showed a delay of 5 days in attaining peak parasitemia, but the parasitemia persisted as in normal splenectomized mice. Thus, for P. chabaudi, which displayed no preference for immature erythrocytes, beta-thalassemia offers enhanced resistance for the host. However, for P. berghei, which preferentially invades reticulocytes, thalassemia is not protective. The protective effects of the normal mouse spleen were observed, but the paradoxical facilitation of parasite growth by the thalassemic spleen is a new finding that will require further experimentation to explain. This new in vivo laboratory documentation of thalassemic protection against some rodent malaria parasites may serve as a useful model in further efforts to control this major infectious disease.

Innate immunity to malaria caused by Plasmodium falciparum.

Malaria, a widespread disease caused by protozoa of the genus Plasmodium, contributes to the death of more than 2 million people each year. Resistance to antimalarial drugs is increasing, and an effective vaccine has not yet been designed. In the search for alternative means to control malaria infections, especially those caused by the most lethal species of malaria parasite, Plasmodium falciparum, our attention has turned to elucidating the relationships of the parasite and human host at the molecular level. In this review, we describe possible mechanisms by which naturally occurring genetic mutations might confer resistance to P. falciparum and how our innate immune response mediated by the phagocytic action of monocytes and macrophages acts as a first-line defence in clearing malaria infections. The potential effectiveness of novel therapies to enhance innate phagocytic clearance of malaria parasites, particularly in nonimmune people who are at greatest risk of adverse outcomes, is also discussed.

Plasmodium falciparum in vitro: diminished growth in hemoglobin H disease erythrocytes.

Studies of the ability of Plasmodium falciparum to grow in vitro in the red blood cells of subjects with certain beta-thalassemia syndromes are often difficult to interpret because of the known inhibitory effect of an elevated cellular content of human fetal hemoglobin (HbF). P falciparum therefore was cultured in vitro in the erythrocytes of subjects with hemoglobin H (HbH) disease and various other alpha-thalassemia genotypes that are unaccompanied by increased levels of HbF. Growth of the malaria parasite was markedly retarded in HbH red blood cells, when compared with growth in blood from normal control subjects. No consistent impairment of growth was seen in the erythrocytes of subjects having deletion of only one or two alpha-globin genes. These results indicate that erythrocytes with a severe thalassemia phenotype provide a less hospitable growth environment for P falciparum than normally hemoglobinized red blood cells, even in the absence of increased levels of HbF.