Mark F. Wiser

Acidic phosphoproteins associated with the host erythrocyte membrane of erythrocytes infected with Plasmodium berghei and P. chabaudi

New phosphoproteins appear on the host erythrocyte membrane during Plasmodium berghei and P. chabaudi infection. Distinct proteins having similar properties and all distinguished by isoelectric points of less than 4.0 are identified. Associated with the erythrocyte membranes of P. berghei infected erythrocytes are two proteins with molecular masses of 65 and 46 kDa, whereas 93, 90 and 76 kDa proteins are observed during P. chabaudi infection. These new erythrocyte membrane associated proteins are all of parasite origin as indicated by metabolic labeling with proline and are synthesized during the ring stage of the asexual replicative cycle. Three of these proteins, the 93 kDa P. chabaudi protein and both P. berghei proteins, have been purified and the amino acid composition determined. All three are characterized by a relatively high proportion of aspartate and glutamate residues. Mono-and polyclonal antibodies were also raised against the same three purified proteins. No cross reactivity between these three proteins is observed, but one monoclonal antibody against the 65 kDa P. berghei crossreacts with a 27 kDa mouse erythrocyte protein. Immunofluorescence using the antibodies in combination with subcellular fractionation studies clearly shows that these phosphoproteins are associated with the host erythrocyte membrane and not the parasite.

Cytosolic protein kinase activity associated with the maturation of the malaria parasite Plasmodium berghei

Seven cytosolic phosphoproteins with relative molecular masses of 110, 58, 52, 46, 38, 36 and 34kDa and isoelectric points between 4.2 and 5.0 are identified from the rodent malaria parasite Plasmodium berghei. Similar patterns of phosphorylated proteins are obtained from parasite cytosol after incubation of intact infected erythrocytes with [32P]orthophosphate, or from parasite cytosol incubated with [gamma-32P]ATP. The characteristics of the phosphorylation reaction are similar to the previously described Plasmodium protein kinase [Wiser, M.F., Eaton, J.W. and Sheppard, J.R. (1983) J. Cell. Biochem. 21, 305-314], suggesting that the same protein kinase is involved. More protein phosphorylation activity is associated with the mature parasites than the immature forms, suggesting that these phosphoproteins may play some role in the parasites erythrocytic stage cycle.

Plasmodium berghei, P. chabaudi, and P. falciparum: Similarities in phosphoproteins and protein kinase activities and their stage specific expression

Phosphoproteins from Plasmodium berghei, P. chabaudi, and P. falciparum are compared. A major phosphoprotein of 46 kDa is found in all three species. Peptide mapping indicates that this protein is indeed the same in all three cases and is phosphorylated at similar sites in all three species. Monoclonal antibodies were raised against three other P. berghei phosphoproteins. All three monoclonal antibodies recognize both P. berghei and P. chabaudi proteins. Only one of the monoclonal antibodies crossreacts with a P. falciparum protein of 36 kDa, whereas the equivalent P. berghei and P. chabaudi proteins are 34 and 32 kDa, respectively. The highest rate of synthesis of the phosphoproteins is observed during the early trophozoite stage, whereas the highest rate of phosphorylation is observed during the late trophozoite stage.

Export of Plasmodium Proteins via a Novel Secretory Pathway

The intraerythrocytic location of the malaria parasite necessitates modification of the host cell. These alterations are mediated either directly or indirectly by parasite proteins exported to specific compartments within the host cell. However, little is known about how the parasite specifically targets proteins to locations beyond its plasma membrane. Mark Wiser, Norbert Lanners and Richard Bafford here propose an alternative secretory pathway for the export of parasite proteins into the host erythrocyte. The first step of this pathway is probably an endoplasmic reticulum (ER)-like organelle that is distinct from the normal ER. Possible mechanisms of protein trafficking in the infected erythrocyte are also discussed. The proposed ER-like organelle and alternative secretory pathway raise many questions about the cell biology of protein export and trafficking in Plasmodium.

Increased sensitivity in antigen detection during immunoblot analysis resulting from antigen enrichment via immunoprecipitation

The sensitivity in antigen detection during immunoblot analysis is greatly increased if the antigen is first immunoprecipitated from the crude extract before electrophoresis and transfer to nitrocellulose. Not only does the method allow detection of antigens which are minor components of crude mixtures or antigens which cannot be radiolabeled, but the method also resolves problems, such as high background, which are often associated with immunoprecipitation. Also, by modifying the method, whether or not monoclonal antibodies recognize the same or different antigens and/or epitopes can be easily determined.

Further characterization of a 58 kDa Plasmodium berghei phosphoprotein as a cochaperone

Molecular chaperones are important for proper protein folding during protein biogenesis. This report describes a protein from Plasmodium berghei which is 30% identical and 40% similar to a recently described mammalian cochaperone, or heat shock protein 70 interacting protein. The P. berghei cochaperone accumulates throughout the trophozoite stage and decreases during the schizont stage. The stage specific expression is consistent with its presumed role in protein folding or protein-protein interactions. The largest difference between the Plasmodium and mammalian sequences is a more extensive domain of imperfect glycine-glycine-methionine-proline (GGMP) tandem repeats in the parasites cochaperone sequence. Immunofluorescence studies show that the protein is an abundant cytosolic protein of the parasite. However, antibodies raised against the GGMP repeat domain, which is also found in other parasite chaperones, react with both the parasite and host erythrocyte membrane. The reactivity with the host membrane suggests that the parasite exports molecular chaperones into the infected erythrocyte.

The complete sequence of Plasmodium berghei merozoite surface protein-1 and its inter- and intra-species variability

The complete gene for merozoite surface protein-1 (MSP-1) from Plasmodium berghei has been cloned and sequenced. Comparison of the P. berghei MSP-1 sequence with MSP-1 from other rodent parasites reveals five conserved domains interrupted by four variable blocks. These variable blocks exhibit no sequence homology but do have similar amino acid compositions. Primary proteolytic processing sites are located near the boundaries between the conserved domains and the variable blocks. Sequencing of the variable blocks from several P. berghei isolates shows that the predominant intra-species difference is in the number of tandem repeats. The inter- and intra-species differences suggest that the variable blocks are localized areas with relatively high levels of slipped-strand mispairing, unequal crossing-over, or other intragenic recombination activity. MSP-1 from P. berghei exhibits more repetitiveness than MSP-1 from other species suggesting that P. berghei experiences a higher intrinsic level of events producing variable numbers of tandem repeats or a lower level of events leading to the degeneration of tandem repeats.

PLASMODIAL SERINE REPEAT ANTIGEN HOMOLOGUES WITH PROPERTIES OF SCHIZONT CYSTEINE PROTEASES

Proteases appear to be required for critical events in the erythrocytic life cycle of malaria parasites, including the rupture of erythrocytes by mature schizonts and the subsequent invasion of erythrocytes by daughter merozoites [1,2]. This conclusion is supported by studies showing that parasite rupture and invasion of erythrocytes are inhibited by serine and cysteine protease inhibitors [1] and that the proteolytic processing of late schizont-stage proteins is required for the completion of the erythrocytic cycle [3,4]. A number of schizont protease activities have been identified biochemically [2], but limitations on available quantities of protein have made it difficult to definitively characterize these proteases or to ascertain their specific biological roles. The Plasmodium falciparum serine repeat antigen (known as SERA, SERA-1, SERP or P126 [5–7]) is being studied as a potential vaccine component [8]. A number of SERA homologues have been described, namely serine repeat protein homologue (SERPH [9] or SERA-2 [10]) and SERA-3 [10] from P. falciparum and five homologues from Plasmodium 6i6ax [11]. SERA and SERPH have been localized to the parasitophorous vacuole of mature schizonts [9,12], and SERA fragments are released into the bloodstream near the time of erythrocyte rupture [12]. SERA and its homologues all contain a 30 kDa ‘protease domain’ that has similarity in sequence to papain-family cysteine proteases, particularly near highly conserved active site residues [13] (Fig. 1A). Taken together, available data suggest that SERA and SERPH may act as late schizontAbbre6iations: SERA, serine repeat antigen; SERPH, serine repeat antigen homologue. * Corresponding author. Tel.: +1 415 2068845; fax: +1 415 2066015; e-mail: rosnthl@itsa.ucsf.edu 1 Note: Nucleotide sequence data reported in this paper are available in the GenBankTM data base under accession numbers U59860, U59861, U59862 and AF052747.

Characterization of proteins localized to a subcellular compartment associated with an alternate secretory pathway of the malaria parasite.

Monoclonal antibodies recognizing proteins localized to a unique subcellular compartment within the malaria parasite are described in this report. These monoclonal antibodies recognize Plasmodium falciparum proteins of 68, 45 and 22 kDa proteins which are also conserved in rodent Plasmodium species. Co-localization studies indicate that these proteins are located in a brefeldin A-induced compartment which was previously proposed to be an early step in the export of proteins from the parasite into the infected erythrocyte. COPII coat proteins, Sar1p and Sec31p, and the endoplasmic reticulum-associated chaperone, BiP, all partially co-localize with the 68 and 22 kDa proteins, thus suggesting that this subcellular compartment has some similarities to the endoplasmic reticulum or that this compartment represents a domain of the endoplasmic reticulum. The 68 and 22 kDa proteins are highly soluble in non-ionic detergent and are likely to be located within the lumen of a membrane-bound compartment. These proteins found within this subcellular compartment are present throughout the blood stage from very early rings to segmenters. The results of this study further substantiate the existence of an alternate secretory pathway in the malaria parasite which plays a role in the export of proteins into the host erythrocyte.

Molecular characterization of a Plasmodium chabaudi erythrocyte membrane-associated protein with glutamate-rich tandem repeats.

The malarial parasite dramatically affects the structure and function of the erythrocyte membrane by exporting proteins that specifically interact with the host membrane. This report describes the complete sequence and some biochemical properties of a 93‐kDa Plasmodium chabaudi chabaudi protein that interacts with the host erythrocyte membrane. Approximately 40% of the deduced protein sequence consists of tandem repeats of 14 amino acids that are rich in glutamic acid residues. Comparison of the repeat sequences from two different P. c. chabaudi strains derived from the same initial isolate revealed an exact duplication of 294 nucleotides suggesting a recent gel electrophoresis and gel filtration chromatography suggest that the protein is a long rod‐shaped or fibrillar. protein. Attributes shared between the 93‐kDa protein, some P. falciparum proteins with glutamate‐rich tandem repeats, and cytoskeletal proteins suggest that these parasite proteins function as cytoskeletal proteins that possibly stabilize the erythrocyte membrane.