Trafficking of STEVOR to the Maurer's clefts in Plasmodium falciparum-infected erythrocytes

The human malarial parasite Plasmodium falciparum exports proteins to destinations within its host erythrocyte, including cytosol, surface and membranous profiles of parasite origin termed Maurer's clefts. Although several of these exported proteins are determinants of pathology and virulence, the mechanisms and trafficking signals underpinning protein export are largely uncharacterized-particularly for exported transmembrane proteins. Here, we have investigated the signals mediating trafficking of STEVOR, a family of transmembrane proteins located at the Maurer's clefts and believed to play a role in antigenic variation. Our data show that, apart from a signal sequence, a minimum of two addition signals are required. This includes a host cell targeting signal for export to the host erythrocyte and a transmembrane domain for final sorting to Maurer's clefts. Biochemical studies indicate that STEVOR traverses the secretory pathway as an integral membrane protein. Our data suggest general principles for transport of transmembrane proteins to the Maurer's clefts and provide new insights into protein sorting and trafficking processes in P. falciparum.     

Protein phosphatase 1, a Plasmodium falciparum essential enzyme, is exported to the host cell and implicated in the release of infectious merozoites

The malarial parasite Plasmodium falciparum transposes a Golgi-like compartment, referred to as Maurer's clefts, into the cytoplasm of its host cell, the erythrocyte, and delivering parasite molecules to the host cell surface. We report here a novel role of the Maurer's clefts implicating a parasite protein phosphatase 1 (PP1) and related to the phosphorylation status of P. falciparum skeleton-binding protein 1 (PfSBP1), a trans-membrane protein of the clefts interacting with the host cell membrane via its carboxy-terminal domain. Based on co-immunoprecipitation and inhibition studies, we show that the parasite PP1 type phosphatase modulates the phosphorylation status of the amino-terminal domain of PfSBP1 in the lumen of Maurer's clefts. Importantly, the addition of a PP1 inhibitor, calyculin A, to late schizonts results in the hyperphosphorylation of PfSBP1 and prevents parasite release from the host cell. We propose that the hyperphosphorylation of PfSBP1 interferes with the release of merozoites, the invasive blood stage of the parasite, by increasing the red cell membrane stability. Moreover, the parasite PP1 phosphatase is the first enzyme essential for the parasite development detected in the Maurer's clefts.     

Maurer's cleft organization in the cytoplasm of plasmodium falciparum-infected erythrocytes: new insights from three-dimensional reconstruction of serial ultrathin sections

Maurer's clefts are single-membrane-limited structures in the cytoplasm of erythrocytes infected with the human malarial parasite Plasmodium falciparum. The currently accepted model suggests that Maurer's clefts act as an intermediate compartment in protein transport processes from the parasite across the cytoplasm of the host cell to the erythrocyte surface, by receiving and delivering protein cargo packed in vesicles. This model is mainly based on two observations. Firstly, single-section electron micrographs have shown, within the cytoplasm of infected erythrocytes, stacks of long slender membranes in close vicinity to round membrane profiles considered to be vesicles. Secondly, proteins that are transported from the parasite to the erythrocyte surface as well as proteins facilitating the budding of vesicles have been found in association with Maurer's clefts. Verification of this model would be greatly assisted by a better understanding of the morphology, dimensions and origin of the Maurer's clefts. Here, we have generated and analyzed three-dimensional reconstructions of serial ultrathin sections covering segments of P. falciparum-infected erythrocytes of more than 1 microm thickness. Our results indicate that Maurer's clefts are heterogeneous in structure and size. We have found Maurer's clefts consisting of a single disk-shaped cisternae localized beneath the plasma membrane. In other examples, Maurer' clefts formed an extended membranous network that bridged most of the distance between the parasite and the plasma membrane of the host erythrocyte. Maurer's cleft membrane networks were composed of both branched membrane tubules and stacked disk-shaped membrane cisternae that eventually formed whorls. Maurer's clefts were visible in other cells as a loose membrane reticulum composed of scattered tubular and disk-shaped membrane profiles. We have not seen clearly discernable isolated vesicles in the analyzed erythrocyte segments suggesting that the current view of how proteins are transported within the Plasmodium-infected erythrocyte may need reconsideration.     

Electron tomography of the Maurer's cleft organelles of Plasmodium falciparum-infected erythrocytes reveals novel structural features

During intraerythrocytic development, the human malaria parasite, Plasmodium falciparum, establishes membrane-bound compartments, known as Maurer's clefts, outside the confines of its own plasma membrane. The Maurer's compartments are thought to be a crucial component of the machinery for protein sorting and trafficking; however, their ultrastructure is only partly defined. We have used electron tomography to image Maurer's clefts of 3D7 strain parasites. The compartments are revealed as flattened structures with a translucent lumen and a more electron-dense coat. They display a complex and convoluted morphology, and some regions are modified with surface nodules, each with a circular cross-section of approximately 25 nm. Individual 25 nm vesicle-like structures are also seen in the erythrocyte cytoplasm and associated with the red blood cell membrane. The Maurer's clefts are connected to the red blood cell membrane by regions with extended stalk-like profiles. Immunogold labelling with specific antibodies confirms differential labelling of the Maurer's clefts and the parasitophorous vacuole and erythrocyte membranes. Spot fluorescence photobleaching was used to demonstrate the absence of a lipid continuum between the Maurer's clefts and parasite membranes and the host plasma membrane.     

Genesis of and trafficking to the Maurer's clefts of Plasmodium falciparum-infected erythrocytes

Malaria parasites export proteins beyond their own plasma membrane to locations in the red blood cells in which they reside. Maurer's clefts are parasite-derived structures within the host cell cytoplasm that are thought to function as a sorting compartment between the parasite and the erythrocyte membrane. However, the genesis of this compartment and the signals directing proteins to the Maurer's clefts are not known. We have generated Plasmodium falciparum-infected erythrocytes expressing green fluorescent protein (GFP) chimeras of a Maurer's cleft resident protein, the membrane-associated histidine-rich protein 1 (MAHRP1). Chimeras of full-length MAHRP1 or fragments containing part of the N-terminal domain and the transmembrane domain are successfully delivered to Maurer's clefts. Other fragments remain trapped within the parasite. Fluorescence photobleaching and time-lapse imaging techniques indicate that MAHRP1-GFP is initially trafficked to isolated subdomains in the parasitophorous vacuole membrane that appear to represent nascent Maurer's clefts. The data suggest that the Maurer's clefts bud from the parasitophorous vacuole membrane and diffuse within the erythrocyte cytoplasm before taking up residence at the cell periphery.     

The Plasmodium falciparum Maurer's clefts in 3D

In 1902, the German physician Georg Maurer discovered a dotted staining pattern within the cytoplasm of Plasmodium falciparum infected erythrocytes that, according to the tradition at the time, was named in his honour. The significance of Georg Maurer's discovery remained unrecognized for almost a century. Only recently are Maurer's clefts appreciated as a novel type of secretory organelle. Established by the malaria parasite within its host cell, Maurer's clefts play an essential role in directing proteins from the parasite to the erythrocyte surface. In this issue of Molecular Microbiology, Hanssen et al. report on the three dimensional structure of Maurer's clefts, as determined by electron tomography. The data presented suggest that Maurer's clefts are connected to both the parasitophorous vacuolar and the erythrocyte plasma membrane, however, no continuum exists that would allow lipids or proteins to freely flow between these three compartments. This seminal work, which stands in the tradition of Georg Maurer's original discovery, represents a milestone in our understanding of the structure and function of this fascinating organelle.     

A conditional export system provides new insights into protein export in Plasmodium falciparum-infected erythrocytes

The human malarial parasite Plasmodium falciparum exports determinants of virulence and pathology to destinations within its host erythrocyte, including the cytoplasm, the plasma membrane and membrane profiles of parasite origin termed Maurer's clefts. While there is some information regarding the signals that allot proteins for export, the trafficking route itself has remained largely obscure, partly due to technical limitations in following protein trafficking with time. To overcome these shortcomings, we have established a conditional protein export system in P. falciparum, based on the previously described conditional aggregation domain (CAD domain) that self-aggregates in the endoplasmic reticulum in a manner that is reversible by the addition of a small molecule. By fusing the CAD domain to the first 80 amino acids of STEVOR and full-length PfSBP1, we were able to control export of a soluble and a transmembrane protein to the erythrocyte cytosol and the Maurer's clefts respectively. The conditional export system allowed us to study the temporal sequence of events of protein export and identify intermediate steps. We further explored the potential of the conditional export system in identifying factors that interact with exported proteins en route. Our data provide evidence for a physical interaction of exported proteins with the molecular chaperone PfBiP during early export steps.     

Deciphering the export pathway of malaria surface proteins

The intra-erythrocytic stages of Plasmodium falciparum assemble a unique protein trafficking system that targets parasite proteins to the red cell cytoplasm and cell surface. It is through this trafficking pathway that the primary virulence determinants of P. falciparum infections are targeted to the erythrocyte surface to mediate adhesion to host endothelial cells. A recent study has shown that SBP-1, a parasite protein associated with Maurer's clefts in the infected red cell cytosol, is essential for transport of the virulence factor PfEMP-1. This discovery sheds new light on the little-understood mechanisms that regulate protein trafficking in infected cells.     

The Maurer's cleft protein MAHRP1 is essential for trafficking of PfEMP1 to the surface of Plasmodium falciparum-infected erythrocytes

During the intra-erythrocytic development of Plasmodium falciparum, the parasite modifies the host cell surface by exporting proteins that interact with or insert into the erythrocyte membrane. These proteins include the principal mediator of cytoadherence, P. falciparum erythrocyte membrane protein 1 (PfEMP1). To implement these changes, the parasite establishes a protein-trafficking system beyond its confines. Membrane-bound structures called Maurer's clefts are intermediate trafficking compartments for proteins destined for the host cell membrane. We disrupted the gene for the membrane-associated histidine-rich protein 1 (MAHRP1). MAHRP1 is not essential for parasite viability or Maurer's cleft formation; however, in its absence, these organelles become disorganized in permeabilized cells. Maurer's cleft-resident proteins and transit cargo are exported normally in the absence of MAHRP1; however, the virulence determinant, PfEMP1, accumulates within the parasite, is depleted from the Maurer's clefts and is not presented at the red blood cell surface. Complementation of the mutant parasites with mahrp1 led to the reappearance of PfEMP1 on the infected red blood cell surface, and binding studies show that PfEMP1-mediated binding to CD36 is restored. These data suggest an important role of MAHRP1 in the translocation of PfEMP1 from the parasite to the host cell membrane.     

Localization of a parasite encoded protein to erythrocyte cytoplasmic vesicles of Plasmodium falciparum-infected cells

Intracellular development of the malarial parasite results in substantial modifications of the membrane and cytoskeleton of the erythrocyte host cell. Two related Plasmodium falciparum-encoded proteins of 50 kDa and 43 kDa (Pf 50/43), identified by reactivity with a single mAb, were demonstrated to be localized to the erythrocyte cytoplasm of parasite-infected cells. Immunofluorescence and immunoelectron microscopy using mAb.7E11 demonstrated the Pf 50/43 is localized in the membrane of the vesicles in the erythrocyte cytoplasm, vesicles which correspond to Maurer's clefts. Solubility properties of the proteins suggest they are integral membrane proteins. By immunofluorescence, Pf 50/43 is shown to colocalize with actin which has a highly modified organization in the infected erythrocyte. Pf 50/43 is located exclusively in the vesicles, is not transported to the erythrocyte membrane or secreted. It is proposed the vesicles may play a role in transport of molecules across the erythrocyte cytoplasm, between the parasite and the external erythrocyte plasma membrane.     

Trafficking and assembly of the cytoadherence complex in Plasmodium falciparum-infected human erythrocytes

After invading human erythrocytes, the malarial parasite Plasmodium falciparum, initiates a remarkable process of secreting proteins into the surrounding erythrocyte cytoplasm and plasma membrane. One of these exported proteins, the knob-associated histidine-rich protein (KAHRP), is essential for microvascular sequestration, a strategy whereby infected red cells adhere via knob structures to capillary walls and thus avoid being eliminated by the spleen. This cytoadherence is an important factor in many of the deaths caused by malaria. Green fluorescent protein fusions and fluorescence recovery after photobleaching were used to follow the pathway of KAHRP deployment from the parasite endomembrane system into an intermediate depot between parasite and host, then onwards to the erythrocyte cytoplasm and eventually into knobs. Sequence elements essential to individual steps in the pathway are defined and we show that parasite-derived structures, known as Maurer's clefts, are an elaboration of the canonical secretory pathway that is transposed outside the parasite into the host cell, the first example of its kind in eukaryotic biology.     

The twists and turns of Maurer's cleft trafficking in P. falciparum-infected erythrocytes

The malaria parasite, Plasmodium falciparum, invades the red blood cells (RBCs) of its human host and initiates a series of morphological rearrangements within the host cell cytoplasm. The mature RBC has no endogenous trafficking machinery; therefore, the parasite generates novel structures to mediate protein transport. These include compartments called the Maurer's clefts (MC), which play an important role in the trafficking of parasite proteins to the surface of the host cell. Recent electron tomography studies have revealed MC as convoluted flotillas of flattened discs that are tethered to the RBC membrane, prompting speculation that the MC could, in one respect, represent an extracellular equivalent of the Golgi apparatus. Visualization of both resident and cargo proteins has helped decipher the signals and routes for trafficking of parasite proteins to the MC and beyond.     

Genetic ablation of a Maurer's cleft protein prevents assembly of the Plasmodium falciparum virulence complex

The malaria parasite Plasmodium falciparum assembles knob structures underneath the erythrocyte membrane that help present the major virulence protein, P. falciparum erythrocyte membrane protein-1 (PfEMP1). Membranous structures called Maurer's clefts are established in the erythrocyte cytoplasm and function as sorting compartments for proteins en route to the RBC membrane, including the knob-associated histidine-rich protein (KAHRP), and PfEMP1. We have generated mutants in which the Maurer's cleft protein, the ring exported protein-1 (REX1) is truncated or deleted. Removal of the C-terminal domain of REX1 compromises Maurer's cleft architecture and PfEMP1-mediated cytoadherance but permits some trafficking of PfEMP1 to the erythrocyte surface. Deletion of the coiled-coil region of REX1 ablates PfEMP1 surface display, trapping PfEMP1 at the Maurer's clefts. Complementation of mutants with REX1 partly restores PfEMP1-mediated binding to the endothelial cell ligand, CD36. Deletion of the coiled-coil region or complete deletion of REX1 is tightly associated with the loss of a subtelomeric region of chromosome 2, encoding KAHRP and other proteins. A KAHRP-green fluorescent protein (GFP) fusion expressed in the REX1-deletion parasites shows defective trafficking. Thus, loss of functional REX1 directly or indirectly ablates the assembly of the P. falciparum virulence complex at the surface of host erythrocytes.     

Characterization of the pathway for transport of the cytoadherence-mediating protein, PfEMP1, to the host cell surface in malaria parasite-infected erythrocytes

The Plasmodium falciparum erythrocyte membrane protein 1 (PfEMP1) family of antigenically diverse proteins is expressed on the surface of human erythrocytes infected with the malaria parasite P. falciparum, and mediates cytoadherence to the host vascular endothelium. In this report, we show that export of PfEMP1 is slow and inefficient as it takes several hours to traffic newly synthesized proteins to the erythrocyte membrane. Upon removal by trypsin treatment, the surface-exposed population of PfEMP1 is not replenished during subsequent culture indicating that there is no cycling of PfEMP1 between the erythrocyte surface and an intracellular compartment. The role of Maurer's clefts as an intermediate sorting compartment in trafficking of PfEMP1 was investigated using immunoelectron microscopy and proteolytic digestion of streptolysin O-permeabilized parasitized erythrocytes. We show that PfEMP1 is inserted into the Maurer's cleft membrane with the C-terminal domain exposed to the erythrocyte cytoplasm, whereas the N-terminal domain is buried inside the cleft. Transfer of PfEMP1 to the erythrocyte surface appears to involve electron-lucent extensions of the Maurer's clefts. Thus, we have delineated some important aspects of the unusual trafficking mechanism for delivery of this critical parasite virulence factor to the erythrocyte surface.     

The Maurer's clefts of Plasmodium falciparum: parasite-induced islands within an intracellular ocean

It is suggested that Maurer's clefts, membranous structures observed within the cytoplasm of Plasmodium-falciparum-infected human erythrocytes, play an important role in trafficking virulence proteins from the parasite to the surface of the host cell. How they fulfil this role, however, still is unclear. A recent study by Bhattacharjee et al. now suggests that the clefts function as the major conduit through which parasite-encoded proteins pass before entering the host cell. In this article we comment on the significance of this information in our understanding of the novel 'extracellular' secretory pathway of this important human pathogen.     

New Export Pathway in Plasmodium falciparum‐Infected Erythrocytes: Role of the Parasite Group II Chaperonin,PfTRiC

The export of numerous proteins to the plasma membrane of its host erythrocyte is essential for the virulence and survival of the malaria parasite Plasmodium falciparum. The Maurer's clefts, membrane structures transposed by the parasite in the cytoplasm of its host erythrocyte, play the role of a marshal platform for such exported parasite proteins. We identify here the export pathway of three resident proteins of the Maurer's clefts membrane: the proteins are exported as soluble forms in the red cell cytoplasm to the Maurer's clefts membrane in association with the parasite group II chaperonin (PfTRIC), a chaperone complex known to bind and address a large spectrum of unfolded proteins to their final location. We have also located the domain of interaction with PfTRiC within the amino‐terminal domain of one of these Maurer's cleft proteins, PfSBP1. Because several Maurer's cleft membrane proteins with different export motifs seem to follow the same route, we propose a general role for PfTRiC in the trafficking of malarial parasite proteins to the host erythrocyte.      

Delivery of the malaria virulence protein PfEMP1 to the erythrocyte surface requires cholesterol-rich domains

The particular virulence of the human malaria parasite Plasmodium falciparum derives from export of parasite-encoded proteins to the surface of the mature erythrocytes in which it resides. The mechanisms and machinery for the export of proteins to the erythrocyte membrane are largely unknown. In other eukaryotic cells, cholesterol-rich membrane microdomains or "rafts" have been shown to play an important role in the export of proteins to the cell surface. Our data suggest that depletion of cholesterol from the erythrocyte membrane with methyl-beta-cyclodextrin significantly inhibits the delivery of the major virulence factor P. falciparum erythrocyte membrane protein 1 (PfEMP1). The trafficking defect appears to lie at the level of transfer of PfEMP1 from parasite-derived membranous structures within the infected erythrocyte cytoplasm, known as the Maurer's clefts, to the erythrocyte membrane. Thus our data suggest that delivery of this key cytoadherence-mediating protein to the host erythrocyte membrane involves insertion of PfEMP1 at cholesterol-rich microdomains. GTP-dependent vesicle budding and fusion events are also involved in many trafficking processes. To determine whether GTP-dependent events are involved in PfEMP1 trafficking, we have incorporated non-membrane-permeating GTP analogs inside resealed erythrocytes. Although these nonhydrolyzable GTP analogs reduced erythrocyte invasion efficiency and partially retarded growth of the intracellular parasite, they appeared to have little direct effect on PfEMP1 trafficking.     

Evidence for trafficking of PfEMP1 to the surface of P. falciparum-infected erythrocytes via a complex membrane network

The human malarial parasite Plasmodium falciparum exports virulence determinants, such as the P. falciparum erythrocyte membrane protein 1 (PfEMP1), beyond its own periplasmatic boundaries to the surface of its host erythrocyte. This is remarkable given that erythrocytes lack a secretory pathway. Here we present evidence for a continuous membrane network of parasite origin in the erythrocyte cytoplasm. Co-localizations with antibodies against PfEMP1, PfExp-1, Pf332 and PfSbpl at the light and electron microscopical level indicate that this membrane network is composed of structures that have been previously described as tubovesicular membrane network (TVM), Maurer's clefts and membrane whorls. This membrane network could also be visualized in vivo by vital staining of infected erythrocytes with the fluorescent dye LysoSensor Green DND-153. At sites where the membrane network abuts the erythrocyte plasma membrane we observed small vesicles of 15-25 nm in size, which seem to bud from and/or fuse with the membrane network and the erythrocyte plasma membrane, respectively. On the basis of our data we hypothesize that this membrane network of parasite origin represents a novel secretory organelle that is involved in the trafficking of PfEMP1 across the erythrocyte cytoplasm.     

Export of PfSBP1 to the Plasmodium falciparum Maurer's Clefts

The human malaria parasite Plasmodium falciparum exports determinants of virulence and pathology to destinations within the host erythrocyte, including the erythrocyte cytoplasm, plasma membrane and membrane profiles of parasite origin termed Maurer's clefts. Most of the exported proteins contain a conserved pentameric motif termed plasmodial export element (PEXEL)/vacuolar transfer signal (VTS) that functions as a cleavable sorting signal permitting export to the host erythrocyte. However, there are some exported proteins, such as the skeleton-binding protein 1 (PfSBP1) that lack the PEXEL/VTS motif and that are not N-terminally processed, suggesting the presence of alternative sorting signals and/or mechanisms. In this study, we have investigated trafficking of PfSBP1 to the Maurer's clefts. Our data show that the transmembrane domain of PfSBP1 functions as an internal signal sequence for entry into the parasite's secretory pathway and for transport to the parasite plasma membrane. Trafficking beyond the parasite's plasma membrane required additional N-terminal domains, which are characterized by a high negative net charge. Biochemical data indicate that these domains affect the solubility and extraction profile, the orientation of the protein within the membrane and the subcellular localization. Our findings suggest new principles of protein export in P.   falciparum -infected erythrocytes.     

Morphological changes in erythrocytes induced by malarial parasites

Host cell alterations induced by Plasmodium falciparum, P. brasilianum, P. vivax and P. malariae were described by electron microscopy and post-embedding immunoelectron microscopy. P. falciparum infection induces knobs, electron-dense material and clefts in the erythrocyte. Clefts are involved in exporting P. falciparum antigen from the parasite to the erythrocyte membrane. P. falciparum antigen is present in knobs which adhere to endothelial cells causing the blockage of cerebral capillaries and ensuing pathological changes in cerebral tissues. P. brasilianum infection induces knobs, short and long clefts and electron-dense material. These structures appear to contain different P. brasilianum antigens. This indicates that each structure functions independently in trafficking P. brasilianum protein to the erythrocyte surface. P. vivax infection induces caveola-vesicle complexes and clefts in the erythrocyte. These structures are also involved in trafficking P. vivax protein from the parasite to the erythrocyte membrane. P. malariae induces caveolae, electron-dense material, vesicles, clefts and knobs in the erythrocyte. Although vesicles and caveolae are seen in the erythrocyte cytoplasm, they do not form caveola-vesicle complexes as seen in P. vivax-infected erythrocytes. They also appear to be involved in trafficking of malaria antigens. These studies, therefore, indicate that host cell changes occur in order to facilitate the transport of malarial antigens to the host cell membrane. The significance of these phenomena is still not clear.