Pfmdr2 Confers Heavy Metal Resistance to Plasmodium falciparum

Elli Rosenberg,Ilena Litus,Nurit Schwarzfuchs,Rosa Sinay,Pnina Schlesinger,Jacob Golenser,Stefan Baumeister,Klaus Lingelbach,Yaakov Pollack

doi:10.1074/jbc.m601686200

Abstract

Heavy metals are required by all organisms for normal function, but high levels of heavy metals are toxic. Therefore, homeostasis of these metals is crucial. In the human malaria-causing agent Plasmodium falciparum, the mechanisms of heavy metal transport have yet to be characterized. We have developed a P. falciparum line resistant to heavy metals from a wild-type line sensitive to heavy metals. A molecular and biochemical analysis of the involvement of the P. falciparum multidrug resistance 2 (pfmdr2) gene, an ABC-type transporter, in heavy metal homeostasis was studied. Using a novel uptake assay applied on these two strains, it was demonstrated that, when exposed to heavy metals, the sensitive line accumulates metal, whereas no accumulation was observed in the resistant line. The accumulation occurs within the parasite itself and not in the cytoplasm of the red blood cell. This difference in the accumulation pattern is not a result of amplification of the pfmdr2 gene or of a change in the expression pattern of the gene in the two lines. Sequencing of the gene from both lines revealed a major difference; a stop codon is found in the sensitive line upstream of the normal termination, resulting in a truncated protein that lacks 188 amino acids that contain a portion of the essential cytoplasmatic transporter domain, thereby rendering it inactive. In contrast, the resistant line harbors a full-length, active protein. These findings strongly suggest that the PFMDR2 protein acts as an efflux pump of heavy metals.

Highlights

Malaria, caused in the majority of cases by the protozoan parasite Plasmodium falciparum, is a major global disease [1]
Culturing the cadmium-resistant line for long periods of time in the absence of the metal had no effect on the extent of the resistance phenomenon, indicating that the change enabling the resistance is stable and is not a transient response of the parasite to cadmium exposure
Our study is based on a biochemical and molecular comparison of a P. falciparum heavy metal sensitive line and a heavy metal resistant line developed for this purpose

Summary

Introduction

Malaria, caused in the majority of cases by the protozoan parasite Plasmodium falciparum, is a major global disease [1]. Only some are essential (iron, molybdenum, manganese, zinc, nickel, copper, vanadium, cobalt, and selenium), whereas the remaining ones appear in cells as a result of their wide distribution in various ecosystems Regardless of their essentiality to life, most heavy metals are toxic to cells when their concentrations increase above a certain level. Homology was found between PFMDR2 and the heavy metaltolerance protein HMT1, which is involved in heavy metal tolerance in the fission yeast Schizosaccharomyces pombe [11, 12]. This structural similarity established our working hypothesis that pfmdr might be a candidate for conferring heavy metal resistance to P. falciparum. Examples are the Leishmania ltpgpA [16], Caenorhabditis elegans mrp1 [17], Saccharomyces cerevisiae ycf (18 –20), and the S. pombe hmt genes mentioned above

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Conclusion