Ectopic Expression of Plasmodium vivax vir Genes in P. falciparum Affects Cytoadhesion via Increased Expression of Specific var Genes

Plasmodium falciparum-infected erythrocytes (PfIEs) adhere to endothelial cell receptors (ECRs) of blood vessels mainly via PfEMP1 proteins to escape elimination via the spleen. Evidence suggests that P. vivax-infected reticulocytes (PvIRs) also bind to ECRs, presumably enabled by VIR proteins, as shown by inhibition experiments and studies with transgenic P. falciparum expressing vir genes. To test this hypothesis, our study investigated the involvement of VIR proteins in cytoadhesion using vir gene-expressing P. falciparum transfectants. Those VIR proteins with a putative transmembrane domain were present in Maurer’s clefts, and some were also present in the erythrocyte membrane. The VIR protein without a transmembrane domain (PVX_050690) was not exported. Five of the transgenic P. falciparum cell lines, including the one expressing PVX_050690, showed binding to CD36. We observed highly increased expression of specific var genes encoding PfEMP1s in all CD36-binding transfectants. These results suggest that ectopic vir expression regulates var expression through a yet unknown mechanism. In conclusion, the observed cytoadhesion of P. falciparum expressing vir genes depended on PfEMP1s, making this experimental unsuitable for characterizing VIR proteins.


Introduction
Plasmodium vivax is the second most common malaria pathogen in the world with about 4.5 million malaria cases annually. This parasite is particularly widespread in Central and South America and in Asia. However, while 627,000 people die from infection with P. falciparum, only about 30,000 people per year die from infection with P. vivax [1]. The reasons for the large differences in mortality depend on the difference in infection modes. P. vivax infects only reticulocytes, which constitute 0.5-2.0 percent of peripheral blood cells, while P. falciparum infects erythrocytes, allowing for much higher parasitemia [2,3]. Furthermore, erythrocytes infected with trophozoite stage P. falciparum cytoadhere to endothelial cell receptors (ECRs) of blood vessels to escape elimination via the spleen [4,5]. However, this leads to a number of pathological consequences for the human host, which include motif in 160 vir genes that had similarity to the export signal from P. falciparum [37,38]. This suggested that the VIR proteins adopt different localizations and thus different functions in the PvIR [38,39]. This was also indicated by the simultaneous expression of several vir genes, in contrast with the mutually exclusive expression of var genes. Therefore, the VIR proteins do not appear to be involved in antigenic variation [19,38,[40][41][42].
To analyze the function of VIR proteins in cytoadhesion, transgenic P. falciparum cell lines were generated, expressing three different vir genes [39]. Export was predicted for all three encoded VIR proteins (PVX_102635 (VIR10), PVX_108770 (VIR14), and PVX_112645 (VIR17-like)). PVX_108770 and PVX_102635 could be localized to the erythrocyte membrane, but for PVX_108770, only cytoadhesion to CD36, ICAM-1, E-selectin, and VCAM-1 could be detected under static conditions and only to ICAM-1 under flow conditions. Furthermore, only binding to ICAM-1 could be specifically inhibited with antibodies against conserved VIR domains [39]. The results were verified by Fernandez-Bercerra et al., who showed that the VIR protein PVX_108770 adhered particularly to fibrocyte cells expressing ICAM-1 [43].
In order to identify further VIR proteins mediating cytoadhesion to ECRs in our study, in addition to the described VIR protein PVX_108770, further transgenic P. falciparum cell lines expressing different vir genes were generated. For this purpose, 12 P. falciparum transfectants were generated, the localization of the VIR proteins encoded by the expressed vir genes was determined, and the binding profile was analyzed using transgenic CHO-745 cells presenting CD36 or ICAM-1 on their cell surface. Five transgenic P. falciparum lines showed binding to CD36. However, the transcriptome analyses showed binding is most likely not mediated by the VIR proteins. Vir expression leads to a strongly increased expression of specific var genes, which encode Pf EMP1s of the B-and C-family and could mediate the observed binding phenotype.

CHO-745 Cell Culture
For the binding assays, transgenic CHO-745 cells presenting CD36 or ICAM-1 on the cell surface were used. For this step, the CHO-745 cells were transfected with the vector pAcGFP-N1 containing either the gene encoding CD36 or the gene encoding ICAM-1. As control, mock-transfected cells were used. The transfection of the CHO-745 cells was performed as described previously [48]. G418 (0.7 mg/mL; Geneticin; Thermo Fisher Scientific, Bremen, Germany) was used as a selection marker. Transfected CHO-745 cells were cultivated in Ham's F12 medium (Capricorn Scientific, Ebsdorfergrund, Germany) supplemented with 10% heat-inactivated fetal calf serum (Capricorn Scientific, Ebsdorfergrund, Germany) and penicillin-streptomycin (0.1 U/mL; Gibco, Thermo Fisher Scientific, Bremen, Germany). The transgenic CHO-745 cells presenting CD36 or ICAM-1 on the cell surface were routinely sorted for surface expression of the ECRs via fluorescence-activated cell sorting ( Figure S2).

Static Binding Assay
A static binding assay was performed to verify the binding capacity of the transgenic parasites expressing different vir genes. Highly synchronized trophozoite stage or schizont stage parasites culture were used. Forty-eight hours before the binding experiment, transgenic CHO-745 cells (3 × 10 4 ) were seeded as a triplicate on a coverslip (coated before with 1% gelatin) in a 24-well plate. On the day of the assay, the parasite culture was set to a parasitemia of 5% and a hematocrit of 1% in the binding medium (RPMI 1640/2% glucose). To reduce non-specific binding, pre-absorption of Pf IEs was performed on mock-transfected CHO-745 cells in a T25 flask for 1 h at 37 • C, with the flask swirled every 15 min. Afterward, the pre-absorbed Pf IEs were added to the respective wells with the transgenic CHO-745 cells and incubated for 1 h at 37 • C, again carefully swirling the plate every 15 min. After 1 h, the coverslips were removed from the wells and washed in beakers filled with a binding medium. They were then placed in a new plate that was fixed at a 45 • angle, containing 600 µL binding medium in each well, and incubated for 45 min at RT with the overgrown side down. The remaining Pf IEs were fixed with 1% glutaraldehyde in PBS for 30 min at room temperature (RT). The fixed cells were stained with a filtered Giemsa/Weisser buffer solution (1:10) for another 30 min. The coverslips were then fixed to a slide with a drop of CV Leica Mounting Solution (Leica, Wetzlar, Germany) with the overgrown side

RNA Purification and mRNAseq
For RNA isolation, parasites were synchronized 48 h prior to harvest. Ring stage Pf IEs were rapidly lysed in a medium 10-times the volume of the cells with pre-warmed 37 • C TRIzol (Invitrogen, Thermo Fisher Scientific, Bremen, Germany) and incubated for 5 min at 37 • C. Samples were stored at −80 • C before RNA was isolated using a PureLink RNA Mini Kit (Thermo Fisher Scientific, Bremen, Germany) according to the manufacturer's instructions. Contaminations with genomic DNA were removed using the TURBO DNAfree Kit (Invitrogen, Thermo Fisher Scientific, Bremen, Germany) and using the Agencourt RNAClean XP (Beckman Coulter, Krefeld, Germany). The RNA concentration and quality was analyzed with an Agilent 2100 Bioanalyser System using the Agilent RNA 6000 Pico Kit (Agilent Technologies, Ratlingen, Germany).
The total RNA from each sample was prepared for sequencing using the QIAseq Stranded mRNA Library Kit (Qiagen, Hilden, Germany) according to the manufacturer's instructions. The methodology was based on the 3 -end captures of polyadenylated RNA species and included unique dual indexes (UDIs), which allow direct counting of unique RNA molecules in each sample. Normalized libraries were pooled and sequenced using a 150-cycle (2 × 75 bp paired-end) NextSeq 550 reagent kit v2.5 (Illumina, San Diego, CA, USA) on a NextSeq 550 platform with a depth of 8-16 million paired-end reads generated for each sample. The reads were trimmed and filtered using Trimmomatic [49] and aligned to 3D7 genome data available at PlasmoDB, release 54 [50] using RSEM [51] and Bowtie2 [52] software. The differential expression was tested using DEseq2 for normalization of the raw reads [53].

Expression of vir Genes in P. falciparum and Localization of the Respective Encoded VIR Protein
A total of 12 transfectants of the P. falciparum isolate 3D7 expressing different vir genes were generated (PVX_050690 3D7 , PVX_060690 3D7 , PVX_093715 3D7 , PVX_101560 3D7 , PVX_113230 3D7 , PVX_115475 3D7 , PVX_068690 3D7 , PVX_077695 3D7 , PVX_081850 3D7 , PVX_ 096925 3D7 , PVX_097525 3D7 , and PVX_107235 3D7 ). The selection was based on the determination of different domains using various in silico analyses. Thus, when selecting the VIR proteins, care was taken to ensure that all but one of them had one transmembrane domain and were of different sizes. The VIR protein PVX_050690 does not have a predicted transmembrane domain and thus acted as a control of a non-exported protein. In addition, the VIR proteins were analyzed using the online program 3 of 5 to determine whether they contained the protein export motif PEXEL (RxLxE/Q/D) or a PEXEL-like motif (RxLxx) within the first 70 amino acids. A PEXEL motif was identified in the VIR protein PVX_096925, in PVX_097525, and in PVX_101560. A mature N-terminus (MAQ/MAA/MEE) was present in PVX_081850, PVX_107235, and PVX_115475 ( Figure 1).  Immunofluorescence analyses were performed to localize the VIR proteins in the PfIEs. In order to detect the VIR proteins, a 3xHA-tag was fused to their C-terminus. Therefore, two specific first antibodies were always used, one detecting the 3xHA-tag and the other a protein that can be assigned to a specific compartment of the PfIE (α-spectrinerythrocyte membrane, α-ETRAMP-parasitophorous vacuolar membrane (PVM), α-SBP-1-Maurer's clefts, or α-ATS-conserved acidic terminal segment of PfEMP1).
As suspected from the missing transmembrane domain, the VIR protein PVX_050690 was not exported, and localization was thus restricted to the parasite (Figures 2, 3 and S3). In all other P. falciparum transfectants, an export of the VIR proteins in the PfIEs could be detected. Here, colocalization of the VIR proteins with Maurer's clefts was found for all transfectants. At the trophozoite stage, association with the surface of PfIEs was detected only for the VIR protein PVX_068690 in 11.7% of the PfIEs examined. This percentage increased to 33.9% in the schizont stage PfIEs. The VIR protein PVX_113230 was detected at the erythrocyte membrane in 49% of the analyzed schizont stage PfIEs, followed by PVX_068690 with 34%, PVX_101560 with 28.3%, and PVX_081850 with 17.5%. For all other transfectants, membrane association could only be detected in 8-17% of the analysed PfIEs, with PVX_115475 only detected in the parasite and Maurer's clefts (Figures 2, 3 and S3). In addition, the extent of colocalization of VIR proteins with PfEMP1 should be investigated. To localize PfEMP1s, an α-ATS antibody directed against the conserved cytoplasmic ATS domain was used. Unfortunately, for unknown reasons, this antibody did not recognize PfEMP1 presented on the surface of PfIEs; however, PfEMP1 localized in the Maurer's clefts can be detected. Interestingly, only partial colocalization (50-80%) of PfEMP1 with SBP-1, the Maurer's clefts marker, was detectable. The VIR proteins PVX_068690 and PVX_077695 showed a 93-97% colocalization with the ATS domain of PfEMP1s, both in the trophozoite and in the schizont stage. For almost all other VIR proteins, a colocalization between 20-55% (with one exception of 80%, PVX_081850) can be found (Figures 2, 3 and S3). Immunofluorescence analyses were performed to localize the VIR proteins in the Pf IEs. In order to detect the VIR proteins, a 3xHA-tag was fused to their C-terminus. Therefore, two specific first antibodies were always used, one detecting the 3xHA-tag and the other a protein that can be assigned to a specific compartment of the Pf IE (α-spectrin-erythrocyte membrane, α-ETRAMP-parasitophorous vacuolar membrane (PVM), α-SBP-1-Maurer's clefts, or α-ATS-conserved acidic terminal segment of Pf EMP1).
As suspected from the missing transmembrane domain, the VIR protein PVX_050690 was not exported, and localization was thus restricted to the parasite (Figures 2, 3 and S3). In all other P. falciparum transfectants, an export of the VIR proteins in the Pf IEs could be detected. Here, colocalization of the VIR proteins with Maurer's clefts was found for all transfectants. At the trophozoite stage, association with the surface of Pf IEs was detected only for the VIR protein PVX_068690 in 11.7% of the Pf IEs examined. This percentage increased to 33.9% in the schizont stage Pf IEs. The VIR protein PVX_113230 was detected at the erythrocyte membrane in 49% of the analyzed schizont stage Pf IEs, followed by PVX_068690 with 34%, PVX_101560 with 28.3%, and PVX_081850 with 17.5%. For all other transfectants, membrane association could only be detected in 8-17% of the analysed Pf IEs, with PVX_115475 only detected in the parasite and Maurer's clefts (Figures 2, 3 and S3). In addition, the extent of colocalization of VIR proteins with Pf EMP1 should be investigated. To localize Pf EMP1s, an α-ATS antibody directed against the conserved cytoplasmic ATS domain was used. Unfortunately, for unknown reasons, this antibody did not recognize Pf EMP1 presented on the surface of Pf IEs; however, Pf EMP1 localized in the Maurer's clefts can be detected. Interestingly, only partial colocalization (50-80%) of Pf EMP1 with SBP-1, the Maurer's clefts marker, was detectable. The VIR proteins PVX_068690 and PVX_077695 showed a 93-97% colocalization with the ATS domain of Pf EMP1s, both in the trophozoite and in the schizont stage. For almost all other VIR proteins, a colocalization between 20-55% (with one exception of 80%, PVX_081850) can be found (Figures 2, 3 and S3).

Binding Phenotype of Erythrocytes Infected with P. falciparum Transfectants Expressing Different vir Genes
The next step was to investigate whether the transfectants were able to cytoadhere to ECRs, in this case CD36 and ICAM-1. For the binding experiments, the 3D7 isolate used here to produce the transfectants was very well-suited as it has largely lost the ability to adhere to the ECRs through long-term cultivation. Thus, only an average of 4 and 0.15 3D7-Pf IE bound to 100 CD36-and ICAM-1-presenting CHO-745 cells, respectively ( Figure 4A,B). First, the binding experiments were performed with parasites that were in the trophozoite stage. Of the twelve transfectants examined, significant binding to CD36 was detected for five (PVX_050690, PVX_060690, PVX_068690, PVX_093715, and PVX_096925). Interestingly, parasites expressing PVX_050690, which encoded the only non-exported VIR protein, also showed binding to CD36. Only parasites expressing PVX_096925 showed significant binding to ICAM-1 ( Figure 4A). In the next step, it was investigated whether the observed binding phenotype was also detectable for Pf IEs in the schizont stage. Here, too, significant binding to CD36 could be detected for all five transfectants. However, none of the transfectants showed any more binding to ICAM-1 ( Figure 4B).

Transcriptome Analysis of Transfectants Showing Binding to CD36
Transcriptome analyses were performed to ensure the expression of the vir genes did not affect the gene expression of P. falciparum, especially the var genes. For this purpose, the expression profile of parasites in the ring stage was analyzed, as the var genes were expressed in this stage. It was striking that in all transfectants showing binding to CD36, the expression of at least one var gene was strongly increased. For the PVX_050690 3D7 transfectants, which synthesized the only non-exported VIR protein, an increase from 15 to 5750 normalized reads for the var gene PF3D7_0712600 was observed, followed by PF3D7_1255200 with an increase from 1.8 to 640 normalized reads. For PVX060690 3D7 , PF3D7_0712600 showed the largest increase, from 18 to 3340 normalized reads. The second highest increase was observed for var PF3D7_0900100, from 1 to 680 normalized reads. For PVX068690 3D7 , the strongest increases in expression were measured for two var C Microorganisms 2022, 10, 1183 9 of 17 family genes (PF3D7_0712600 and PF3D7_0712000, from 16 to 4050 and from 100 to 9200 normalized reads, respectively). In the PVX_093715 3D7 and PVX_096925 3D7 transfectants, only one var gene (PF3D7_0712600 (from 16 to 1440 normalized reads) and PF3D7_0632800 (from 8 to 3060 normalized reads), respectively) was expressed most strongly ( Figure 5, Tables S1-S10).

Figure 2.
Localization of VIR proteins (PVX_050690, PVX_060690, PVX_068690, PVX PVX_096925, PVX_077695, PVX_081850, PVX_097525, PVX_101560, PVX_107235, PVX_113 PVX_115475) in erythrocytes infected with P. falciparum 3D7 transfectants expressing th sponding vir genes. PfIEs were fixed with acetone, and VIR proteins were localized with αin the trophozoite stage and schizont stage PfIEs. Colocalization was performed with α-Sp ETRAMP, α-SBP-1, and α-ATS (green). The cell nuclei were stained with Hoechst-33342 (b also Figure S3. Interestingly, parasites expressing PVX_050690, which encoded the only non-exported VIR protein, also showed binding to CD36. Only parasites expressing PVX_096925 showed significant binding to ICAM-1 ( Figure 4A). In the next step, it was investigated whether the observed binding phenotype was also detectable for PfIEs in the schizont stage. Here, too, significant binding to CD36 could be detected for all five transfectants. However, none of the transfectants showed any more binding to ICAM-1 ( Figure 4B).

Transcriptome Analysis of Transfectants Showing Binding to CD36
Transcriptome analyses were performed to ensure the expression of the vir gen not affect the gene expression of P. falciparum, especially the var genes. For this pu the expression profile of parasites in the ring stage was analyzed, as the var genes expressed in this stage. It was striking that in all transfectants showing binding to C the expression of at least one var gene was strongly increased. For the PVX_050 transfectants, which synthesized the only non-exported VIR protein, an increase fr

Expression of PVX_108770 in P. falciparum and Characterization of Respective PVX_108770 3D7 Transfectants
To test whether the expression of the vir genes actually has an influence on the expression of the var genes and whether the observed cytoadhesion could thus be due to the correspondingly encoded PfEMP1s, PVX_108770 should be expressed, for which binding to ICAM-1 has been demonstrated [39]. PVX_108770 has a transmembrane domain, and like all other VIR proteins that have a putative transmembrane domain, this protein was detected mainly in Maurer's clefts ( Figure 6A,B). However, in about 30% of PfIEs, an association with the erythrocyte membrane was also found. It was striking that the export occurred relatively late, such that the PVX_108770 protein was mainly detectable in the parasite at the trophozoite stage and only to a small extent in Maurer's clefts ( Figure 6B).

Expression of PVX_108770 in P. falciparum and Characterization of Respective PVX_108770 3D7 Transfectants
To test whether the expression of the vir genes actually has an influence on the expression of the var genes and whether the observed cytoadhesion could thus be due to the correspondingly encoded Pf EMP1s, PVX_108770 should be expressed, for which binding to ICAM-1 has been demonstrated [39]. PVX_108770 has a transmembrane domain, and like all other VIR proteins that have a putative transmembrane domain, this protein was detected mainly in Maurer's clefts ( Figure 6A,B). However, in about 30% of Pf IEs, an association with the erythrocyte membrane was also found. It was striking that the export occurred relatively late, such that the PVX_108770 protein was mainly detectable in the parasite at the trophozoite stage and only to a small extent in Maurer's clefts ( Figure 6B). In contrast with the study mentioned above, Pf IE of the transfectant PVX_108770 3D7 did not bind to CD36 or ICAM-1 ( Figure 6C) [39]. However, the loss of cytoadhesion correlated with the results of the transcriptome analysis. Unlike the transfectants, for which binding mainly to CD36 was detected, no increase in expression of var genes could be detected ( Figure 6D, Tables S11 and S12).
Microorganisms 2022, 10, x FOR PEER REVIEW 12 of 17 not bind to CD36 or ICAM-1 ( Figure 6C) [39]. However, the loss of cytoadhesion correlated with the results of the transcriptome analysis. Unlike the transfectants, for which binding mainly to CD36 was detected, no increase in expression of var genes could be detected ( Figure 6D, Tables S11 and S12).

Discussion
Various studies have shown that PvIRs, just like PfIEs, also have the capacity for cytoadhesion, albeit to a lesser extent. Here, the ECR ICAM-1 appeared to be the most important binding partner. However, binding to CSA and hyaluronic acid (HA) has also been described [26][27][28][29]39]. However, it is not yet fully understood which proteins of P. vivax mediate this cytoadhesion. Among others, the members of the VIR protein family come into question. This family consists of about 300 proteins of different sizes and structures. There are members with and without transmembrane domains and with and without a signaling and/or a PEXEL motif. It can therefore be assumed the VIR proteins fulfil different functions [36][37][38][39]. In our study, the importance of the VIR proteins for the cytoadhesion of PvIR should be analyzed in detail.

Discussion
Various studies have shown that PvIRs, just like Pf IEs, also have the capacity for cytoadhesion, albeit to a lesser extent. Here, the ECR ICAM-1 appeared to be the most important binding partner. However, binding to CSA and hyaluronic acid (HA) has also been described [26][27][28][29]39]. However, it is not yet fully understood which proteins of P. vivax mediate this cytoadhesion. Among others, the members of the VIR protein family come into question. This family consists of about 300 proteins of different sizes and structures. There are members with and without transmembrane domains and with and without a signaling and/or a PEXEL motif. It can therefore be assumed the VIR proteins fulfil different functions [36][37][38][39]. In our study, the importance of the VIR proteins for the cytoadhesion of PvIR should be analyzed in detail.
Although progress continues to be made in developing an in vitro culture for P. vivax, only cultures with few replication cycles and very low parasitemia have been obtained, making continuous in vitro culture of P. vivax impossible to date [56]. An alternative for analyzing the function of P. vivax proteins is the heterologous expression of P. vivax genes in P. falciparum. For several P. vivax proteins, the subcellular localization and function could be investigated in this way. For example, overexpression of the pvcrt-o gene, which encodes the P. vivax vacuolar membrane transporter protein PvCRT-o, in the P. falciparum isolate 3D7 resulted in an approximately twofold increase in chloroquine resistance. Furthermore, PvCRT-o and Pf CRT were colocalized [57]. The episomal P. falciparum transfection system was also used to study the resistance of P. vivax to antifolates. For this purpose, the gene pvdhfr and various pvdhfr-derived mutants encoding the P. vivax dihydrofolate reductase (DHFR) were episomally expressed in an antifolate-sensitive P. falciparum line. In this way, the influence of sensitivity to different antifolate drugs could be investigated [58,59].
It was shown that the episomal P. falciparum transfection system is also suitable for the expression of vir genes and for the subsequent localization and functional analysis of the correspondingly encoded VIR proteins. For these analyses, Bernabeu and colleagues used the classical P. falciparum expression vector pARL, as in the study presented here [39]. This vector has been used in a number of studies, particularly for localization studies of P. falciparum proteins expressed as GFP-or HA-fusion proteins [60][61][62][63]. Based on the expression of vir genes in P. falciparum, three VIR proteins could be localized that have either no (PVX_112645), one (PVX_108770), or two (PVX_102635) putative transmembrane domains [39]. As suspected, PVX_112645 was not exported and was localized in the parasite. At the trophozoite stage, PVX_108770 was localized in the parasite near the parasitophorous vacuole membrane, while PVX_102635 was localized in the cytosol of the erythrocyte. At the schizont stage, both proteins could be detected at the erythrocyte membrane [39]. In addition to the three VIR proteins described above, our study aimed to identify additional VIR proteins that can act as ligands in binding to ECRs.
For the VIR protein PVX_050690, which like PVX_112646 has no transmembrane domain, no export of the protein into erythrocytes could be detected. In contrast with the study described above, all VIR proteins investigated in this study containing a transmembrane domain were localized during the trophozoite stage mainly within the parasite and also within Maurer's clefts. During the schizont stage, the localization of the VIR proteins shifted from the parasite to the Maurer's clefts. Furthermore, depending on the transfectant, an association with the erythrocyte membrane was observed in 0% to 49% of the Pf IEs examined. It is worth noting that the localization of PVX_108770 performed here differs in part from that mentioned above [39]. In both studies, the protein can be detected mainly in the parasite during the trophozoite stage. While Bernabeu et al. detected PVX_108770 at the schizont stage on the erythrocyte membrane, this was only the case in about 30% of the Pf EIs examined in this study. However, in almost all erythrocytes infected with PVX_108770 3D7 , the VIR protein was detectable in the parasite and in Maurer's clefts [39].
In five of the transfectants in this study, binding of Pf IEs to CD36 could be detected. However, there was no correlation with the membrane association of the respective VIR proteins. This was particularly striking in this context for PVX_050690. As already mentioned, PVX_050690 had no transmembrane domain and could only be localized in the parasite. Nevertheless, significant binding of the respective Pf IEs to CD36 could be detected in both the trophozoite and schizonts stages. Another striking feature was that in all transfectants showing binding to CD36, the expression of at least one var gene increased strongly compared with the control, with all correspondingly encoded Pf EMP1s belonging to the B or C family. PVX_108770 3D7 transfectants, on the other hand, showed no significant differences in the var gene expression profile compared with the control and, accordingly, no binding to the investigated receptors CD36 and ICAM-1.
In summary, the expression of certain vir genes (as shown here for PVX_050690, PVX_060690, PVX068690, PVX 093715, and PVX_096925) appears to influence the expression of some var genes by a hitherto unknown mechanism. It is therefore imperative, especially for functional analyses, e.g., with the help of mRNAseq, to exclude an influence of the heterologous expression of P. vivax genes in P. falciparum on the expression profile and/or metabolism of P. falciparum.