Abstract
Plasmodium falciparum has developed extensive mechanisms to evade host immune clearance. Currently, most of our understanding is based on in vitro studies of individual parasite variant surface antigens and how this relates to the processes in vivo is not well-understood. Here, we have used a humanized mouse model to identify parasite factors important for in vivo growth. We show that upregulation of the specific PfEMP1, VAR2CSA, provides the parasite with protection from macrophage phagocytosis and clearance in the humanized mice. Furthermore, parasites adapted to thrive in the humanized mice show reduced NK cell-mediated killing through interaction with the immune inhibitory receptor, LILRB1. Taken together, these findings reveal new insights into the molecular and cellular mechanisms that the parasite utilizes to coordinate immune escape in vivo. Identification and targeting of these specific parasite variant surface antigens crucial for immune evasion provides a unique approach for therapy.
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Introduction
Plasmodium falciparum is the most important causative agent of human malaria. Currently, annual malaria infections and mortality are approximately 220 million and 400,000, respectively1. During the erythrocytic stage of malaria infection, the parasite invades red blood cells (RBCs) and expresses variant surface antigens (VSAs) on the surface of the infected red blood cell (iRBC). These VSAs such as P. falciparum Erythrocyte Membrane Protein 1 (PfEMP1)2 and repetitive interspersed family of polypeptides (RIFINs)3 bind to host receptors and sequester to specific tissues and form rosettes to avoid clearance by the spleen. More recently, these multigenic and highly polymorphic VSAs, have been shown to play a role in evading recognition by the host innate immune system4.
Macrophages and natural killer (NK) cells are the earliest innate immune cells that respond to parasite infection5,6, and the outcome of this early host–parasite interaction is a strong determinant for immunopathology and disease severity7,8. However, parasites have developed mechanisms to inhibit macrophage phagocytosis9,10 and evade killing by NK cells4,8. Macrophages recognize and phagocytose parasite-infected red blood cells (iRBC) through the class B scavenger receptor, CD36, which binds to group B and C PfEMP1 expressed on the surface of iRBC11. Parasites isolated from patients with severe malaria exhibit reduced expression of PfEMP1 that binds to CD3612. A subset of RIFIN has also been shown to inhibit NK cell activation through leukocyte immunoglobulin-like receptor subfamily B member 1 (LILRB1)4. Despite this progress, the determinants that allow a parasite to evade macrophage and NK cell clearance and thrive in the human host have not been identified.
One of the main challenges of immunological studies of P. falciparum is the lack of a suitable model system that accurately emulates all the intricacies of the complex immune responses the human host develops in response to an infection. Current studies using in vitro cultured parasites are further hampered by the fact that through continuous in vitro culture, numerous parasitic adaptations have occurred, including the loss of parasitic virulence factors13,14,15,16. Noticeably, there is an overall downregulation of PfEMP117 and specific downregulation of the non-CD36-binding Group A var genes18. Interestingly, parasites isolated from patients with severe malaria expressed a higher level of group A var transcripts compared to parasites isolated from patients with non-severe malaria12. Similarly, expression of RIFIN as well as STEVOR, two additional families of variant surface antigens, are absent or expressed at a lower level in continuous in vitro cultured strains compared to parasites directly isolated from patients19,20
To gain a better understanding in the mechanisms the parasite utilizes to effectively survive in vivo, we characterized the changes that occur when in vitro cultured P. falciparum is adapted to grow in human RBC-reconstituted NOD/SCID IL2γnull (RBC-NSG) mice. In RBC-NSG mice, human RBCs support parasite infection in the presence of mouse macrophages as NSG mice are deficient in T, B, and natural killer (NK) cells. The system provides a reductionist in vivo environment to study the changes the parasites need to undergo to evade this first line of defense of the innate immune system. We show that in the presence of physical and immune stress, parasites upregulate the expression of specific var and rifs. Specifically, we identify that upregulation of VAR2CSA, a member of PfEMP1 that does not bind to CD36, appears to play a critical role in enabling parasites to escape from macrophage phagocytosis. These adapted parasites also demonstrated enhanced immune evasion of NK cell-mediated killing through the interaction with the immune suppressive receptor, LILRB1. Our findings reveal molecular and cellular mechanisms involved in parasite adaptation to immunological stress.
Results
Patent infection of RBC-NSG mice by P. falciparum requires a period of adaptation
To study P. falciparum adaptation to immunological and physical stresses in vivo, we infected RBC-NSG mice with an equal inoculum of six different P. falciparum strains that had been continuously cultured in vitro (Table 1). In all cases, no parasites were detected by Giemsa staining of peripheral blood smears until at least day 18 after the initial inoculation (Fig. 1a), consistent with a previous report21. By 35 days after the initial inoculation when parasitemia was apparent, blood was collected from the infected mice and used to infect human RBCs in vitro. After at least 20 cycles of in vitro culture and expansion, the recovered parasites were used to infect a new batch of RBC-NSG mice. No delay in parasitemia was observed this time around (Fig. 1a). Similarly, when whole blood, including iRBCs, was taken from RBC-NSG mice and used directly to infect a new batch of RBC-NSG mice, no delay in parasite growth was observed (black line in Fig. 1a). These results show that the parasites have undergone adaptation in the RBC-NSG mice and have acquired a phenotype that is competent in infecting the RBC-NSG mice and can be stably maintained in vitro culture for at least 20 cycles.
Since long-term continuous in vitro culture of P. falciparum leads to genetic heterogeneity22, we serially diluted the non-adapted 3D7 strain of P. falciparum to obtain a single clone, 3D7-B7, and repeated the adaptation experiment in RBC-NSG mice. Once again, there was a significant delay of 26 ± 5.1 days before 3D7-B7 was detected in the peripheral blood circulation of inoculated mice (Fig. 1b). Similarly, when the recovered parasites from RBC-NSG mice were cultured in vitro for 20 cycles and subsequently used to infect RBC-NSG mice, no delay in parasitemia was observed. Therefore, the observed parasite adaptation in RBC-NSG mice is not due to the selection of a single unique parasite from a genetically heterogeneous culture. Parasites recovered from RBC-NSG mice after adaptation are referred to as adapted strains (AS).
Adaptation of P. falciparum parasites is associated with transcriptional changes of specific variant surface antigens
To understand the changes contributing to the adaptation phenotype, we determined the genetic differences between three non-adapted and adapted parasites (3D7-B7, 3D7attB, and NF54attB) by whole genome sequencing23. Single nucleotide polymorphism (SNP) variant calling identified similar SNPs in both the parental non-adapted strains and their corresponding adapted strains and no conserved unique SNP was detected among the three adapted strains. Kinship coefficient analysis24 of the SNPs called for each parasite strain pair did not significantly diverge and had high kinship coefficient values (>0.487, Fig. 2a). Since kinship coefficient values of above 0.354 corresponds to duplicate or monozygotic twins25, our results suggest that adaptation is not due to the acquisition of a unique mutation(s).
We next examined whether transcriptional changes could be responsible for the adaptation phenotype by comparing the gene expression profile of three pairs of non-adapted and adapted P. falciparum strains (3D7-B7, 3D7attB, and NF54CR) using microarray analysis26. We included NF54CR, a strain of NF54attB parasites stably expressing Cas9 and T7 RNA polymerase27, as it was used for later studies. Cultures of infected RBCs were tightly synchronized and RNA was harvested every 8 h across the intraerythrocytic development cycle (IDC) to generate six time points per parasite strain. Significance Analysis of Microarray (SAM)28 of the 3 pairs of non-adapted and adapted parasite strains using a delta of 0.55 showed that 27 genes and 93 genes were significantly upregulated and downregulated, respectively (Fig. 2b and Supplementary Fig. 1). Using a false discovery rate (FDR) of 0.01, we further refined these genes to derive a list of differentially expressed genes (DEG), of which 14 were upregulated and 36 were downregulated (Fig. 2c and Tables 2 and 3). Gene Ontology (GO)29,30 biological processes analysis31 revealed that the DEGs are involved in processes such as modulation of erythrocyte aggregation, antigenic variation, and cytoadherence to microvasculature (Fig. 2d). Many of the DEGs were parasite variant surface antigens, including one var gene and 3 rif genes that were upregulated and 4 var genes, 5 rif genes, 4 stevor genes and 1 surf gene that were downregulated (Fig. 2c and Tables 2 and 3).
To understand the transcriptional differences of VSAs, we further analyzed the time-course expression of the differentially expressed var, rif and stevor. In non-adapted parasites, the var genes with highest expression differed from each other (PF3D7_1240900 in 3D7-B7, PF3D7_0412400 in 3D7attB, and PF3D7_0420700 in NF54CR) (Table 4), consistent with a previous report17. These three var genes belongs to groups B or C var genes and are known to interact with CD36. In contrast, in all three adapted strains, the same var gene PF3D7_1200600 (var2csa) was the most highly expressed (Table 4 and Supplementary Fig. 1a). Var2csa belongs to group E PfEMP1 and does not interact with CD3632. Furthermore, 4 var genes that belong to group C33 were significantly downregulated in adapted parasites (Supplementary Fig. 1). Overall, the expression of these differentially expressed var genes followed a temporal profile where the transcripts level peaked at 16 h post infection (hpi), and then dipped to a minimum at 40 hpi (Fig. 3a–c, Supplementary Fig. 1b–f), in agreement with previous observations34.
We performed qRT-PCR analysis of the var gene expression35 of in vitro cultured non-adapted 3D7 parasites, adapted 3D7 parasites that were obtained directly from infected RBC-NSG mice, and the adapted parasites that were cultured in vitro for 2 weeks (Supplementary Table 1). Results from the qPCR analysis recapitulates the microarray analysis that non-adapted parasites primarily expressed var group B and C genes. Adapted parasites that were freshly isolated from RBC-NSG mice showed high var2csa expression (Supplementary Fig. 1g). After culturing for 2 weeks in vitro, non-adapted parasites still showed var group B and C gene expression with negligible var2csa expression whereas adapted parasites maintained high var2csa expression. We also stained non-adapted and adapted 3D7 parasites with the well-characterized anti-VAR2CSA antibody, PAM1.436 followed by flow cytometry (Supplementary Fig. 7). As shown in Fig. 2e, about 25% of the adapted parasites stained positive whereas only background level of non-adapted parasites was positive.
Among the rif VSA family, 3 type A rif were significantly upregulated while 2 were significantly downregulated (Supplementary Fig. 2a). Three type B rif were also significantly downregulated (Supplementary Fig. 2b)37. Unlike the var genes which exhibited a defined maximum and minimum peak of expression, no such temporal pattern was observed for rif genes (Fig. 3d, e and Supplementary Fig. 2c–j), consistent with previous observations38. In addition, 4 stevor genes were significantly downregulated in adapted parasites (Supplementary Fig. 3a–e). Like the rif genes, the stevor genes were continually expressed throughout the IDC with no visible maximal and minimal peak. Taken together, these results show that adaptation is associated with changes in a relatively small number of genes, many of which are the parasite variant surface antigens (VSAs).
Surface expression of VAS2CSA is required for in vivo adaptation through macrophage evasion
To determine the roles of identified DEGs in adaptation of parasites in RBC-NSG mice, we adapted the in vitro conditional knockdown TetR-DOZI aptamer system for in vivo regulation of P. falciparum genes39. To validate this approach, 3D7attB AS parasites were transfected with the pMG56 plasmid encoding the firefly luciferase (FLuc) under the translational control of the TetR-DOZI RNA aptamer system, as well as attP sites for Bxb1 integrase-mediated recombination (Supplementary Fig. 4a), to generate 3D7attB AS pMG56 parasites. Human RBCs were infected with 3D7attB AS pMG56 parasites, serially diluted, and incubated with luciferin with or without aTc. A luminescent signal was readily detected when 5×106 iRBCs were used (Supplementary Fig. 4b). 3D7attB AS pMG56 parasites were used to infect RBC-NSG mice. When parasitemia in infected mice reached 5%, in vivo bioluminescent imaging was performed. Approximately ten-fold higher luminescent signal was detected in aTc treated mice (4.7 ± 2.1 ×106 p/s) than in mice without aTc treatment (0.41 ± 0.03 ×106 p/s) or uninfected RBC-NSG given aTc (0.44 ± 0.04 × 106 p/s (Fig. 4a). These results show that the TetR-DOZI RNA aptamer system can be utilized to regulate the expression of P. falciparum proteins in RBC-NSG mice.
To investigate further the biological implication of var2csa upregulation in parasite adaptation in RBC-NSG mice, we attempted to target the TetR-DOZI RNA aptamer system into the var2csa locus. This approach failed probably because of the high homology among var genes at the 3’ ATS segment. Therefore, we used an alternative approach by taking advantage of the fact that members of the PfEMP1 undergo allelic exclusive expression40. We tagged membrane-associated histidine rich protein 1 (MAHRP1, PF3D7_1370300), which is required for PfEMP1 surface expression but not required for export of STEVOR and other parasite proteins to the erythrocyte surface41,42, with the TetR-DOZI system to obtain NF54CR AS mahrp1 conditional knockdown parasites (Supplementary Fig. 4c). Expression of MAHRP1 was reduced by about 95% in NF54CR AS mahrp1 in the absence of aTc as compared to the presence of aTc (Fig. 4b). Immunofluorescence analyses revealed punctate staining pattern of PfEMP1 close to the surface of the erythrocyte membrane in the presence of aTc (Fig. 4c) but a more diffuse staining in the absence of aTc, consistent with an accumulation of PfEMP1 within the parasite plasma membrane, in agreement with previous report41. No growth defects in these parasites were observed in continuous culture. Mice were infected with NF54CR AS mahrp1 parasites that had been cultured in the presence of aTc. An initial parasitemia was observed in all infected mice on day 2, which continued to increase in mice that were given aTC (Fig. 4d). In contrast, parasitemia in mice without aTc treatment did not increase and eventually reduced to background level. These results suggest that adapted parasites require surface expression of VAR2CSA in order to survive and multiply in RBC-NSG mice.
To investigate the cellular mechanisms involved in VAR2CSA-mediated adaptation, we co-cultured NF54CR, NF54CR AS, and NF54CR AS mahrp1 parasites with human monocyte-derived macrophages (MDM) (Supplementary Fig. 8). A phagocytosis rate of 31.9 ± 1.6% was observed for non-adapted NF54CR parasites as compared to 19.8 ± 2.5% with NF54CR AS parasites (Fig. 4e). In the presence of aTc, the phagocytosis rate of NF54CR AS mahrp1 was 17.0 ± 1.1%, which was not significantly different from NF54CR AS parasites. However, in the absence of aTc, the phagocytosis rate was significantly increased to 24.2 ± 1.2% (Fig. 4e). Similarly, when murine macrophage cell line RAW 264.7 was used for phagocytosis assay, phagocytosis of the adapted parasites was significantly less than the non-adapted parasites (Supplementary Fig. 5). Consistently, anti-CD36 antibody blocked phagocytosis of non-adapted parasites but not the adapted parasites by human monocyte-derived macrophages (Supplementary Fig. 6). These results suggest that adapted parasites can evade macrophage phagocytosis, probably in part due to selective expression of VAR2CSA that does not bind to CD3610.
To further verify the involvement of macrophages in the adaptation of P. falciparum parasites, we depleted macrophages in RBC-NSG mice with clodronate liposome43. After 2 rounds of treatment, the percentage of F4/80hi CD11bint macrophages in the splenic CD45+ population was reduced from 19.9 ± 2.7% to 6.1 ± 2.9% (Fig. 4f and Supplementary Fig. 9). The chlodronate-treated mice were infected with non-adapted 3D7 parasites and given chlodronate liposome every 2 days for the duration of the experiment. In clodronate-treated mice, parasitemia rose to 4.1 ± 2.3% by day 5 while in the untreated mice, no parasites were detectable after day 1 (Fig. 4g). Thus, macrophages are a critical immune cell type that parasites must evade during adaptation in RBC-NSG mice.
Upregulation of immune-modulating RIFINs in adapted parasites leads to decreased NK cell killing but does not affect macrophage phagocytosis
We and others have shown that human NK cells can respond to infected RBC directly, although the response is heterogenous among the human population6,8. To determine if adapted parasites can resist NK cell-mediated elimination, we screened for and used human donor NK cells that can respond to iRBC. Non-adapted 3D7 or adapted 3D7 AS parasites were co-cultured with NK cells purified from human peripheral blood (Supplementary Fig. 10). While NK cells were able to reduce 3D7 parasitemia by 67.5 ± 3.2%, this reduction was significantly lowered to 44.3 ± 2.5% for 3D7 AS (Fig. 5a), demonstrating that adapted parasites were able to evade NK cell killing in vitro.
One of the significantly upregulated rif gene in our microarray analysis was PF3D7_1254800 (Fig. 3e, f), which had been shown to bind LILRB1-Fc fusion protein and inhibit NK cell activation4. To determine if parasites evade NK cells through LILRB1, we repeated the co-culture of NK cells with either 3D7 or 3D7 AS parasites in the presence of an anti-LILRB1 neutralizing antibody or an isotype control antibody. As shown in Fig. 5b, when NK cells were treated with anti-LILRB1 neutralizing antibody, the parasitemia reduction difference between 3D7 and 3D7 AS was abrogated (63.9 ± 4.7% vs 54.5% ± 3.8). Similarly, when compared to isotype control, the presence of the anti-LILRB1 neutralizing antibody enhanced 3D7 AS parasite elimination by NK cells from 39.7 ± 1.7% to 54.5 ± 3.8%.
We have utilized a selection-linked integration (SLI) approach44 to select for non-adapted 3D7 parasites that expressed PF3D7_1254800 (3D7-SLI-RIFIN) and verified its role in modulating NK cell-mediated killing45. To evaluate whether PF3D7_1254800 also plays a role in reducing phagocytosis by macrophages we utilized the 3D7-SLI-RIFIN along with a parasite line that expressed the SLI tagged var gene (PF3D7_0421300) to produce 3D7-SLI-PfEMP1 parasites. Macrophage phagocytosis of the non-adapted 3D7 parasites (30.3 ± 2.6%), 3D7-SLI-RIFIN (27.6 ± 3.5%), and 3D7-SLI-PfEMP1 (25.9 ± 0.7%) was similar, whereas phagocytosis of 3D7 AS (17.3 ± 1.9%) was significantly reduced (Fig. 5c). These results show that the adapted parasites evade NK cell killing through interaction with LILRB1. However, upregulation of RIFIN PF3D7_1254800 does not reduce macrophage phagocytosis of non-adapted parasites.
Discussion
Over the course of co-evolution with its human host, P. falciparum has developed a repertoire of mechanisms to evade the host immune clearance. One such mechanism is the switching of its surface-exposed VSA, especially VSAs belonging to the var family46. Expression of var in freshly isolated parasites from patients was observed to be highly coordinated, with a single dominant var gene being expressed at any time47. However, such coordination is lost during continuous in vitro culture, resulting in a random non-coordinated expression of var genes48, possibly due to the lack of selective pressure by the host immune system. The overall expression of var genes are also downregulated17. Here, we report that in vivo adaptation of parasites resulted in unique phenotypic and transcriptomic changes in the malaria parasite. Notably, there was an almost four-fold upregulation of the var2csa in adapted parasites, coupled with the downregulation of four CD36-binding Group C var genes18.
Var2csa is one of three vars that are conserved across the different P. falciparum strains49. VAR2CSA is the only member of the group E PfEMP150 and binds chondroitin sulfate A (CSA) but not CD3650 and has been implicated in pregnancy-associated malaria due to this characteristic51. However, recent controlled human malaria infection trials have shown that VAR2CSA is expressed in non-pregnant volunteers as well52. This suggests that VAR2CSA expression could have another function apart from binding to CSA found in the placenta53. Studies have also shown that parasites isolated from patients with severe malaria express high levels of group A PfEMP1 that do not bind CD3612,35, suggesting the role of avoiding recognition by CD36 is a mechanism of parasite evasion of macrophage phagocytosis. We have now demonstrated this mechanism of action beyond the previous correlation. Parasites that successfully adapted to grow in RBC-NSG mice expressed VAR2CSA and VAR2CSA-expressing adapted parasites were resistant to macrophage phagocytosis in vitro. When surface expression of VAR2CSA was inhibited, adapted parasites were efficiently phagocytosed by macrophages in vitro and did not induce patent infection in RBC-NSG mice. We speculate that in the absence of PfEMP1 surface expression, the decreased expression of CD47 in late-stage iRBC compared to uninfected or ring-stage parasites makes them susceptible to phagocytosis as shown in previous work54. Downregulation of VAR2CSA on the iRBC in the inducible mharp1 knockdown would then expose the infected erythrocyte to CD47-mediated phagocytosis. Conversely, when macrophages were depleted, non-adapted parasites could immediately flourish in RBC-NSG mice. Together, these results demonstrate that the expression of PfEMP1, such as VAR2CSA, that does not bind to CD36, is a mechanism by which parasites evade macrophages in order to establish robust infection in vivo.
RIFINs also showed differential expression during the adaptation process. The type A RIFINs are localized to the iRBC membrane and might be surface-exposed, while type B RIFINs remain inside the infected RBC37,55. We found that all upregulated rif genes are type A, while three out of five downregulated rif are type B. Differential expression between type A and type B RIFINs were also seen in a controlled human malaria infection trial of 4 volunteers where expression of type A RIFINs were upregulated in all volunteers whereas type B RIFINs showed no general changes56 when compared to in vitro cultured parasites. This suggest that in the RBC-NSG mice and human infection, type A RIFINs are upregulated and expressed as compared to in vitro cultured parasites. Recently, type A RIFINs were shown to bind to inhibitory immune receptors such as LILRB1, LILRB2 and LAIR1 to evade NK and B cell recognition4,57,58. Here, we demonstrate that parasites adapted in the RBC-NSG mice show reduced NK cell killing in vitro and upon blocking of LILRB1 receptor with a neutralizing antibody, NK cell killing of the adapted parasite is restored, suggesting the possibility that evasion of NK cell killing by RBC-NSG mice adapted parasites involves RIFINs that are recognized by LILRB1. Notably, our RBC-NSG mice do not have NK, T or B cells, raising the question what is selecting the expression of RIFINs by adapted parasites. In our study, we show that adapted parasites are resistant to elimination by NK cells in vitro and this resistance is abolished when LILRB1 is blocked by antibody. We also showed that elevated expression of PF3D7_1254800 or PF3D7_0421300 does not inhibit macrophage phagocytosis of non-adapted parasites in vitro. Our results leaves open the possibility that in vivo selection of adapted parasites with increased RIFIN expression in the RBC-NSG mice could still be mediated by macrophages as LILRB1 is predominantly expressed by monocytic lineage cells, NK cells and B cells. Additional studies are required to resolve this issue.
In conclusion, we show that significant changes in transcription occur during parasite adaptation in RBC-NSG mice. These changes are not random but specifically, happen to genes involved in immune evasion. In particular, a single var known to be involved in repressing macrophage phagocytosis and a small set of rif important to escape NK cell killing was repeatedly upregulated in multiple adapted parasites, suggesting immune evasion during adaptation. As an escape from clearance by the innate immune system is particularly important early on during the establishment of the blood-stage infection when parasite numbers are still relatively small, identification of specific var and rif that are important during parasite adaptation provide insights into the mechanism of host immune evasion and may lead to improved intervention strategies.
Methods
P. falciparum strains and culturing
P. falciparum blood-stage parasites were cultured in 2.5% hematocrit human RBC in malaria culture media (MCM) comprising of 10.43 g RPMI 1640 powder (Gibco), 25 ml 1 M HEPES (Gibco), 2 g NaHCO3 (Sigma-Aldrich), 5 g Albumax (Gibco), 0.05 g hypoxanthine (Sigma-Aldrich) and 25 mg gentamicin (Gibco) in 1 L milli-Q water. Cultures were incubated in Heracell 150 incubator (Thermo Scientific) at 37 °C in 5% CO2, 3% O2, and 92% N2.
NF54CR (NF54Cas9+T7 Polymerase)27 parasites were kindly shared with us by Prof. Jacquin Niles. Other parasite lines used were obtained from BEI Resources (Table 1).
Primary cells
Whole blood was donated by healthy non-malarial immune adult volunteers at the National University Hospital of Singapore Blood Donation Center. Informed consent was obtained from all donors in accordance with approved protocol and guidelines. Project ethics and approval were obtained from the Institutional Review Board of National University of Singapore (NUS-IRB 10–285). Whole venous blood was collected in Citrate-Phosphate Dextrose-Adenine-1 (CPDA-1, JMS) and PBMC were isolated from whole blood over Ficoll-Paque PLUS (GE Healthcare) density gradient. Pelleted RBC were washed twice in RPMI 1640 (Sigma-Aldrich) and stored 1:1 in MCM. Remaining RBCs within the PBMC fraction were lysed with ACK lysis buffer (Life Technologies) and purified PBMC were washed twice with RPMI 1640. PBMCs were counted and cryopreserved at a concentration of 1 × 108 cells/ml in 1:1 RPMI and PBMC freezing medium of 85% fetal bovine serum (Gibco) and 15% dimethyl sulfoxide (Sigma-Aldrich) in liquid nitrogen.
Mice
NOD/SCID IL2γnull (NSG) mice were approved by the institutional animal care and use committee (IACUC) of National University of Singapore (NUS), Agency of Science, Technology and Research (A*STAR) and Massachusetts Institute of Technology (MIT). Mice used were female and between 6 and 10 weeks of age. Mice were housed at an ambient temperature of between 19 °C to 24 °C and humidity levels of 30% to 70% in a 12-hour light–dark cycle. Mice also had ad libitum access to food and water.
Plasmids
Plasmids pMG5639 and pSN054 were kindly shared by professor Jacquin Niles for the generation of 3D7attb pMG56 and NF54CR AS mahrp1 parasites, respectively.
In vivo infection
6–10 week-old female NSG mice were injected daily with 1 ml of RBC mixture (50% human RBC, 25% RPMI, 25% human AB serum) intraperitoneally to generate RBC-NSG mice59. Human RBC reconstitution was assessed every other day by determining CD235ab levels via flow cytometry. Mice with reconstitution levels above 20% were infected with 1 ×107 mixed stage P. falciparum intravenously. Peripheral blood parasitemia was determined via Giemsa staining. Upon detection of parasitemia, mice were bled and adapted parasites were recovered.
For macrophage depletion, RBC-NSG mice were treated with 25 µl of Clodrosome® Liposomal Clodronate (5 mg/ml) (Encapsula NanoSciences LLC) intraperitoneally on day −6, day −4, and day −2 before infection with P.falciparum at day 0.
In vivo imaging was performed using an IVIS® Spectrum (PerkinElmer) on mice injected with RediJect D-Luciferin Bioluminescent Substrate (PerkinElmer) at 100 µl via intraperitoneal injection. Data was analyzed on LivingImage 3.2 (PerkinElmer).
Whole-genome sequencing
P. falciparum genomic DNA was isolated using NucleoSpin® Blood Columns (Macherey-Nagel) as per manufacturer’s protocol. Whole-genome next-generation sequencing of adapted and non-adapted P. falciparum was performed at Singapore Centre for Environmental Life Sciences Engineering Sequencing Core using Illumina Miseq Run V3. FASTQ files of sequencing reads were aligned to the P. falciparum 3D7 reference genome available, at PlasmoDB, using bowtie2 v2.3.2. SAM file generated from the alignment was converted to BAM files using samtools v1.3. SNP variant calling on the BAM files was done using freebayes v1.0.1 and SNP filtering based on QUAL using vcffilter.
Transcriptional microarray analysis
Microarray analysis was performed as described previously34. Briefly, P. falciparum RNA was isolated using TRIzol reagent (Invitrogen) as per the manufacturer’s protocol. RNA integrity was determined using 2100 Bioanalyzer with RNA 6000 Nano chips (Agilent). cDNA was synthesized using a combination of SMARTer PCR cDNA Synthesis Kit (Takara) and SuperScript II Reverse Transcriptase (ThermoFisher). cDNA was then amplified in the presence of 0.225 mM amino-allyl-dUTP (Biotium) using Taq DNA polymerase (New England Biolabs). PCR products were purified with MinElute PCR purification kit (Qiagen) according to the manufacturer’s protocol and eluted in 16 µl of elution buffer. The reference pool was created by adding equal amounts of RNA from each time point from the non-adapted strain.
4 µg of amplified DNA samples were labeled with Cy3 or Cy5 (GE Healthcare). Experimental samples were labeled with Cy5 while reference pools were labeled with Cy3. Cy5-labeled and Cy3-labeled reference pool were mixed and hybridized on post-processed microarray chips using the Agilent hybridization system (Agilent) and scanned using PowerScannerTM (Tecan). Scanned images were analyzed using GenePix Pro 6.0 (Axon Instruments). Microarray data was LOESS normalized and filtered for signal intensity over the background noise using R package LIMMA v3.3060. Differentially expressed genes were determined using Significance Analysis of Microarray (SAM)28.
Peripheral blood mononuclear cell (PBMC) purification
PBMCs were isolated using Ficoll-Paque PLUS (GE Healthcare) as per manufacturer protocol. NK cells and monocytes were isolated from purified PBMCs using EasySep™ Human NK Cell Isolation Kit and EasySep™ Human Monocyte Isolation Kit (STEMCELL), respectively.
Phagocytosis assay
Monocyte-derived macrophages were obtained by culturing purified monocytes in RPMI 10% FBS for 7 days. Non-adherent cells are removed. Phagocytosis assay was performed by incubating DAPI-treated trophozoites at a ratio of 5 iRBCs to 1 macrophage for 90 mins. Thereafter, the co-culture was washed in PBS to remove excess iRBCs. Macrophages were detached using Accutase (StemCell Technologies), stained with anti-human CD14 (Clone 63D3; Biolegend, 1:100 dilution), and quantified using Attune NxT (Life Technologies) and analyzed using Flowjo v10. Percentage phagocytosis is calculated as the percentage of DAPI-positive macrophages.
Primary NK cell parasitemia reduction co-culture
Primary NK cells were co-cultured with trophozoites at a parasitemia of 0.5% and at a ratio of 1 iRBCs to 10 NK cells for 96 h. Quantification of parasitemia was done by flow cytometry by staining for NK cells with anti-human CD45 (Clone 2D1; Biolegend; 1:100 dilution) and anti-human CD56 (Clone MEM-188; Biolegend; 1:100 dilution)6. Parasitemia reduction was calculated as \(\% \,{Parasitemia}\,{reduction}=\,\frac{{{Parasitemia}}_{{no\; NK}}-{{Parasitemia}}_{{NK}}}{{{Parasitemia}}_{{no\; NK}}}\times 100\). Neutralization of LILRB1 was performed with anti-LILRB1 antibody (500 ng/ml, R&D Systems, MAB20172).
Immunofluorescence assay (IFA)
Smears of late-stage parasite cultures were prepared on glass slides and methanol fixed on ice for 15 mins and air-dried. Smears were blocked in 3% bovine serum albumin (BSA; Sigma-Aldrich). Slides were incubated with primary rat anti-HA (Roche) at 1:100 and primary mouse anti-PfEMP1 ATS at 1:500 overnight. After three rounds of washing, slides were incubated with secondary goat anti-rat IgG (H + L) Alexa Fluor 488 (1:500; Invitrogen) and goat anti-mouse IgG (H + L) Alexa Fluor 647 (1:500; Invitrogen) with Hoechst 33342 (1:1000) for 1 hour at room temperature. The slides were then mounted in VECTASHIELD® Antifade mounting media (Vector Laboratories), imaged on LSM710 confocal microscope (Carl Zeiss), and analyzed on ZEN 2 (Carl Zeiss).
Western blotting
Late trophozoite parasites cultured with or without aTc were isolated using a 65% Percoll gradient. Recovered parasites were resuspended in Laemmli Sample Buffer (Bio-rad) and β-mercaptoethanol (Sigma-Aldrich) and loaded on a 10% Mini-PROTEAN® TGX™ Precast Protein Gel. Samples were transferred to 0.2 μm polyvinylidene difluoride (PVDF) membrane using Trans-Blot Turbo Transfer System (Bio-Rad). The membrane was blocked in 5% skim milk in 0.1% PBS-Tween (PBS-T) for 1 h at room temperature and incubated overnight with rat anti-HA tag (Roche) and mouse anti-Actin (Invitrogen) at 1:3000 in 2% Bovine Serum Albumin (BSA). The blot was then washed 3 times in PBS-T and probed with goat anti-rat HRP (Biolegend) and goat anti-mouse HRP (Biolegend) at 1:10,000 in 2% BSA PBS-T for 1 h at room temperature. The blot was imaged on ChemiDoc MP (Bio-Rad) in Clarity Max Western ECL Substrate (Bio-Rad). Western blot analysis was done using Image Lab v6.0 (Bio-Rad).
Quantitative real-time PCR
Total RNA was extracted from highly synchronized ring-stage parasites (18hpi) using TRIzol Reagent (Invitrogen) according to manufacturer’s protocol. Complementary DNA was synthesized with SuperScript ll Reverse transcriptase (Invitrogen) using a mix of Oligo(dT)12–18 and random primers. Quantitative real-time PCR was performed with Luna® Universal qPCR Master Mix (NEB) using primer pairs for var gene subgroups35.
Quantification and statistical analysis
Data are presented as the mean and standard error of the mean (SEM). Differences between paired samples were analyzed using a paired two-tailed t test, while unpaired samples were analyzed with Student’s t test. Multiple comparison tests were performed using Tukey’s multiple comparison test. A p value of < 0.05 was considered statistically significant. All calculations were performed using the GraphPad 7 software package.
Reporting summary
Further information on research design is available in the Nature Research Reporting Summary linked to this article.
Data availability
Microarray raw data are deposited in the ArrayExpress database under the accession number E-MTAB-11764. DNA sequencing raw data are deposited in the NCBI Sequence Read Archive database under the accession numbers SAMN28580495, SAMN28580496, SAMN28580497, SAMN28580498, SAMN28580499, SAMN28580500 [https://www.ncbi.nlm.nih.gov/sra/PRJNA841277]. The main data that support the findings of this study are provided within the Article and Supplementary Information. Source data are provided with this paper.
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Acknowledgements
We thank Lan Hiong Wong and Donald Tay for their technical assistance, Farzad Olfat for administrative support and Neslihan Kaya for bioinformatics analysis as well as Professor Lars Hviid for kindly sharing with us the PAM1.4 antibody. This work was supported by the National Research Foundation of Singapore through the Singapore–MIT Alliance for Research and Technology’s (SMART) Interdisciplinary Research Groups in Infectious Disease and Antimicrobial Resistance Research Program and the Singapore Ministry of Health’s National Medical Research Council under its Cooperative Basic Research Grant (NMRC/CBRG/0040/2013) and Open Fund Individual Research Grant (NMRC/OFIRG/0058/2017). M.C. and W.Y. were supported by the SMART graduate fellowship while R.I.O. was supported by a SINGA graduate fellowship.
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M.C., W.Y., P.P., and J.C. designed the research and interpreted the data. M.C., C.F.P., and J.C.N. designed and performed the Tet-R aptamer and CRISPR editing in adapted P. falciparum experiments. M.C., W.Y., and R.H. performed and analyzed the microarray data. M.C., W.Y., and R.I.O. performed the macrophage phagocytosis assay, NK cell killing assay and qPCR quantification of PfEMP1 experiments. M.C., W.Y., Q.C., J.C., and P.P. designed and performed the huRBC-NSG mouse model experiments and analyzed the data. M.C. and W.Y. performed all other experiments. M.C., W.Y., J.C., and P.P. wrote the manuscript. J.C., and P.P. supervised the work.
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Chew, M., Ye, W., Omelianczyk, R.I. et al. Selective expression of variant surface antigens enables Plasmodium falciparum to evade immune clearance in vivo. Nat Commun 13, 4067 (2022). https://doi.org/10.1038/s41467-022-31741-2
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DOI: https://doi.org/10.1038/s41467-022-31741-2
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