Maurer's clefts-restricted localization, orientation and export of a Plasmodium falciparum RIFIN

RIFINs are clonally variant antigens expressed in Plasmodium falciparum. Transfection and the green fluorescence protein (GFP) tagged either internally or C-terminally to the 3D7 PFI0050c RIFIN gene product were used to investigate protein localization, orientation and trafficking. Green fluorescence pattern emerging from live transfectant parasites expressing each of the RIFIN-GFP chimera was different. The internally GFP-tagged protein was exported to Maurer's clefts (MC) in the erythrocyte cytosol, whereas the C-terminally GFP-tagged full-length RIFIN chimera was not trafficked out of the parasite. Interestingly, when some RIFIN-specific C-terminal amino acid sequences were removed, the resulting truncated molecule reached the MC. Using anti-RIFIN and anti-GFP antibodies to probe both live and fixed transfectants, staining was confined to MC and was not detected on the erythrocyte surface, a location previously suggested for this protein family. From selective permeabilization experiments, the highly variable portion of the RIFIN-GFP-insertion chimera appeared to be exposed to the erythrocyte cytosol, presumably anchored in the MC membrane via the two transmembrane domains. Trafficking of both chimeras in young ring stages was sensitive to Brefeldin A (BFA), although older rings showed differential sensitivity to BFA.     

Maurer's clefts: a novel multi-functional organelle in the cytoplasm of Plasmodium falciparum-infected erythrocytes

Discovered in 1902 by Georg Maurer as a peculiar dotted staining pattern observable by light microscopy in the cytoplasm of erythrocytes infected with the human malarial parasite Plasmodium falciparum, the function of Maurer's clefts have remained obscure for more than a century. The growing interest in protein sorting and trafficking processes in malarial parasites has recently aroused the Maurer's clefts from their deep slumber. Mounting evidence suggests that Maurer's clefts are a secretory organelle, which the parasite establishes within its host erythrocyte, but outside its own confines, to route parasite proteins across the host cell cytoplasm to the erythrocyte surface where they play a role in nutrient uptake and immune evasion processes. Moreover, Maurer's clefts seem to play a role in cell signaling, merozoite egress, phospholipid biosynthesis and, possibly, other biochemical pathways. Here, we review our current knowledge of the ultrastructure of Maurer's clefts, their proteinaceous composition and their function in protein 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.     

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.     

Formation of pure and mixed clones of c mutants in serratiaphage sigma after treatment of the free virion with UV or hydroxylamine

The clone composition of c mutants of phage σ induced by UV irradiation of the free virion was studied, using Hcr⁺, Hcr^? and UV-irradiated Hcr⁺ cells as hosts and 2, 3 and 4 different UV doses, respectively. Most of the c plaques contained only mutant phages, and the distribution of mosaics was asymmetrical, i.e. most mixed clones contained >80% mutant type. The frequency of mosaics decreased with increasing UV dose in all three host systems; however, the decrease was significant only with the UV-irradiated Hcr⁺ host. Propagation of UV-irradiated σ in Hcr⁺ and Hcr^? hosts, respectively, did not lead to a significant difference in the frequency of mosaics, but, using UV-irradiated Hcr⁺ host significantly increased the percentage of mixed clones.The composition of plaques containing c mutants, after UV irradiation and treatment with hydroxylamine, was also studied by picking and testing all plaques (mutant and wild-type) of the survivors of a single UV dose and a single incubation time, respectively. In both experiments, besides pure and nearly pure (visible) c mutant plaques, many cryptic mutants containing predominantly >20% mutant type were found. The distribution of mosaics was of an almost “inverse symmetrical” type, the class of clones with about 50% mutant and 50% wild-type being the rarest.From these results incomplete recombinational repair is suggested to be responsible for the formation of pure mutant clones in mutation induction.     

鼠疟原虫裂殖子的超微结构研究

用透射电镜观察了两种鼠疟原虫的体内游离裂殖子。发现顶端中央有一凹陷的口样结构。描述了棒状体、球形体和个体间的结构差异,以及核孔、表被等的形态细节。还注意到线粒体外侧常伴有一致密舌形结构。对以上结果进行了讨论。     

Ultraviolet reactivation of lambda phage: assay of infectivity of DNA molecules by spheroplast transfection

Prior irradiation of non-lysogenic bacteria by ultraviolet light leads to an increase in the viability of infecting irradiated λ phage (ultraviolet reactivation). Similarly, u.v. irradiation of wild type or uvrD bacteria lysogenic for λcIind^? increased the fraction of closed circular duplex phage DNA molecules formed after infection with u.v.-irradiated λ phage. The closed circular molecules isolated from the irradiated lysogens were shown to be free from u.v. damage by a spheroplast transfection assay. The increase of closed circular molecules is sufficient to explain the ultraviolet reactivation observed by the increase of viability of irradiated phage.In ultraviolet reactivation, damage must be erased on irradiated DNA molecules and the repair is independent of total replication of phage genomes, exchange of sister chromatids or recombination between phage genomes. Protein synthesis is necessary to increase the level of closed circular molecules of irradiated λ phage after irradiation of bacteria.     

A mutant of Escherichia coli K-12, URT-34, with a temperature-sensitive defect at the incision step of the excision repair mechanism

URT-43, which has a defect in excision repair, exhibits a temperature-dependent ultraviolet survival. It was shown that URT-43 requires protein synthesis but not DNA synthesis for recovery, by examining recovery in a growth medium containing chloramphenicol or nalidixic acid. The recovery of irradiated bacteriophage λ in URT-43 took place in a medium containing nalidixic acid at 30°, but not at 41°, and chloramphenicol prevented this recovery. These results seem to imply that the product of the mutated gene in URT-43 is labile. URT-43 was confirmed to have a temperature-sensitive mutation at the incision step of the excision repair mechanism by examining the nick formation of parental DNA in alkaline sucrose gradients. The release of pyrimidine dimers was reinvestigated directly by one- and two-dimensional paper-chromatography and indirectly by examining the distribution of DNA molecules synthesized after irradiation. Dimers were excised into the acid-soluble fraction when growing bacteria were incubated, but were not excised when in amino acid starved bacteria. These results suggest that URT-43 is a mutant slowly excising pyrimidine dimers because the product of a mutated gene concerned with the incision step of the excision repair mechanism is unstable.     

Exploration of the P3 region of PEXEL peptidomimetics leads to a potent inhibitor of the Plasmodium protease,plasmepsin V

The use of arginine isosteres is a known strategy to overcome poor membrane permeability commonly associated with peptides or peptidomimetics that possess this highly polar amino acid. Here, we apply this strategy to peptidomimetics that are potent inhibitors of the malarial protease, plasmepsin V, with the aim of enhancing their activity against Plasmodium parasites, and exploring the structure–activity relationship of the P₃ arginine within the S₃ pocket of plasmepsin V. Of the arginine isosteres trialled in the P₃ position, we discovered that canavanine was the ideal and that this peptidomimetic potently inhibits plasmepsin V, efficiently blocks protein export and inhibits parasite growth. Structure studies of the peptidomimetics bound to plasmepsin V provided insight into the structural basis for the enzyme activity observed in vitro and provides further evidence why plasmepsin V is highly sensitive to substrate modification.