Maria Teresa Bejarano

A Molecular Link between Malaria and Epstein–Barr Virus Reactivation

Although malaria and Epstein–Barr (EBV) infection are recognized cofactors in the genesis of endemic Burkitt lymphoma (BL), their relative contribution is not understood. BL, the most common paediatric cancer in equatorial Africa, is a high-grade B cell lymphoma characterized by c-myc translocation. EBV is a ubiquitous B lymphotropic virus that persists in a latent state after primary infection, and in Africa, most children have sero-converted by 3 y of age. Malaria infection profoundly affects the B cell compartment, inducing polyclonal activation and hyper-gammaglobulinemia. We recently identified the cystein-rich inter-domain region 1α (CIDR1α) of the Plasmodium falciparum membrane protein 1 as a polyclonal B cell activator that preferentially activates the memory compartment, where EBV is known to persist. Here, we have addressed the mechanisms of interaction between CIDR1α and EBV in the context of B cells. We show that CIDR1α binds to the EBV-positive B cell line Akata and increases the number of cells switching to the viral lytic cycle as measured by green fluorescent protein (GFP) expression driven by a lytic promoter. The virus production in CIDR1α-exposed cultures was directly proportional to the number of GFP-positive Akata cells (lytic EBV) and to the increased expression of the EBV lytic promoter BZLF1. Furthermore, CIDR1α stimulated the production of EBV in peripheral blood mononuclear cells derived from healthy donors and children with BL. Our results suggest that P. falciparum antigens such as CIDR1α can directly induce EBV reactivation during malaria infection that may increase the risk of BL development for children living in malaria-endemic areas. To our knowledge, this is the first report to show that a microbial protein can drive a latently infected B cell into EBV replication.

Identification of a Polyclonal B-Cell Activator in Plasmodium falciparum

ABSTRACT Polyclonal B-cell activation and hypergammaglobulinemia are prominent features of human malaria. We report here that Plasmodium falciparum-infected erythrocytes directly adhere to and activate peripheral blood B cells from nonimmune donors. The infected erythrocytes employ the cysteine-rich interdomain region 1α (CIDR1α) of P. falciparum erythrocyte membrane protein 1 (PfEMP1) to interact with the B cells. Stimulation with recombinant CIDR1α induces proliferation, an increase in B-cell size, expression of activation molecules, and secretion of immunoglobulins (immunoglobulin M) and cytokines (tumor necrosis factor alpha and interleukin-6). Furthermore, CIDR1α binds to Fab and Fc fragments of human immunoglobulins and to immunoglobulins purified from the sera of different animal species. This binding pattern is similar to that of the polyclonal B-cell activator Staphylococcus aureus protein A. Our findings shed light on the understanding of the molecular basis of polyclonal B-cell activation during malaria infections. The results suggest that the var gene family encoding PfEMP1 has evolved not only to mediate the sequestration of infected erythrocytes but also to manipulate the immune system to enhance the survival of the parasite.

Large granular lymphocytes inhibit the in vitro growth of autologous Epstein-Barr virus-infected B cells.

The effect of lymphocyte subsets, separated on the basis of cell density, on Epstein-Barr virus (EBV)-induced B-cell proliferation was studied. The experiments were performed with lymphocytes of seropositive individuals. After 2 weeks of culture, the growth of B cells was inhibited by the T subset, which is also active in natural killer assays, i.e., the low-buoyant density lymphocyte fractions. However, if the cultures were observed for a longer time, the initial growth regressed even in cultures containing the subsets which did not have natural killing (NK) function, i.e., those with high cell density. The initial cell concentration at which the cultures were seeded determined the outcome of the experiments and the demonstration of inhibitory effects. An important difference was seen between the subsets with regard to radiosensitivity. The prompt inhibitory effect of the NK-positive subset remained after irradiation, while the function of the NK-negative one was abrogated. In the presence of the irradiated T-enriched total population, infected B cells (BEBV) grew. Consequently, the radiation-resistant effector compartment, represented by the low-density cells, was not sufficient to counteract the establishment of BEBV lines. They contributed, nevertheless, to the regression because the kinetics of B-cell growth were different in cultures containing separated high-density cells or the total population. In the former, growth continued for a longer time and complete regression occurred only in the cultures initiated with high cell concentrations. The experiments showed that two types of cells contribute to the regression of BEBV growth in cultures initiated with lymphocytes of seropositive donors. One acts promptly and is independent of cell proliferation; another is activated for proliferation by encounter with B blasts.

Increased B Cell Survival and Preferential Activation of the Memory Compartment by a Malaria Polyclonal B Cell Activator

Chronic malaria infection is characterized by polyclonal B cell activation, hyperglobulinemia, and elevated titers of autoantibodies. We have recently identified the cysteine-rich interdomain region 1α (CIDR1α) of the Plasmodium falciparum erythrocyte membrane protein 1 as a T cell-independent polyclonal B cell activator and Ig binding protein. Here, we show that, although the binding affinity of CIDR1α to human IgM and IgG is relatively low, B cell activation still proceeds. CIDR1α rescues tonsillar B cells from apoptosis, and increases the proportion of cycling cells. Comparison of the impact on naive and memory B cell compartment indicated that CIDR1α preferentially activates memory B lymphocytes. Analysis of the gene expression profiles induced by CIDR1α and anti-Ig activation using a cDNA microarray demonstrated a low degree of homology in the signatures imposed by both stimuli. The microarray data correlate with the functional analysis demonstrating that CIDR1α activates various immunological pathways and protects B cells from apoptosis. Together, the results provide evidence for a role of malaria in preferentially activating the memory B cell compartment. The polyclonal B cell activation and augmented survival induced by CIDR1α is of relevance for understanding the mechanisms behind the increased risk of Burkitt’s lymphoma in malaria endemic areas.

Clearance of Circulating Epstein-Barr Virus DNA in Children with Acute Malaria after Antimalaria Treatment

Children living in malaria-endemic regions have a high incidence of Burkitt lymphoma (BL), the etiology of which involves Plasmodium falciparum malaria and Epstein-Barr virus (EBV) infections. In the present study, we compared EBV DNA loads in plasma and saliva samples from Ugandan children with acute malaria (M+) at the time of diagnosis and 14 days after antimalaria treatment, children without malaria (M-), and children with BL. EBV DNA was detected, by real-time polymerase chain reaction, in 31% of the plasma and in 79% of the saliva samples from children in the M+ group. Antimalaria treatment led to clearance of plasma viral load in 85% of the cases but did not affect the levels in saliva. There was a significant difference in plasma EBV loads across the groups. The lowest levels were detected in samples from the M- group, increased levels were detected in samples from the M+ group, and levels reached the highest values in samples from children with BL. The same trend was evident in the frequency and levels of anti-BZLF1 antibodies, which is indicative of viral reactivation. In the M+ group, the positive plasma samples clustered around 7-9 years of age, the peak incidence of BL. The clearance of circulating EBV after antimalaria treatment suggests a direct relationship between active malaria infection and viral reactivation.

Endemic Burkitt's lymphoma as a polymicrobial disease New insights on the interaction between Plasmodium falciparum and Epstein―Barr virus

Despite the well-established relationship between endemic Plasmodium falciparum malaria and Epstein-Barr virus (EBV) infection in the genesis of endemic Burkitts lymphoma (eBL), very little research has examined the interaction between these two pathogens. eBL, the most prevalent childhood cancer in equatorial Africa where malaria is holoendemic, is a high-grade B cell lymphoma characterized by a c-myc translocation and the consistent presence of EBV. After primary infection, EBV establishes a life-long persistent infection characterized by virus shedding into saliva. African children are infected early in life and most have sero-converted by 3 years of age while sero-conversion tends to occur later in developed countries. Acute and chronic malaria infections profoundly affect the B cell compartment, inducing polyclonal activation, hyper-gammaglobulinemia and a dramatic increase in the levels of circulating EBV. In this review we present and discuss recent data suggesting a molecular link between the parasite, the B cell and EBV and provide evidence that adds to the concept of polymicrobial disease pathogenesis in eBL. Following the observation of EBV reactivation in children living in malaria endemic areas and its relationship with acute malaria infection, we identified the cystein-rich inter-domain region 1 alpha (CIDR1 alpha) of the Plasmodium falciparum membrane protein 1 as a polyclonal B cell activator. CIDR1 alpha increases B cell survival and preferentially activates the memory compartment where EBV is known to persist. Analysis of the mechanisms of interaction between CIDR1 alpha and EBV in the context of B cells demonstrated that CIDR1 alpha induces virus production in the EBV-infected B cell line Akata and in latently infected primary B cells derived from the peripheral blood of healthy carriers and children with eBL. This is the first demonstration that EBV can be reactivated directly by another pathogen. Our results suggest that P. falciparum antigens such as PfEMP1 can directly induce EBV reactivation during malaria infections. The increased viral load and the concomitant polyclonal B cell activation with enhanced B cell survival may augment the risk of eBL development in children living in malaria-endemic areas.

Optimized expression of Plasmodium falciparum erythrocyte membrane protein 1 domains in Escherichia coli

BackgroundThe expression of recombinant proteins in Escherichia coli is an important and frequently used tool within malaria research, however, this method remains problematic. High A/T versus C/G content and frequent lysine and arginine repeats in the Plasmodium falciparum genome are thought to be the main reason for early termination in the mRNA translation process. Therefore, the majority of P. falciparum derived recombinant proteins is expressed only as truncated forms or appears as insoluble inclusion bodies within the bacterial cells.MethodsSeveral domains of PfEMP1 genes obtained from different P. falciparum strains were expressed in E. coli as GST-fusion proteins. Expression was carried out under various culture conditions with a main focus on the time point of induction in relation to the bacterial growth stage.Results and conclusionsWhen expressed in E. coli recombinant proteins derived from P. falciparum sequences are often truncated and tend to aggregate what in turn leads to the formation of insoluble inclusion bodies. The analysis of various factors influencing the expression revealed that the time point of induction plays a key role in successful expression of A/T rich sequences into their native conformation. Contrary to recommended procedures, initiation of expression at post-log instead of mid-log growth phase generated significantly increased amounts of soluble protein of a high quality. Furthermore, these proteins were shown to be functionally active. Other factors such as temperature, pH, bacterial proteases or the codon optimization for E. coli had little or no effect on the quality of the recombinant protein, nevertheless, optimizing these factors might be beneficial for each individual construct. In conclusion, changing the timepoint of induction and conducting expression at the post-log stage where the bacteria have entered a decelerated growth phase, greatly facilitates and improves the expression of sequences containing rare codons.

TLRs innate immunereceptors and Plasmodium falciparum erythrocyte membrane protein 1 (PfEMP1) CIDR1α-driven human polyclonal B-cell activation.

Chronic malaria severely affects the immune system and causes polyclonal B-cell activation, as evidenced by the presence of hypergammaglobulinemia, elevated levels of autoantibodies, loss of B-cell memory and the frequent occurrence of Burkitts lymphomas (BL) in children living in malaria endemic areas. Previous studies have shown that the cysteine-rich interdomain region 1α (CIDR1α) of the Plasmodium falciparum erythrocyte membrane protein 1 (PfEMP1) of the FCR3S1.2 strain, subsequently named CIDR1α, interacts with B cells partially through the binding to the B-cell receptor (BCR). This interaction leads to an activated phenotype, increased survival, and a low degree of proliferation. CIDR1α preferentially activates the memory B-cell compartment, therefore PfEMP1 is considered to act as a polyclonal B-cell activator and its role in memory maintenance has been suggested. In this report, we extend the analysis of the PfEMP1-CIDR1α B-cell interaction and demonstrate that PfEMP1-CIDR1α increases the expression of TLR7 and TLR10 mRNA transcripts and sensitizes B cells to TLR9 signalling via the MyD88 adaptor molecule. Furthermore, despite its ability to bind to surface Igs, PfEMP1-CIDR1α-induced B-cell activation does not seem to proceed through the BCR, since it does not induce Lyn and/or phospho-tyrosine mediated signalling pathways. Rather PfEMP1-CIDR1α induces the phosphorylation of downstream kinases, such as ERK1/2, p38 and IKBα, in human B cells. These findings indicate that PfEMP1-CIDR1α induces a persistent activation of B cells, which in turn can contribute to the exhaustion and impairment of B-cell functions during chronic malaria infection.

Effect of Acute Plasmodium falciparum Malaria on Reactivation and Shedding of the Eight Human Herpes Viruses

Human herpes viruses (HHVs) are widely distributed pathogens. In immuno-competent individuals their clinical outcomes are generally benign but in immuno-compromised hosts, primary infection or extensive viral reactivation can lead to critical diseases. Plasmodium falciparum malaria profoundly affects the host immune system. In this retrospective study, we evaluated the direct effect of acute P. falciparum infection on reactivation and shedding of all known human herpes viruses (HSV-1, HSV-2, VZV, EBV, CMV, HHV-6, HHV-7, HHV-8). We monitored their presence by real time PCR in plasma and saliva of Ugandan children with malaria at the day of admission to the hospital (day-0) and 14 days later (after treatment), or in children with mild infections unrelated to malaria. For each child screened in this study, at least one type of HHV was detected in the saliva. HHV-7 and HHV-6 were detected in more than 70% of the samples and CMV in approximately half. HSV-1, HSV-2, VZV and HHV-8 were detected at lower frequency. During salivary shedding the highest mean viral load was observed for HSV-1 followed by EBV, HHV-7, HHV-6, CMV and HHV-8. After anti-malarial treatment the salivary HSV-1 levels were profoundly diminished or totally cleared. Similarly, four children with malaria had high levels of circulating EBV at day-0, levels that were cleared after anti-malarial treatment confirming the association between P. falciparum infection and EBV reactivation. This study shows that acute P. falciparum infection can contribute to EBV reactivation in the blood and HSV-1 reactivation in the oral cavity. Taken together our results call for further studies investigating the potential clinical implications of HHVs reactivation in children suffering from malaria.

Malaria A blueprint of ‘bad air’

Last year the sequence of chromosome 2 fromPlasmodium falciparum — the agent that causes malaria — was announced. Now, hot on its heels, comes the sequence of chromosome 3. Each chromosome is equivalent in size to an entire bacterial genome, and, although we still know only 7% of the total P. falciparum sequence, by comparing the two chromosomes we can learn much about how P. falciparumoutwits the immune system.