Interaction of sporozoites of Theileria parva with bovine lymphocytes in vitro. 1. Early events after invasion

Sporozoites of Theileria parva rapidly enter bovine lymphocytes by a mechanism of passive endocytosis that depends upon progressive circumferential binding of ligands on the parasite to receptors on the host-cell membrane. Within 10 min of entry, the micronemes of the sporozoite discharge their content and the enveloping host-cell membrane is lysed. The host cell responds within 30 min of invasion by polymerization of microtubules arrayed tangential to the sporozite and converging upon the cytocentrum. Multivesicular bodies and lysosomes are generated and gather around the parasite but are ineffective in the absence of an endocytotic membrane with which they can fuse. Thus Theileria parva can be added to the category of obligate intracellular parasites that ensure their survival by lysis of the parasitophorous vacuole.     

The entry of Theileria parva sporozoites into bovine lymphocytes: evidence for MHC class I involvement

We have examined the process of Theileria parva sporozoite entry into susceptible bovine lymphocytes and have begun to identify one of the possible molecular interactions involved in the process. The entry process involves a defined series of events and we have used a number of experimental procedures in combination with a method of quantitation to examine various aspects of this process. T. parva sporozoites are nonmotile organisms and the initial sporozoite-lymphocyte interaction is a chance event which can occur at 0-2 degrees C. All subsequent stages in the process are temperature dependent, require the participation of live intact sporozoites and host cells, and involve some cytochalasin-inhibitable rearrangement of the host cell surface membrane or cytoskeleton. Sporozoite entry can be inhibited by antibodies (mAbs) reactive with major histocompatibility complex (MHC) class I molecules (IL-A 19, IL-A 88) and with beta 2 microglobulin (B1G6), whereas mAbs reactive with MHC class II molecules (IL-A 21, J 11), and a common panleucocyte surface antigen, (IL-A 87; a bovine equivalent of CD 11a) have no effect. These results indicate that MHC class I molecules play a role in the process of T. parva sporozoite entry into bovine lymphocytes although as yet the precise role has not been determined. Once internalized within the lymphocyte, a process that takes less than 3 min at 37 degrees C, the sporozoite rapidly escapes from the encapsulating host cell membrane; a process which occurs concurrently with the discharge of the contents of the sporozoite rhoptries and microspheres. The intracytoplasmic parasite is covered by a layer of sporozoite-derived fuzzy material to which host cell microtubules rapidly become associated.     

Theileria parva: expression of a sporozoite surface coat antigen

A monoclonal antibody specific for the Theileria parva sporozoite, which recognizes a determinant on the surface coat and blocks sporozoite infectivity, was used to investigate the presence of the determinant on other stages of the parasite lifecycle. Immunofluorescence techniques did not demonstrate this determinant on the kinete, schizont, merozoite, or piroplasm stages of the parasite. Immunoautoradiography, using a tritiated form of the monoclonal antibody, on sections of infected salivary glands collected from ticks that had fed for 0, 1, 2, 3, or 4 days revealed that the determinant recognized was synthesized predominantly during sporogony, between 2 to 3 days after the tick started feeding. Immunoelectron microscopy was performed on ultrathin frozen sections of infected tick salivary glands incubated with the monoclonal antibody followed by Protein-A--colloidal gold. The antigen or its precursor could be detected in the developing parasite. In ticks fed 2 days, the sporoblast was labeled, both in the cytoplasm and on parasite membranes, often including the nuclear envelope. In sections from ticks fed 4 days, the sporozoite surface membrane was labeled, as were membrane-bounded sporozoite organelles identified as micronemes. Observation by immunofluorescence, on sporozoites incubated with bovine peripheral blood lymphocytes, suggested that the antigen recognized by the monoclonal antibody does not enter the lymphocyte during sporozoite endocytosis. We conclude that synthesis of the antigen or its precursor(s) occurs during sporogony in the feeding tick, at the time of maximal parasite proliferation, and precedes the formation of morphologically mature sporozoites; the antigen's role in the parasite life cycle also appears to be limited to events associated with the sporozoite entry process.     

The entry of sporozoites of Theileria parva into bovine lymphocytes in vitro. Immunoelectron microscopic observations

In an electron microscopic investigation of the entry of sporozoites of Theileria parva into bovine lymphocytes, the fate of the surface coat of the parasite was traced by immunocytochemical methods. A monoclonal antibody (MAbD1) raised in mice and directed against a surface antigen of sporozoites, was applied to ultrathin frozen sections of bovine lymphocytes infected in vitro. Sites of binding of MAbD1 were localized using a protein A-colloidal gold conjugate as an electron-dense label. The surface of all free sporozoites was labelled. Sporozoites in the process of entering were labelled only on that portion of the membrane not yet tightly bound to the lymphocyte membrane. No label was detected on sporozoites that had completed entry. After fixation with formaldehyde, but not with glutaraldehyde, local areas of labelling were found on lymphocytes in contact with sporozoites and on cells already invaded. The sporozoite organelles, called micronemes, occasionally appeared to contain labelled antigen. No label was found on sporozoites or lymphocytes in control preparations previously exposed to non-specific antibody or treated with protein A-colloidal gold alone. The findings support the conclusion that the sporozoite surface coat, containing the antigen recognized by MAbD1, is shed as the sporozoite enters the host cell.     

Development of recombinant antigen vaccines for the control of theileriosis

Immunization against Theileria parva involves infection with sporozoites and simultaneous treatment with a long-acting tetracycline. For T. annulata, immunization is achieved by inoculation of attenuated schizont-infected lymphocytes. The two methods are inadequate because of the use of live organisms and the methods are also bedevilled by the multiplicity of strains, particularly of T. parva. For these reasons, alternative methods of control are being sought. In this review an attempt is made to highlight advances towards subunit vaccines against T. parva and T. annulata. Several candidate antigens which are thought to induce protective responses have been identified and recombinant DNA technology is being employed to produce these antigens in bulk. Relevant antigens may be delivered as subunit vaccines by using recombinant vaccinia virus or attenuated Salmonella spp. as carriers of the genes expressing these antigens. It is likely that effective vaccines against T. parva and T. annulata will have to elaborate immune responses against both the sporozoite and schizont stages of the parasite.     

A rapid and sensitive intracellular flow cytometric assay to identify Theileria parva infection within target cells

Theileria parva is an intracellular protozoan parasite transmitted by ticks that causes a fatal lymphoproliferative disease of cattle known as East Coast Fever. Vaccination against the disease currently relies on inoculation of the infective sporozoite stage of the parasite and simultaneous treatment with long-acting formulations of oxytetracycline. Sporozoites are maintained as frozen stabilates of triturated infected ticks and the method requires accurate titration of stabilates to determine appropriate dose rates. Titration has traditionally been undertaken in cattle and requires large numbers of animals because of individual variation in susceptibility to infection. An alternative tissue culture-based method is laborious and time consuming. We have developed a flow cytometric method for quantifying the infectivity of sporozoite stabilates in vitro based on the detection of intracellular parasite antigen. The method allows clear identification of parasitized cells with a high degree of sensitivity and specificity. Analysis of infected cells between 48 and 72 h post-infection clearly defines the potential transforming capability of different stabilates.     

Theileria parva: sporozoite entry into bovine lymphocytes is not dependent on the parasite cytoskeleton.

The main conclusion from the present study is that T. parva sporozoite entry is dependent on a functional host cell actin cytoskeleton and is not driven by the parasite. Treating lymphocytes with cytochalasin D resulted in a dose-dependent reduction in the levels of host cell infection. However, the primary effect was to block sporozoite binding and only at the highest concentration (20 microM) was sporozoite internalization significantly reduced. In fact at lower concentrations (1-10 microM) cytochalasin treatment lead to a relative increase in sporozoite internalization. The results are consistent with sporozoite entry being primarily a passive process and with a functional host cell actin cytoskeleton that is required only to maintain the molecular integrity of the surface membrane. Thus T. parva sporozoite entry differs from the process in other apicomplexans, although the results are consistent with a number of features of sporozoite biology. Treatment of lymphocytes with either the microtubule-destabilizing agent, nocodazole, or taxol, which induces microtubule polymerization, had no significant effect on sporozoite binding or entry. As both reagents had the expected effects on the lymphocyte microtubule system, it is unlikely that host cell microtubules are essential for successful sporozoite invasion or establishment.     

Alteration of host cell phenotype by Theileria annulata and Theileria parva: mining for manipulators in the parasite genomes

The apicomplexan parasites Theileria annulata and Theileria parva cause severe lymphoproliferative disorders in cattle. Disease pathogenesis is linked to the ability of the parasite to transform the infected host cell (leukocyte) and induce uncontrolled proliferation. It is known that transformation involves parasite dependent perturbation of leukocyte signal transduction pathways that regulate apoptosis, division and gene expression, and there is evidence for the translocation of Theileria DNA binding proteins to the host cell nucleus. However, the parasite factors responsible for the inhibition of host cell apoptosis, or induction of host cell proliferation are unknown. The recent derivation of the complete genome sequence for both T. annulata and T. parva has provided a wealth of information that can be searched to identify molecules with the potential to subvert host cell regulatory pathways. This review summarizes current knowledge of the mechanisms used by Theileria parasites to transform the host cell, and highlights recent work that has mined the Theileria genomes to identify candidate manipulators of host cell phenotype.     

A Sporozoite-based vaccine for Theileria parva

East Coast fever, which is caused by Theileria parva infection in cattle, is of major economic importance in eastern and central Africa. Until recently, the only available method of immunization against East Coast fever was the infection with live sporozoites and simultaneous treatment with a long-acting oxytetracycline. This method has two major disadvantages: (I) it uses live organisms; and (2) the immunity engendered is parasite strain specific. In this article, Antony Musoke, Vishvonath Nene and Subhosh Morzoria review the progress made in developing an alternative method o f immunization based on a defined sporozoite antigen.     

Apoptosis of Theileria-infected lymphocytes induced upon parasite death involves activation of caspases 9 and 3

The intracellular parasite Theileria parva (T. parva) can infect bovine B and T-lymphocytes. T. parva-infected cells become transformed, and they survive and proliferate independently of exogenous growth factors. In vivo the uncontrolled cellular proliferation associated with lymphocyte transformation underlies the pathogenesis of the disease called East Coast Fever. The transformed state of parasitised cells can be reversed upon elimination of the parasite by specific theilericide drugs. In this study we found that elimination of the parasite by buparvaquone induces apoptosis of transformed B and CD8(+) T-lymphocytes. Apoptosis is accompanied by the activation of caspase 9 and caspase 3 and processing of poly(ADP ribose) polymerase and is inhibited by Z-VAD a general caspase inhibitor. Based on these observations, we propose that the lack of activation of a caspase 9 > caspase 3 > poly(ADP ribose) polymerase pathway is important and protects T. parva-transformed cells from spontaneous apoptosis.     

Protective immune mechanisms against Theileria parva: evolution of vaccine development strategies.

Theileria parva is an intracellular sporozoan parasite that infects and transforms bovine lymphocytes, causing a severe lymphoproliferative disease known as East Coast fever in eastern, central and southern Africa. In this article, Declan McKeever and colleagues summarize the current understanding of immune mechanisms provoked by the parasite with regard to their role in both pathogenesis and protection. In particular, the influence of genomic polymorphism in parasite and host on the development of immunity is discussed, along with the evolution of current vaccine development strategies as a result of immunological research on the disease.     

Baculovirus surface display of Theileria parva p67 antigen preserves the conformation of sporozoite-neutralizing epitopes

Theileria parva is an intracellular protozoan parasite that causes East Coast fever, a severe lymphoproliferative disease in cattle. Previous attempts to produce recombinant sporozoite surface antigen (p67) in bacterial or insect cells for vaccine purposes have not resulted in a correctly folded protein. Here, we report the expression of N- and C-terminal domains of p67 fused to the baculovirus envelope glycoprotein GP64 by cloning the appropriate p67 cDNA segments between the signal sequence and the major portion of GP64. To further advance the generation of such recombinants, existing surface display techniques were combined with bacmid technology. Chimeric proteins were present on the surface of budded viruses as judged by immunogold labelling and were exposed on the surface of insect cells, as concluded from immunofluorescence studies of infected, non-fixed insect cells. In non-denaturing dot blot experiments, a strong reaction was obtained between monoclonal TpM12 and baculovirus particles displaying the p67N-GP64 chimeric protein. This antibody, raised against native p67, also specifically recognized the surface of recombinant-infected cells. Apparently, a more native conformation was achieved than when p67 was expressed in E.coli or in conventional baculovirus expression systems. The baculovirus surface expression system, therefore, provides an improved way of expressing this T.parva sporozoite surface protein.     

De novo expression of T cell markers on Theileria parva-transformed lymphoblasts in cattle

We describe monoclonal antibodies that detect two new membrane antigens on bovine T cells. One molecule is only expressed on activated T cells and has a m.w. of 100,000. The other antigen is a glycoprotein that is precipitated as two bands of m.w. 150,000 and 158,000 and is expressed on a subpopulation of T cells and all myeloid cells. We show that when bovine lymphocytes are transformed by the protozoan parasite Theileria parva, both antigens become expressed on the cell surface. The infected cell acquires the phenotype of a proliferating T cell, irrespective of its precursor cell phenotype.     

Salivary gland of the tick vector of East Coast fever. III. The ultrastructure of sporogony in Theileria parva

Sporogony of the sporozoan Theileria parva in the salivary gland of the tick vector of East Coast fever was studied in electron micrographs. The findings differ in several respects from previous interpretations based upon light microscopy. Cytokinesis of the primary sporoblast to form secondary and tertiary sporoblasts is not substantiated. Instead it is suggested that the parasite develops as a ramifying, multinucleate syncytium rapidly increasing in size and complexity until it gives rise to myriad sporozoites in a terminal episode of cytoplasmic fission. The proliferating nuclei initially occupy peripheral lobules that are continuous with a central labyrinth of branching and anastomosing processes which present a very large surface area for interchange of metabolites with the host cell cytoplasm. The membrane of the labyrinth is rich in cytostomes, but no evidence if found to bulk uptake of host cytoplasmic matrix or organelles into food vacuoles. Rhoptries are the first of the polar organelles of the parasite to develop and are associated with dense plaques irregularly distributed on the inner aspect of the parasite membrane. Micronemes form independently of the rhoptries at a later stage. After 3-4 days of tick feeding, sporogeny is complete and the infected salivary gland cell contains up to 50, 000 spherical or ovoid sporozoites about 1 micrometer in diameter. These are limited by a simple plasma membrane. The inner layer of the 'pellicle', the polar ring, and the conoid described for zoites of other Apicomplexa are lacking. Maturational changes are noted in sporozoites after sporogony is completed. Micronemes appear to increase in size, and possibly in number, from days 3-5 and the majority take up positions immediately subjacent to the plasmalemma.     

Ultrastructure of the intra-erythrocytic stage of Theileria species from cattle and waterbuck

A transmission electron microscopic study of the intra-erythrocytic stages of a pathogenic Theileria parva from cattle and a previously uncharacterized Theileria sp. from waterbuck (Kobus defassa) in Kenya revealed several novel ultrastructural features, associated with feeding and multiplication, in these parasites. In trophozoites a connecting channel was observed between the parasite's cytostome and its intracytoplasmic food vacuole. In some cases the limiting membrane of the food vacuole was seen to be continuous with a close-meshed network of membrane-bounded, anastomosing tubules. This labyrinthine structure, which has not been described previously, may function as a digestive organelle in theilerial trophozoites. Electron micrographs also revealed the mode of intra-erythrocytic multiplication of these parasites in vivo. Prior to division, electron-dense cisternae and rhoptries appeared beneath the parasite's plasmalemmal membrane, marking the sites of merozoite formation. From a single parasite, a maximum of four merozoites were formed by schizogonous division and subsequently separated from a residual body by constriction at the base of each merozoite. In addition, observations on two double-membraned organelles seen in trophozoites and the intra-erythrocytic crystalline structures associated with Theileria sp. in waterbuck are reported.     

The genome of Theileria parva: some structural properties

The DNA of the protozoan Theileria parva, the causal agent of the bovine East Coast Fever, has been prepared at least 99% pure from the intra-erythrocytic form of the parasite. Its buoyant density was found to be 1.696 g/cm3 and its calculated G + C content was 36.7%. Fragmentation of T. parva by the restriction enzyme EcoRI provides some evidence of the presence of repetitive DNA sequences.