Malaria parasite Plasmodium gallinaceum up-regulates host red blood cell channels.

The properties of the malaria parasite-induced permeability pathways in the host red blood cell have been a major area of interest particularly in the context of whether the pathways are host- or parasite-derived. In the present study, the whole-cell configuration of the patch-clamp technique has been used to show that, compared with normal cells, chicken red blood cells infected by Plasmodium gallinaceum exhibited a 5-40-fold larger membrane conductance, which could be further increased up to 100-fold by raising intracellular Ca(2+) levels. The increased conductance was not due to pathways with novel electrophysiological properties. Rather, the parasite increased the activity of endogenous 24 pS stretch-activated non-selective cationic (NSC) and 62 pS calcium-activated NSC channels, and, in some cases, of endogenous 255 pS anionic channels.

Perturbation of the pump-leak balance for Na(+) and K(+) in malaria-infected erythrocytes.

In human erythrocytes infected with the mature form of the malaria parasite Plasmodium falciparum, the cytosolic concentration of Na(+) is increased and that of K(+) is decreased. In this study, the membrane transport changes underlying this perturbation were investigated using a combination of (86)Rb(+), (43)K(+), and (22)Na(+) flux measurements and a semiquantitative hemolysis technique. From >15 h postinvasion, there appeared in the infected erythrocyte membrane new permeation pathways (NPP) that caused a significant increase in the basal ion permeability of the erythrocyte membrane and that were inhibited by furosemide (0.1 mM). The NPP showed the selectivity sequence Cs(+) > Rb(+) > K(+) > Na(+), with the K(+)-to-Na(+) permeability ratio estimated as 2.3. From 18 to 36 h postinvasion, the activity of the erythrocyte Na(+)/K(+) pump increased in response to increased cytosolic Na(+) (a consequence of the increased leakage of Na(+) via the NPP) but underwent a progressive decrease in the latter 12 h of the parasite's occupancy of the erythrocyte (36-48 h postinvasion). Incorporation of the measured ion transport rates into a mathematical model of the human erythrocyte indicates that the induction of the NPP, together with the impairment of the Na(+)/K(+) pump, accounts for the altered Na(+) and K(+) levels in the host cell cytosol, as well as predicting an initial decrease, followed by a lytic increase in the volume of the host erythrocyte.

Functional state of the plasma membrane Ca2+ pump in Plasmodium falciparum-infected human red blood cells.

The active Ca2+ transport properties of malaria-infected, intact red blood cells are unknown. We report here the first direct measurements of Ca2+ pump activity in human red cells infected with Plasmodium falciparum, at the mature, late trophozoite stage. Ca2+ pump activity was measured by the Co2+-exposure method adapted for use in low-K+ media, optimal for parasitised cells. This required a preliminary study in normal, uninfected red cells of the effects of cell volume, membrane potential and external Na+/K+ concentrations on Ca2+ pump performance. Pump-mediated Ca2+ extrusion in normal red cells was only slightly lower in low-K+ media relative to high-K+ media despite the large differences in membrane potential predicted by the Lew-Bookchin red cell model. The effect was prevented by clotrimazole, an inhibitor of the Ca2+-sensitive K+ (KCa) channel, suggesting that it was due to minor cell dehydration. The Ca2+-saturated Ca2+ extrusion rate through the Ca2+ pump (Vmax) of parasitised red cells was marginally inhibited (2-27 %) relative to that of both uninfected red cells from the malaria-infected culture (cohorts), and uninfected red cells from the same donor kept under identical conditions (co-culture). Thus, Ca2+ pump function is largely conserved in parasitised cells up to the mature, late trophozoite stage. A high proportion of the ionophore-induced Ca2+ load in parasitised red cells is taken up by cytoplasmic Ca2+ buffers within the parasite. Following pump-mediated Ca2+ removal from the host, there remained a large residual Ca2+ pool within the parasite which slowly leaked to the host cell, from which it was pumped out.

Increased permeability of the malaria-infected erythrocyte to organic cations.

The human malaria parasite, Plasmodium falciparum, induces in the plasma membrane of its host red blood cell new permeation pathways (NPP) that allow the influx of a variety of low molecular weight solutes. In this study we have demonstrated that the NPP confer upon the parasitised erythrocyte a substantial permeability to a range of monovalent organic (quaternary ammonium) cations, the largest having an estimated minimum cross-sectional diameter of 11-12 A. The rate of permeation of these cations showed a marked dependence on the nature of the anion present, increasing with the lyotropicity of the anion. There was no clear relationship between the permeation rate and either the size or the hydrophobicity of these solutes. However, the data were consistent with the rate of permeation being influenced by a combination of these two factors, with the pathways showing a marked preference for the relatively small and hydrophobic phenyltrimethylammonium ion over larger or less hydrophobic solutes. Large quaternary ammonium cations inhibited flux via the NPP, as did long-chain n-alkanols. For both classes of compound the inhibitory potency increased with the size and hydrophobicity of the solute. This study extends the range of solutes known to permeate the NPP of malaria-infected erythrocytes as well as providing some insight into the factors governing the rate of permeation.

Passive Ca(2+) transport and Ca(2+)-dependent K(+) transport in Plasmodium falciparum-infected red cells.

Previous reports have indicated that Plasmodium falciparum-infected red cells (pRBC) have an increased Ca(2+) permeability. The magnitude of the increase is greater than that normally required to activate the Ca(2+)-dependent K(+) channel (K(Ca) channel) of the red cell membrane. However, there is evidence that this channel remains inactive in pRBC. To clarify this discrepancy, we have reassessed both the functional status of the K(Ca) channel and the Ca(2+) permeability properties of pRBC. For pRBC suspended in media containing Ca(2+), K(Ca) channel activation was elicited by treatment with the Ca(2+) ionophore A23187. In the absence of ionophore the channel remained inactive. In contrast to previous claims, the unidirectional influx of Ca(2+) into pRBC in which the Ca(2+) pump was inhibited by vanadate was found to be within the normal range (30-55 micromol (10(13) cells. hr)(-1)), provided the cells were suspended in glucose-containing media. However, for pRBC in glucose-free media the Ca(2+) influx increased to over 1 mmol (10(13) cells. hr)(-1), almost an order of magnitude higher than that seen in uninfected erythrocytes under equivalent conditions. The pathway responsible for the enhanced influx of Ca(2+) into glucose-deprived pRBC was expressed at approximately 30 hr post-invasion, and was inhibited by Ni(2+). Possible roles for this pathway in pRBC are considered.

Transport properties of the host cell membrane.

The malaria-infected erythrocyte shows an increased permeability to a wide range of solutes. The increase is mediated in part by parasite-induced new permeation pathways (NPP) and in part (for some solutes, under some conditions) by increased activity of endogenous transporters. The NPP provide the major route for the influx into the infected cell of a number of essential nutrients, but although the functional characteristics of these pathways are understood in some detail, they are yet to be identified at a molecular level. Lucifer yellow, a fluorescent anion, is taken up by malaria-infected erythrocytes to a much greater extent than uninfected erythrocytes via a pathway that differs in its pharmacological characteristics from the NPP. The nature, origin and location of this pathway remain to be established.

Increased choline transport in erythrocytes from mice infected with the malaria parasite Plasmodium vinckei vinckei.

Parasitized erythrocytes from mice infected with the murine malaria parasite Plasmodium vinckei vinckei showed a marked increase in the rate of influx of choline compared with erythrocytes from uninfected mice. In contrast, uninfected erythrocytes from P. vinckei-infected animals transported choline at the same rate as those from uninfected mice. The increased influx of choline into parasitized cells was via two discrete routes. One was a saturable pathway with a Km similar to that of the choline carrier of normal erythrocytes but a Vmax approx. 20-fold higher than that observed in uninfected cells. The other was a non-saturable pathway inhibited by furosemide. At choline concentrations within the normal physiological plasma concentration range, the former pathway contributed approx. two-thirds and the latter approx. one-third of the influx of choline into parasitized cells. The characteristics of the furosemide-sensitive pathway were similar to those of a broad-specificity pathway that is induced in human erythrocytes infected in vitro with Plasmodium falciparum. The results of this study rule out the possibility that the induced transport pathway of P. falciparum-infected erythrocytes is an artifact arising in vitro from the long-term culture of parasitized cells and provide evidence that this pathway makes a significant contribution to the uptake of choline into the parasitized cells of malaria-infected animals.