Structure of the immunodominant surface antigen from the Toxoplasma gondii SRS superfamily

Toxoplasma gondii is a persistent protozoan parasite capable of infecting almost any warm-blooded vertebrate. The surface of Toxoplasma is coated with a family of developmentally regulated glycosylphosphatidylinositol (GPI)-linked proteins (SRSs), of which SAG1 is the prototypic member. SRS proteins mediate attachment to host cells and interface with the host immune response to regulate the virulence of the parasite. The 1.7 A structure of the immunodominant SAG1 antigen reveals a homodimeric configuration in which the dimeric interface is mediated by an extended beta-sheet that forms a deep groove lined with positively charged amino acids. This basic groove seems to be conserved among SRS proteins and potentially serves as a sulfated proteoglycan-binding site on target cell surfaces, thus rationalizing the promiscuous attachment properties of Toxoplasma to a broad range of host cell types.     

Identification of a sporozoite-specific member of the Toxoplasma SAG superfamily via genetic complementation

Toxoplasma gondii sporozoites possess an array of stage-specific antigens that are localized to the membrane and internal cellular space, as well as secreted into the primary parasitophorous vacuole. Specific labelling of viable sporozoites excysted from oocysts reveals a complex admixture of surface proteins partially shared with tachyzoites. SAG1, SRS3 and SAG3 were detected on sporozoites as well as numerous minor antigens. In contrast, tachyzoite SAG2A and B were completely absent whereas a dominant 25 kDa protein was unique to the sporozoite surface. The sporozoite gene encoding this protein was identified in tachyzoites genetically complemented with a sporozoite cDNA library and cloned via site-specific recombination into a bacterial shuttle vector. The sporozoite cDNA identified in these experiments encoded a protein with conserved structural features of the prototypical T. gondii SAG1 (P30) and shared sequence identity with surface proteins from Sarcocystis spp. This new member of the SAG superfamily was designated SporoSAG. Expression of SporoSAG in tachyzoites conferred enhanced invasion on transgenic parasites suggesting a role for this protein in oocyst/sporozoite transmission to susceptible hosts.     

Surface antigens of Toxoplasma gondii: variations on a theme

Toxoplasma gondii is an obligate intracellular protozoan parasite with an exceptionally broad host range. Recently, it has become apparent that the number of surface antigens (SAGs) it expresses may rival the number of genera it can infect. Most of these antigens belong to the developmentally regulated and distantly related SAG1 or SAG2 families. The genes encoding the surface antigens are distributed throughout the T. gondii genome, with remarkably little polymorphism observed at each locus. Results from a number of studies have suggested that the surface antigens play an important role in the biology of the parasite. For example, SAG3 null mutants generated by targeted disruption provide convincing evidence that this surface antigen, at least, functions during parasite attachment. Analyses of a SAG1 knockout in rodents, however, indicate that this surface antigen may play a crucial role in immune modulation or virulence attenuation. The current understanding of the SAG1 and SAG2 families will be discussed here.     

Toxoplasma gondii: identification of a developmentally regulated family of genes related to SAG2

Previous studies have shown the surface of Toxoplasma gondii to be dominated by a family of proteins closely related to SAG1. In this study, we report the existence of a second family of genes defined by homology to SAG2. The predicted amino acid sequences of these three new proteins suggests that they are all glycosylphosphatidylinositol-linked surface antigens. All three also contain N-linked glycosylation sites, although their use has yet to be demonstrated. One of these SAG2-related antigens, SAG2B, is expressed in tachyzoites with an apparent size of 23 kDa. It is distinct, however, from the previously identified P23. In contrast to SAG2B, SAG2C and SAG2D appear to be expressed exclusively on the surface of bradyzoites. Analysis of the SAG2 family shows it to have weak but significant homology to the SAG1 family. Thus, all of the sequenced surface antigens of tachyzoites and many of those of bradyzoites fall into one large superfamily that can be divided into two subgroups defined by the prototypic and highly immunogenic SAG1 and SAG2, respectively.     

Protective immunity induced by vaccination with SAG1 gene-transfected cells against Toxoplasma gondii-infection in mice

To develop a vaccine by augmenting the protective cellular immunity against Toxoplasma gondii (T. gondii)-infection, T gondii SAG1 gene-transfectants were established by using RMA.S (H-2b), a murine transporter associated with the antigen processing (TAP) molecule-deficient lymphoma line, as a host antigen-presenting cell (APC). Immunization of C57BL/6 mice with the SAG1-transfected RMA.S induced CD8+ cytotoxic T lymphocytes (CTL) specific for not only SAG1-transfected RMA.S but also T gondii-infected RMA.S, and elicited protective responses to infection with a virulent T. gondii strain, RH.     

Genetic characteristics of the Korean isolate KI-1 of Toxoplasma gondii

Toxoplasma gondii tachyzoites were isolated from an ocular patient in the Republic of Korea and maintained in the laboratory (designated KI-1). In the present study, its genotype was determined by analyzing dense granule antigen 6 (GRA6) gene and surface antigen 2 (SAG2) gene as typing markers. Digestion of the amplification products of GRA6 and of the 5o and 3o ends of SAG2, respectively, with Mse I, Sau3A I, and Hha I, revealed that KI-1 is included in the genotype I, which includes the worldwide virulent RH strain. In addition, when the whole sequences of the coding regions of SAG1, rhoptry antigen 1 (ROP1), and GRA8 genes of KI-1 were compared with those of RH, minor nucleotide polymorphisms and amino acid substitutions were identified. These results show that KI-1 is a new geographical strain of T. gondii that can be included in the genotype I.     

Analysis of the SAG5 locus reveals a distinct genomic organisation in virulent and avirulent strains of Toxoplasma gondii

We have recently characterised, in the virulent strain RH of Toxoplasma gondii, three glycosylphosphatidylinositol-anchored surface antigens related to SAG1 (p30) and encoded by highly homologous, tandemly arrayed genes named SAG5A, SAG5B and SAG5C. In the present study, we compared the genomic organisation of the SAG5 locus in strains belonging to the three major genotypes of T. gondii. Southern blot analysis using a SAG5-specific probe produced two related but distinct hybridisation patterns, one exclusive of genotype I virulent strains, the other shared by avirulent strains of either genotype II or genotype III. To understand the molecular bases of this intergenotypic heterogeneity, we cloned and sequenced the SAG5 locus in the genotype II strain Me49. We found that in this isolate the SAG5B gene is missing, with SAG5A and SAG5C laying contiguously. This genomic arrangement explains the hybridisation profiles observed for all the avirulent strains examined and indicates that the presence of SAG5B is a distinctive trait of genotype I. Furthermore, we identified two novel SAG1-related genes, SAG5D and SAG5E, mapping respectively 1.8 and 4.0 kb upstream of SAG5A. SAG5D is transcribed in tachyzoites and encodes a polypeptide of 362 amino acids sharing 50% identity with SAG5A-C, whereas SAG5E is a transcribed pseudogene. We also evaluated polymorphisms at the SAG5 locus by comparing the coding regions of SAG5A-E from strains representative of the three archetypal genotypes. In agreement with the strict allelic dimorphism of T. gondii, we identified two alleles for SAG5D, whereas SAG5A, SAG5C and SAG5E were found to be three distinct nucleotide variants. The higher intergenotypic polymorphism of SAG5A, SAG5C and SAG5E suggests that these genes underwent a more rapid genetic drift than the other members of the SAG1 family. Finally, we developed a new PCR–restriction fragment length polymorphism method based on the SAG5C gene that is able to discriminate between strains of genotype I, II and III by a single endonuclease digestion.     

弓形虫膜表面抗原SAG2蛋白的高效表达及免疫活性分析

在大肠杆菌中以可溶性形式高效表达弓形虫膜表面抗原SAG2蛋白,并对其免疫活性进行分析。应用PCR技术从刚地弓形虫RH株的基因组DNA中扩增编码SAG2的基因片段,亚克隆至原核表达载体pET32a(+),在大肠埃希菌(E.coli)BL21内表达,并对其表达条件进行优化,Western blotting和ELISA分析纯化蛋白的免疫原性;纯化的重组蛋白免疫小鼠制备多抗,用间接免疫荧光试验(IFA)分析表达蛋白的免疫反应性。成功构建重组质粒pET32a(+)-tSAG2,所表达的融合蛋白大小约为38kD。在IPTG终浓度为0.1mmol/L、诱导时间4-6h和培养温度32℃条件下,重组SAG2蛋白主要以可溶性形式在大肠杆菌中高效表达,每升培养菌液约获得可溶性重组SAG2蛋白16mg。Western blotting及ELISA结果显示纯化蛋白具有良好的免疫原性。IFA显示重组蛋白的抗血清能够识别刚地弓形虫表面的SAG2天然蛋白,所表达蛋白具有良好的免疫反应性。截断的SAG2基因在大肠杆菌中得到了高效表达,重组蛋白保持了天然蛋白的免疫活性,为进一步利用该重组蛋白进行弓形虫病免疫诊断及基因工程亚单位疫苗的研制奠定基础。     

Production of the main surface antigen of Toxoplasma gondii in tobacco leaves and analysis of its antigenicity and immunogenicity

We adapted a previously described Agrobacterium-mediated transient expression system to test the expression level of three constructs carrying the surface antigen 1 (SAG1) of Toxoplasma gondii. Two constructs were based in a Potato virus X (PVX) amplicon. In one of them, the PVX movement protein genes were replaced by the sag1 gene. In the other, the sag1 gene was placed under the control of an additional coat protein subgenomic promoter. In the third construct, the sag1 gene was fused to an apoplastic peptide signal under the CaMV 35S promoter. Western blot analysis of leaf extracts infiltrated with each construct revealed a protein of 35 kDa. SAG1 accumulation in leaves ranged from 0.1 to 0.06% of total soluble protein (equivalent to 10 microg and 6 microg of SAG1 per gram of fresh leaf tissue, respectively). Three of five human seropositive samples reacted with tobacco-expressed SAG1 in Western blot analysis. The C3H mice were immunized with SAG-expressing leaf extracts and perorally challenged with a nonlethal dose of the T. gondii Me49 strain. Mice vaccinated with SAG1 showed significantly lower brain cyst burdens compared to those from the control group. Immunization with SAG1-expressing leaves elicited a specific humoral response with predominant participation of type IgG2a. In conclusion, a functional SAG1 version could be transiently expressed in tobacco leaves.     

Real-Time RT-PCR on SAG1 and BAG1 Gene Expression during Stage Conversion in Immunosuppressed Mice Infected with Toxoplasma gondii Tehran Strain

Toxoplasmic encephalitis is caused by reactivation of bradyzoites to rapidly dividing tachyzoites of the apicomplexan parasite Toxoplasma gondii in immunocompromised hosts. Diagnosis of this life-threatening disease is problematic, because it is difficult to discriminate between these 2 stages. Toxoplasma PCR assays using gDNA as a template have been unable to discriminate between an increase or decrease in SAG1 and BAG1 expression between the active tachyzoite stage and the latent bradyzoite stage. In the present study, real-time RT-PCR assay was used to detect the expression of bradyzoite (BAG1)- and tachyzoite-specific genes (SAG1) during bradyzoite/tachyzoite stage conversion in mice infected with T. gondii Tehran strain after dexamethasone sodium phosphate (DXM) administration. The conversion reaction was observed in the lungs and brain tissues of experimental mice, indicated by SAG1 expression at day 6 after DXM administration, and continued until day 14. Bradyzoites were also detected in both organs throughout the study; however, it decreased at day 14 significantly. It is suggested that during the reactivation period, bradyzoites not only escape from the cysts and reinvade neighboring cells as tachyzoites, but also converted to new bradyzoites. In summary, the real-time RT-PCR assay provided a reliable, fast, and quantitative way of detecting T. gondii reactivation in an animal model. Thus, this method may be useful for diagnosing stage conversion in clinical specimens of immunocompromised patients (HIV or transplant patients) for early identification of tachyzoite-bradyzoite stage conversion.     

Toxoplasma gondii: immunogenicity and protection by P30 peptides in a murine model

Vaccines are promising for the control of toxoplasmosis. Here, we evaluated the immunogenicity of 17 peptides derived from SAG1 surface protein of Toxoplasma gondii in CH3 mice. Only 8 of 16 peptides induced specific antibodies. After a lethal challenge, only the vaccination with 4 of 17 peptides that were from the carboxy terminal end of the protein conferred significant survival. Our work shows that vaccination with peptides from the carboxy-terminal positions of SAG1 major surface protein of Toxoplasma protects mice against a lethal challenge.     

Regulation of developmental senescence is conserved between Arabidopsis and Brassica napus

SAG12 is a developmentally controlled, senescence-specific gene from Arabidopsis which encodes a cysteine protease. Using SAG12 as a probe, we isolated two SAG12 homologues (BnSAG12–1 and BnSAG12–2) from Brassica napus. Structural comparisons and expression studies indicate that these two genes are orthologues of SAG12. The expression patterns of BnSAG12–1 and BnSAG12–2 in Arabidopsis demonstrate that the senescence-specific regulation of this class of cysteine proteases is conserved across these species. Gel-shift assays using the essential promoter regions of SAG12, BnSAG12–1, and BnSAG12–2 show that the extent of binding of a senescence-specific, DNA-binding protein from Arabidopsis is proportional to the expression levels of these genes in Arabidopsis. Therefore, the expression levels of these genes may reflect the affinities of the senescence-specific DNA-binding protein for the promoter element.     

Ly-49 multigene family. New members of a superfamily of type II membrane proteins with lectin-like domains

Ly-49 (YE1/48, A1) is a dimer protein expressed on subpopulations of murine NK cells. It is a member of a superfamily of type II transmembrane proteins containing carbohydrate recognition domains (CRD). In the mouse genome, the detection of multiple restriction fragments that cross-hybridize with Ly-49 cDNA probes suggests the presence of related genes. In this study, we have isolated several genomic clones encoding portions of CRD sequences highly homologous to the CRD of Ly-49. By using primers based on the consensus sequences of the genomic clones, expression of Ly-49-related genes was detected by the polymerase chain reaction in various organs, including lung, kidney, liver, spleen, and thymus. Two full-length cDNA clones that are highly homologous to the Ly-49 gene were subsequently isolated from a lung cDNA library. At the nucleotide level, the two clones are 72% and 80% identical to Ly-49 in their translated regions, but their sequences are different from those of the genomic clones characterized to date. The two cDNA clones potentially encode type II transmembrane proteins containing CRD that are very similar to Ly-49. These amino acid sequences are also homologous to other members of the superfamily of CRD-containing type II transmembrane proteins, including hepatic lectins and the low affinity IgER (CD23). The homology is most evident in the CRD but is also significant in other domains. These results demonstrate the existence of several functional genes that are highly related to Ly-49. These genes comprise a subfamily within the superfamily of type II transmembrane proteins containing CRD.     

Development and clinical evaluation of a rapid serodiagnostic test for toxoplasmosis of cats using recombinant SAG1 antigen

Rapid serodiagnostic methods for Toxoplasma gondii infection in cats are urgently needed for effective control of transmission routes toward human infections. In this work, 4 recombinant T. gondii antigens (SAG1, SAG2, GRA3, and GRA6) were produced and tested for the development of rapid diagnostic test (RDT). The proteins were expressed in Escherichia coli, affinity-purified, and applied onto the nitrocellulose membrane of the test strip. The recombinant SAG1 (rSAG1) showed the strongest antigenic activity and highest specificity among them. We also performed clinical evaluation of the rSAG1-loaded RDT in 182 cat sera (55 household and 127 stray cats). The kit showed 0.88 of kappa value comparing with a commercialized ELISA kit, which indicated a significant correlation between rSAG1-loaded RDT and the ELISA kit. The overall sensitivity and specificity of the RDT were 100% (23/23) and 99.4% (158/159), respectively. The rSAG1-loaded RDT is rapid, easy to use, and highly accurate. Thus, it would be a suitable diagnostic tool for rapid detection of antibodies in T. gondii-infected cats under field conditions.     

Molecular dissection of the human B-cell response against Toxoplasma gondii infection by lambda display of cDNA libraries

The disorders generated by Toxoplasma gondii infection are closely associated with the competence of the host immune system and both humoral and cell mediated immunity are involved in response to parasite invasion. To identify antigens implicated in human B-cell responses, we screened a phage-display library of T. gondii cDNA fragments with sera of infected individuals. This approach identified a panel of recombinant phage clones carrying B-cell epitopes. All the peptide sequences selected by this procedure are regions of T. gondii gene products. These regions contain epitopes of the T. gondii antigens SAG1, GRA1, GRA7, GRA8 and MIC5, which are recognised by human immunoglobulins. Moreover, we report the isolation and characterisation of two additional immunodominant regions encoded by GRA3 and MIC3 genes, whose products have never been described as antigens of the human B-cell response against T. gondii infection. These results demonstrate potential of lambda-display technology for antigen discovery and for the study of the human antibody response against infectious agents.     

Targeted disruption of the glycosylphosphatidylinositol-anchored surface antigen SAG3 gene in Toxoplasma gondii decreases host cell adhesion and drastically reduces virulence in mice

The protozoan parasite Toxoplasma gondii is able to invade a broad range of cells within its mammalian hosts through mechanisms that are not yet fully understood. Several glycosylphosphatidylinositol-anchored antigens found in the parasite membrane are considered as major determinants in the critical interactions with the host cell. We have discovered that two of these surface antigens, SAG1 and SAG3, share significant identity, with considerable similarities in structure, suggesting an overall conserved topology. To investigate their physiological roles further, we have generated T. gondii mutants deficient in SAG3 through gene disruption. The disrupted strains display at least a twofold reduction in host cell invasion when compared with wild-type parasites. This correlated with a similar decrease in host cell adhesion in the SAG3 null mutants. Importantly, the null SAG3 mutants show attenuated infectivity, with a markedly reduced capacity to cause mortality in mice, whereas both wild-type and complemented mutants that re-expressed SAG3 were lethal at the same doses. Taken together, our results indicate that SAG3 is one member of the redundant system of T. gondii receptors that act as ligands mediating host cell recognition and attachment.     

Differentiation of Neospora hughesi from Neospora caninum based on their immunodominant surface antigen, SAG1 and SRS2

Neospora hughesi is a newly recognised parasite that is closely related to Neospora caninum, and is a cause of equine protozoal myeloencephalitis. We have characterised two N. hughesi immunodominant tachyzoite antigens which exhibit antigenic and molecular differences from the homologous tachyzoite antigens on N. caninum. These antigens on N. hughesi are referred to as NhSAG1 and NhSRS2, using the same mnemonics as used for the N. caninum antigens (NcSAG1 and NcSRS2), and are homologous to Toxoplasma gondii surface antigen 1 (SAG1) and SAG1-related sequence 2 (SRS2). The NcSAG1 and NcSRS2 were antigenically conserved in six different N. caninum isolates from cattle and dogs. The two equine-derived Neospora isolates, one designated as N. hughesi, were similar to each other but different from N. caninum. There was 6% difference in amino acid identity between NcSAG1 and NhSAG1, whereas there was a 9% difference when NcSRS2 and NhSRS2 were compared. The polymorphism of these genes and their corresponding proteins provide additional markers which can be used to distinguish N. caninum from N. hughesi.