Expression and purification of full-length recombinant Plasmodium falciparum PfMC-2TM Maurer’s cleft protein

Malaria caused by Plasmodium falciparum remains the most virulent form of malaria, resulting in 216 million cases and 445,000 deaths globally. Invasion of red blood cells by P. falciparum leads to the formation of membranous structures known as Maurer’s clefts (MC). Virulence markers of P. falciparum such as PfEMP1 are transported across the MC to the surface of the infected red blood cell. Insight into the formation and function of the MC will be important for the discovery of new vaccine and drug candidates. The PfMC-2TM is encoded by a multi-gene family of 13 members. PfMC- 2TM is a protein localized to the MC. We induced expression of PfMC-2TM encoded by 1 family member [PF3D7_0114100 (PFA0680c)] in BL21 DE3 strain of Escherichia coli following transformation with recombinant pET-28a plasmid containing a chemically synthesized gene. The purpose of this study was to determine immunogenic properties of the resulting recombinant protein using western blot analysis. The recombinant plasmid was isolated and analyzed in 1% agarose gel and an approximately 5kb band was identified. Pilot expression of transformants showed expression of recombinant PfMC-2TM by western blot. Recombinant PfMC-2TM protein will be expressed and purified for antibody production to allow subsequent domain analysis and characterization.https://engagedscholarship.csuohio.edu/u_poster_2018/1021/thumbnail.jp

Hypervariability within the Rifin, Stevor and Pfmc-2TM superfamilies in Plasmodium falciparum

The human malaria parasite, Plasmodium falciparum, possesses a broad repertoire of proteins that are proposed to be trafficked to the erythrocyte cytoplasm or surface, based upon the presence within these proteins of a Pexel/VTS erythrocyte-trafficking motif. This catalog includes large families of predicted 2 transmembrane (2TM) proteins, including the Rifin, Stevor and Pfmc-2TM superfamilies, of which each possesses a region of extensive sequence diversity across paralogs and between isolates that is confined to a proposed surface-exposed loop on the infected erythrocyte. Here we express epitope-tagged versions of the 2TM proteins in transgenic NF54 parasites and present evidence that the Stevor and Pfmc-2TM families are exported to the erythrocyte membrane, thus supporting the hypothesis that host immune pressure drives antigenic diversity within the loop. An examination of multiple P.falciparum isolates demonstrates that the hypervariable loop within Stevor and Pfmc-2TM proteins possesses sequence diversity across isolate boundaries. The Pfmc-2TM genes are encoded within large amplified loci that share profound nucleotide identity, which in turn highlight the divergences observed within the hypervariable loop. The majority of Pexel/VTS proteins are organized together within sub-telomeric genome neighborhoods, and a mechanism must therefore exist to differentially generate sequence diversity within select genes, as well as within highly defined regions within these genes

A highly conserved segmental duplication in the subtelomeres of Plasmodium falciparum chromosomes varies in copy number

<p>Abstract</p> <p>Background</p> <p>Segmental duplications (SD) have been found in genomes of various organisms, often accumulated at the ends of chromosomes. It has been assumed that the sequence homology in-between the SDs allow for ectopic interactions that may contribute to the emergence of new genes or gene variants through recombinatorial events.</p> <p>Methods</p> <p><it>In silico </it>analysis of the 3D7 <it>Plasmodium falciparum </it>genome, conducted to investigate the subtelomeric compartments, led to the identification of subtelomeric SDs. Sequence variation and copy number polymorphisms of the SDs were studied by DNA sequencing, real-time quantitative PCR (qPCR) and fluorescent <it>in situ </it>hybridization (FISH). The levels of transcription and the developmental expression of copy number variant genes were investigated by qPCR.</p> <p>Results</p> <p>A block of six genes of >10 kilobases in size, including <it>var</it>, <it>rif</it>, <it>pfmc-2tm </it>and three hypothetical genes (<it>n-, o- </it>and <it>q-gene</it>), was found duplicated in the subtelomeric regions of chromosomes 1, 2, 3, 6, 7, 10 and 11 (SD1). The number of SD1 per genome was found to vary from 4 to 8 copies in between different parasites. The intragenic regions of SD1 were found to be highly conserved across ten distinct fresh and long-term cultivated <it>P. falciparum</it>. Sequence variation was detected in a ≈ 23 amino-acid long hypervariable region of a surface-exposed loop of PFMC-2TM. A hypothetical gene within SD1, the <it>n-gene</it>, encoding a PEXEL/VTS-containing two-transmembrane protein was found expressed in ring stage parasites. The <it>n-gene </it>transcription levels were found to correlate to the number of <it>n-gene </it>copies. Fragments of SD1 harbouring two or three of the SD1-genes (<it>o-gene, pfmc-2tm, q-gene</it>) were also found in the 3D7 genome. In addition a related second SD, SD2, of ≈ 55% sequence identity to SD1 was found duplicated in a fresh clinical isolate but was only present in a single copy in 3D7 and in other <it>P. falciparum </it>lines or clones.</p> <p>Conclusion</p> <p><it>Plasmodium falciparum </it>carries multiple sequence conserved SDs in the otherwise highly variable subtelomeres of its chromosomes. The uniqueness of the SDs amongst plasmodium species, and the conserved nature of the genes within, is intriguing and suggests an important role of the SD to <it>P. falciparum</it>.</p

Absence of Erythrocyte Sequestration and Lack of Multicopy Gene Family Expression in Plasmodium falciparum from a Splenectomized Malaria Patient

BACKGROUND:To avoid spleen-dependent killing mechanisms parasite-infected erythrocytes (IE) of Plasmodium falciparum malaria patients have the capacity to bind to endothelial receptors. This binding also known as sequestration, is mediated by parasite proteins, which are targeted to the erythrocyte surface. Candidate proteins are those encoded by P. falciparum multicopy gene families, such as var, rif, stevor or PfMC-2TM. However, a direct in vivo proof of IE sequestration and expression of multicopy gene families is still lacking. Here, we report on the analysis of IE from a black African immigrant, who received the diagnosis of a malignant lymphoproliferative disorder and subsequently underwent splenectomy. Three weeks after surgery, the patient experienced clinical falciparum malaria with high parasitemia and circulating developmental parasite stages usually sequestered to the vascular endothelium such as late trophozoites, schizonts or immature gametocytes. METHODOLOGY/PRINCIPAL FINDINGS:Initially, when isolated from the patient, the infected erythrocytes were incapable to bind to various endothelial receptors in vitro. Moreover, the parasites failed to express the multicopy gene families var, A-type rif and stevor but expression of B-type rif and PfMC-2TM genes were detected. In the course of in vitro cultivation, the parasites started to express all investigated multicopy gene families and concomitantly developed the ability to adhere to endothelial receptors such as CD36 and ICAM-1, respectively. CONCLUSION/SIGNIFICANCE:This case strongly supports the hypothesis that parasite surface proteins such as PfEMP1, A-type RIFIN or STEVOR are involved in interactions of infected erythrocytes with endothelial receptors mediating sequestration of mature asexual and immature sexual stages of P. falciparum. In contrast, multicopy gene families coding for B-type RIFIN and PfMC-2TM proteins may not be involved in sequestration, as these genes were transcribed in infected but not sequestered erythrocytes

Transcriptional regulation of virulence gene families in "Plasmodium falciparum"

To date, malaria caused by Plasmodium falciparum is still a major health threat. It contributes to illness and severe disease and is responsible for up to one million deaths per year. The intra-erythrocytic asexual life cycle stage is responsible for the pathology associated with malaria. The major virulence factor P. falciparum erythrocyte membrane protein 1 (PfEMP1) is exposed at the surface of infected red blood cells (iRBC) and mediates binding to endothelial cells. This leads to sequestration of iRBC in the microvasculature and consequently to evasion of removal in the spleen. PfEMP1 is encoded by the 60-member var gene family, which undergoes antigenic variation by in-situ switching. Importantly, var genes are expressed in a mutually exclusive way, such that only one member is expressed whereas all other copies remain silenced. var genes as well as other gene families such as rif, stevor, phist and pfmc-2tm are located in subtelomeric heterochromatic regions. The function of these additional families is largely unknown, but they are thought to be implicated in host-parasite interactions and to contribute to antigenic variation. With this work, I provide deeper insights into the transcriptional regulation of virulence gene families in P. falciparum by using transfection-based approaches. We functionally identified autonomous cis-acting var promoter elements including an upstream activating sequence that is essential for promoter activation. Notably, an element downstream of the transcriptional start site determines mutually exclusive locus recognition. Further, I used comparative transcriptional profiling to show that mutually exclusive expression is restricted to the var gene family and is not used in the transcription of other subtelomeric gene families. I show for the first time that knock-down of endogenous var gene transcription is also conferred by promoters of a var gene subfamily that is implicated in severe malaria. Taken together, this work provides important insight into the mechanisms involved in the regulation of virulence gene families and antigenic variation in P. falciparum. Moreover, the findings presented here are consistent with a novel mechanism of mutually exclusive gene choice in eukaryotes

Design of a variant surface antigen-supplemented microarray chip for whole transcriptome analysis of multiple Plasmodium falciparum cytoadherent strains, and identification of strain-transcendent rif and stevor genes

<p>Abstract</p> <p>Background</p> <p>The cytoadherence of <it>Plasmodium falciparum </it>is thought to be mediated by variant surface antigens (VSA), encoded by <it>var</it>, <it>rif</it>, <it>stevor </it>and <it>pfmc-2tm </it>genes. The last three families have rarely been studied in the context of cytoadherence. As most VSA genes are unique, the variability among sequences has impeded the functional study of VSA across different <it>P. falciparum </it>strains. However, many <it>P. falciparum </it>genomes have recently been sequenced, allowing the development of specific microarray probes for each VSA gene.</p> <p>Methods</p> <p>All VSA sequences from the HB3, Dd2 and IT/FCR3 genomes were extracted using HMMer software. Oligonucleotide probes were designed with OligoRankPick and added to the 3D7-based microarray chip. As a proof of concept, IT/R29 parasites were selected for and against rosette formation and the transcriptomes of isogenic rosetting and non-rosetting parasites were compared by microarray.</p> <p>Results</p> <p>From each parasite strain 50-56 <it>var </it>genes, 125-132 <it>rif </it>genes, 26-33 <it>stevor </it>genes and 3-8 <it>pfmc-2tm </it>genes were identified. Bioinformatic analysis of the new VSA sequences showed that 13 <it>rif genes </it>and five <it>stevor </it>genes were well-conserved across at least three strains (83-100% amino acid identity). The ability of the VSA-supplemented microarray chip to detect cytoadherence-related genes was assessed using <it>P. falciparum </it>clone IT/R29, in which rosetting is known to be mediated by PfEMP1 encoded by <it>ITvar9</it>. Whole transcriptome analysis showed that the most highly up-regulated gene in rosetting parasites was <it>ITvar9 </it>(19 to 429-fold up-regulated over six time points). Only one <it>rif </it>gene (<it>IT4rifA_042</it>) was up-regulated by more than four fold (five fold at 12 hours post-invasion), and no <it>stevor </it>or <it>pfmc-2tm </it>genes were up-regulated by more than two fold. 377 non-VSA genes were differentially expressed by three fold or more in rosetting parasites, although none was as markedly or consistently up-regulated as <it>ITvar9</it>.</p> <p>Conclusions</p> <p>Probes for the VSA of newly sequenced <it>P. falciparum </it>strains can be added to the 3D7-based microarray chip, allowing the analysis of the entire transcriptome of multiple strains. For the rosetting clone IT/R29, the striking transcriptional upregulation of <it>ITvar9 </it>was confirmed, and the data did not support the involvement of other VSA families in rosette formation.</p

Whole genome sequencing and microsatellite analysis of the Plasmodium falciparum E5 NF54 strain show that the var, rifin and stevor gene families follow Mendelian inheritance

Background: Plasmodium falciparum exhibits a high degree of inter-isolate genetic diversity in its variant surface antigen (VSA) families: P. falciparum erythrocyte membrane protein 1, repetitive interspersed family (RIFIN) and subtelomeric variable open reading frame (STEVOR). The role of recombination for the generation of this diversity is a subject of ongoing research. Here the genome of E5, a sibling of the 3D7 genome strain is presented. Short and long read whole genome sequencing (WGS) techniques (Ilumina, Pacific Bioscience) and a set of 84 microsatellites (MS) were employed to characterize the 3D7 and non-3D7 parts of the E5 genome. This is the first time that VSA genes in sibling parasites were analysed with long read sequencing technology. Results: Of the 5733 E5 genes only 278 genes, mostly var and rifin/stevor genes, had no orthologues in the 3D7 genome. WGS and MS analysis revealed that chromosomal crossovers occurred at a rate of 0–3 per chromosome. var, stevor and rifin genes were inherited within the respective non-3D7 or 3D7 chromosomal context. 54 of the 84 MS PCR fragments correctly identified the respective MS as 3D7- or non-3D7 and this correlated with var and rifin/stevor gene inheritance in the adjacent chromosomal regions. E5 had 61 var and 189 rifin/stevor genes. One large non-chromosomal recombination event resulted in a new var gene on chromosome 14. The remainder of the E5 3D7-type subtelomeric and central regions were identical to 3D7. Conclusions: The data show that the rifin/stevor and var gene families represent the most diverse compartments of the P. falciparum genome but that the majority of var genes are inherited without alterations within their respective parental chromosomal context. Furthermore, MS genotyping with 54 MS can successfully distinguish between two sibling progeny of a natural P. falciparum cross and thus can be used to investigate identity by descent in field isolates