Structural basis of LAIR1 targeting by polymorphic Plasmodium RIFINs.

RIFIN, a large family of Plasmodium variant surface antigens, plays a crucial role in malaria pathogenesis by mediating immune suppression through activation of inhibitory receptors such as LAIR1, and antibodies with LAIR1 inserts have been identified that bind infected erythrocytes through RIFIN. However, details of RIFIN-mediated LAIR1 recognition and receptor activation have been unclear. Here, we use negative-stain EM to define the architecture of LAIR1-inserted antibodies and determine crystal structures of RIFIN-variable 2 (V2) domain in complex with a LAIR1 domain. These structures reveal the LAIR1-binding region of RIFIN to be hydrophobic and membrane-distal, to exhibit extensive structural diversity, and to interact with RIFIN-V2 in a one-to-one fashion. Through structural and sequence analysis of various LAIR1 constructs, we identify essential elements of RIFIN-binding on LAIR1. Furthermore, a structure-derived LAIR1-binding sequence signature ascertained >20 LAIR1-binding RIFINs, including some from P. falciparum field strains and Plasmodium species infecting gorillas and chimpanzees.

Structural basis of malaria RIFIN binding by LILRB1-containing antibodies.

Some Plasmodium falciparum repetitive interspersed families of polypeptides (RIFINs)-variant surface antigens that are expressed on infected erythrocytes1-bind to the inhibitory receptor LAIR1, and insertion of DNA that encodes LAIR1 into immunoglobulin genes generates RIFIN-specific antibodies2,3. Here we address the general relevance of this finding by searching for antibodies that incorporate LILRB1, another inhibitory receptor that binds to ß2 microglobulin and RIFINs through their apical domains4,5. By screening plasma from a cohort of donors from Mali, we identified individuals with LILRB1-containing antibodies. B cell clones isolated from three donors showed large DNA insertions in the switch region that encodes non-apical LILRB1 extracellular domain 3 and 4 (D3D4) or D3 alone in the variable-constant (VH-CH1) elbow. Through mass spectrometry and binding assays, we identified a large set of RIFINs that bind to LILRB1 D3. Crystal and cryo-electron microscopy structures of a RIFIN in complex with either LILRB1 D3D4 or a D3D4-containing antibody Fab revealed a mode of RIFIN-LILRB1 D3 interaction that is similar to that of RIFIN-LAIR1. The Fab showed an unconventional triangular architecture with the inserted LILRB1 domains opening up the VH-CH1 elbow without affecting VH-VL or CH1-CL pairing. Collectively, these findings show that RIFINs bind to LILRB1 through D3 and illustrate, with a naturally selected example, the general principle of creating novel antibodies by inserting receptor domains into the VH-CH1 elbow.

Structure of the Plasmodium-interspersed repeat proteins of the malaria parasite.

The deadly symptoms of malaria occur as Plasmodium parasites replicate within blood cells. Members of several variant surface protein families are expressed on infected blood cell surfaces. Of these, the largest and most ubiquitous are the Plasmodium-interspersed repeat (PIR) proteins, with more than 1,000 variants in some genomes. Their functions are mysterious, but differential pir gene expression associates with acute or chronic infection in a mouse malaria model. The membership of the PIR superfamily, and whether the family includes Plasmodium falciparum variant surface proteins, such as RIFINs and STEVORs, is controversial. Here we reveal the structure of the extracellular domain of a PIR from Plasmodium chabaudi We use structure-guided sequence analysis and molecular modeling to show that this fold is found across PIR proteins from mouse- and human-infective malaria parasites. Moreover, we show that RIFINs and STEVORs are not PIRs. This study provides a structure-guided definition of the PIRs and a molecular framework to understand their evolution.

Structure of Plasmodium falciparum Rh5-CyRPA-Ripr invasion complex.

Plasmodium falciparum causes the severe form of malaria that has high levels of mortality in humans. Blood-stage merozoites of P. falciparum invade erythrocytes, and this requires interactions between multiple ligands from the parasite and receptors in hosts. These interactions include the binding of the Rh5-CyRPA-Ripr complex with the erythrocyte receptor basigin1,2, which is an essential step for entry into human erythrocytes. Here we show that the Rh5-CyRPA-Ripr complex binds the erythrocyte cell line JK-1 significantly better than does Rh5 alone, and that this binding occurs through the insertion of Rh5 and Ripr into host membranes as a complex with high molecular weight. We report a cryo-electron microscopy structure of the Rh5-CyRPA-Ripr complex at subnanometre resolution, which reveals the organization of this essential invasion complex and the mode of interactions between members of the complex, and shows that CyRPA is a critical mediator of complex assembly. Our structure identifies blades 4-6 of the ß-propeller of CyRPA as contact sites for Rh5 and Ripr. The limited contacts between Rh5-CyRPA and CyRPA-Ripr are consistent with the dissociation of Rh5 and Ripr from CyRPA for membrane insertion. A comparision of the crystal structure of Rh5-basigin with the cryo-electron microscopy structure of Rh5-CyRPA-Ripr suggests that Rh5 and Ripr are positioned parallel to the erythrocyte membrane before membrane insertion. This provides information on the function of this complex, and thereby provides insights into invasion by P. falciparum.

EGCG disaggregates amyloid-like fibrils formed by Plasmodium falciparum merozoite surface protein 2.

Merozoite surface protein 2 (MSP2), one of the most abundant proteins on the surface of Plasmodium falciparum merozoites, is a promising malaria vaccine candidate. MSP2 is intrinsically unstructured and forms amyloid-like fibrils in solution. As this propensity of MSP2 to form fibrils in solution has the potential to impede its development as a vaccine candidate, finding an inhibitor that inhibits fibrillogenesis may enhance vaccine development. We have shown previously that EGCG inhibits the formation of MSP2 fibrils. Here we show that EGCG can alter the ß-sheet-like structure of the fibril and disaggregate pre-formed fibrils of MSP2 into soluble oligomers. The fibril remodelling effects of EGCG and other flavonoids were characterised using Thioflavin T fluorescence assays, electron microscopy and other biophysical methods.

Changes in Paramecium caudatum (protozoa) near a switched-on GSM telephone.

The protozoan Paramecium caudatum was examined under normal conditions versus aside a switched-on GSM telephone (900 MHz; 2 Watts). Exposed individuals moved more slowly and more sinuously than usual. Their physiology was affected: they became broader, their cytopharynx appeared broader, their pulse vesicles had difficult in expelling their content outside the cell, their cilia less efficiently moved, and trichocysts became more visible. All these effects might result from some bad functioning or damage of the cellular membrane. The first target of communication electromagnetic waves might thus be the cellular membrane.

The Plasmodium falciparum knob-associated PfEMP3 antigen is also expressed at pre-erythrocytic stages and induces antibodies which inhibit sporozoite invasion.

The expression of the pfemp3 gene and the corresponding PfEMP3 knob-associated protein in the pre-erythrocytic stages of Plasmodium falciparum was demonstrated by RT-PCR, Western blots, IFAT and IEM. The antigen was found on the surface of the sporozoite and in the cytoplasm of mature hepatic stage parasites. Immunological cross-reactivity was observed with sporozoites from the rodent malaria parasites Plasmodium yoelii yoelii and Plasmodium berghei and was exploited to assess a potential role of this protein at the pre-erythrocytic stages. Specific antibodies from immune individuals were found to inhibit P. yoelii yoelii and P. berghei sporozoite invasion of primary hepatocyte cultures. PfEMP3 should now be added to the small list of proteins expressed at the pre-erythrocytic stages of P. falciparum, and its vaccine potential now deserves to be investigated.

Molecular characterization of TgMIC5, a proteolytically processed antigen secreted from the micronemes of Toxoplasma gondii.

During invasion of host cells, Toxoplasma gondii discharges the contents of small, apically located secretory organelles called micronemes. Micronemal proteins are known to be necessary for both parasite motility and invasion of host cells. To further define the contents of Toxoplasma micronemes, we used cell fractionation and secretion-modulating drugs to identify six novel, putative micronemal proteins. In this paper we describe preliminary characterization of one of these novel proteins, TgMIC5. Molecular cloning and DNA sequence analysis of the TgMIC5 cDNA and gene revealed that it encodes a previously identified immunodominant antigen called H4. TgMIC5 also possesses a consensus sequence unique to members of the parvulin family of peptidyl-prolyl cis-trans isomerases (PPIases). TgMIC5 is expressed as a preproprotein, which is proteolytically processed to a proprotein by signal peptidase before being further processed to a mature protein of 22 kDa. Using a combination of protein secretion experiments, immunofluorescence and immunoelectron microscopy, we demonstrated that TgMIC2 is stored in the micronemes of T. gondii tachyzoites before it is secreted into the surrounding medium. Based on its homology with parvulin-like PPIases, TgMIC5 may assist in the folding of other micronemal proteins that function in invasion of host cells by T. gondii tachyzoites.

Protection against invasive amebiasis by a single monoclonal antibody directed against a lipophosphoglycan antigen localized on the surface of Entamoeba histolytica.

A panel of monoclonal antibodies was raised from mice immunized with a membrane preparation from Entamoeba histolytica, the pathogenic species causing invasive amebiasis in humans. Antibody EH5 gave a polydisperse band in immunoblots from membrane preparations from different E. histolytica strains, and a much weaker signal from two strains of the nonpathogenic species Entamoeba dispar. Although the exact chemical structure of the EH5 antigen is not yet known, the ability of the antigen to be metabolically radiolabeled with [32P]phosphate or [3H]glucose, its sensitivity to digestion by mild acid and phosphatidylinositol-specific phospholipase C, and its specific extraction from E. histolytica trophozoites by a method used to prepare lipophosphoglycans from Leishmania showed that it could be classified as an amebal lipophosphoglycan. Confocal immunofluorescence and immunogold labeling of trophozoites localized the antigen on the outer face of the plasma membrane and on the inner face of internal vesicle membranes. Antibody EH5 strongly agglutinated amebas in a similar way to concanavalin A (Con A), and Con A bound to immunoaffinity-purified EH5 antigen. Therefore, surface lipophosphoglycans may play an important role in the preferential agglutination of pathogenic amebas by Con A. The protective ability of antibody EH5 was tested in a passive immunization experiment in a severe combined immunodeficient (SCID) mouse model. Intrahepatic challenge of animals after administration of an isotype-matched control antibody or without treatment led to the development of a liver abscess in all cases, whereas 11 out of 12 animals immunized with the EH5 antibody developed no liver abscess. Our results demonstrate the importance and, for the first time, the protective capacity of glycan antigens on the surface of the amebas.

Giardia lamblia: absence of cyst antigens and reduced secretory vesicle formation and bile salt uptake in an encystation-deficient subline.

Encystation of Giardia lamblia entails the appearance of a number of new antigens, as well as formation of a novel class of large encystation-specific secretory vesicles (ESV) that transport stage-specific proteins to the nascent cyst wall. The monoclonal antibody GCSA-1, which was raised against purified cyst walls, recognizes protein species of approximately 26-46 kDa that are regulated by exposure to bile (plus lactic acid) and alkaline pH, the factors that induce encystation. The GCSA-1 epitope is maximally expressed after approximately 14 hr of encystation and localizes to the interior, but not the membrane of the ESV as shown by frozen section immunoelectron microscopy. To further understand the process of encystation, we compared two sublines of strain WB that differ in their ability to encyst in vitro. Water-resistant cysts were not detected in subline A6 under conditions in which subline C6 formed approximately 2 x 10(5) cysts/ml. Moreover, subline A6 did not form ESV efficiently or detectably express antigens recognized by mAb GCSA-1 or by polyclonal anti-cyst sera. Finally, uptake of the bile salt taurocholate by A6 was reduced 4- to 20-fold, compared with that of C6, although transport by both strains was sodium-dependent and regulated by bile salt starvation. The decrease in bile salt uptake by A6 may be related to its defect in encystation.

Ultrastructural and antigenic preservation of a delicate structure by cryopreparation: identification and immunogold localization during biogenesis of a secretory component (membrane-matrix connection) in Paramecium trichocysts.

Ultrastructure and antigenicity of the "mesh-like sheath" (MLS), a very delicate structure connecting the membrane and the paracrystalline matrix of Paramecium trichocysts, are well preserved after cryofixation (rapid freezing followed by freeze-substitution in methanol and embedding in Lowicryl K11M at 213K). The MLS is labeled by colloidal gold-bound antibodies (Ab-Au10nm) with primary antibody (Ab) against trichocyst components obtained by recloning hybridoma cells twice. We prepared Western blots from reduced gels obtained from subfractionated trichocysts. Trichocyst membranes displayed reactive bands of 68-70, 63-66, 43, 40 (strongest), and 57 and 54 KD, with a weak band of 38 KD. One of the most abundant protein bands of soluble secretory components (56-57 KD) was also strongly stained on blots. On ultra-thin sections pre-trichocysts display Ab-reactive material concentrated below the trichocyst membrane before the MLS can be recognized as a structural entity. Quantitative evaluation of Ab-Au10-labeled ultrathin sections also revealed passage of MLS materials through the very inconspicuous Golgi apparatus. This was substantiated by Ab-peroxidase labeling. We conclude that MLS components (whose ultrastructure is difficult to preserve) are largely membrane-associated, partly soluble proteins. They form a connection (released during exocytosis) between the abundant paracrystalline matrix components and the organelle membrane. MLS might thus maintain a peripheral aqueous space of functional importance.

[Ultrastructural localization of 185 kDa and 82/41 kDa protective antigens in Plasmodium falciparum, FCC1/HN].

Plasmodium falciparum FCC1/HN-infected human erythrocytes were embedded with LR White resin at low temperature. The 185 kDa and 82/41 kDa proteins in erythrocytic stages of P. falciparum were then immunolabeled by using the protective monoclonal antibodies (McAb)F6-D3 and F6-C2 with protein A-colloidal gold probe. The electron-microscopical observation showed that the 185kDa protein recognized by McAb F6-D3 was located on the surface of free and intracellular merozoites as well as the cytoplasm, plasma membrane, and parasitophorous vacuole membrane of immature schizonts. The 82/41 kDa proteins identified by McAb F6-C2 was located within the rhoptries of immature schizonts and mature merozoites. These results demonstrated ultrastructurally that the 185 kDa and 82/41 kDa protective antigens were merozoite surface antigen and merozoite rhoptry antigens of P. falciparum FCC1/HN, respectively.

Electron microscopic analysis of circumsporozoite protein trail formation by gliding malaria sporozoites.

Immunoelectron microscopic techniques were utilized to characterize the morphology of circumsporozoite protein-containing trails deposited on various substrates by gliding Plasmodium berghei and Plasmodium falciparum sporozoites. The basic components of the trails are beadlike particles, 25 to 90 nm in diameter, which are devoid of unit membrane and have an electron-lucent center. Trails were captured on formvar-covered grids coated with anticircumsporozoite protein monoclonal antibodies and compared with trails produced on uncoated formvar; the results suggest that material containing circumsporozoite protein forms the matrix within which the particles are embedded. The trails exhibit morphological features similar to those displayed by circumsporozoite precipitation reactions; of note is the demonstration of sheaths of circumsporozoite protein-containing material that emanate from sporozoites prior to their gliding. The sheaths narrow into accumulations of electron-dense material, which eventually taper to form typical trails. The structural manifestation of sheaths and other morphological details of the formed trails enables us to correlate sporozoite behavior during trail formation with the motile actions of gliding sporozoites observed by light microscopy.

[Localization of the antigen in erythrocytic stages of Plasmodium yoelii by immuno-electron microscopy].

In this study, the antigen recognized by the protective McAb M26-32 in erythrocytic stages of P. yoelii was localized by immuno-electron microscopy with LR Whithe resin embedding and colloidal gold probe cytochemical techniques. The results indicated that the antigen which reacts specifically to McAb M26-32 was mainly localized within the cytoplasm of early and late trophozoites, schizonts and merozoites, being the common antigen of asexual blood stages of the plasmodium. The amount of the antigen was on the increase during the development of trophozoite, while a portion of the antigen might be transported outward by exocytosis of the parasites and then be localized in the cytoplasm of the infected erythrocytes adjacent to the parasites.