Functional role of 64P, the candidate transmission-blocking vaccine antigen from the tick, Rhipicephalus appendiculatus.

Anti-ectoparasite vaccines offer attractive alternatives to the use of chemical pesticides, especially if they also control the pathogens that ectoparasites transmit. However, selection of suitable antigens is a major constraint on vaccine development. The recombinant tick cement protein, 64TRP, derived from the African brown ear tick, Rhipicephalus appendiculatus, acts as a transmission-blocking vaccine in a mouse model of tick-borne encephalitis virus (TBEV) transmission, protecting immunised mice against lethal challenge with TBEV after exposure to infected ticks. 64TRP acts as a dual action vaccine, targeting both 'exposed' antigens in tick saliva and 'concealed' antigenic epitopes in the tick midgut. To assess further the suitability of 64TRP as a vaccine antigen, we examined the function (including localisation) of the protein, and its sequence variability. Histological profiles of normal hamster skin showed similarities between normal skin proteins in the epidermis (keratin) and dermis (collagen/reticulin) and the tick cement cone. Immuno-reactivity of anti-64TRP sera with hamster skin suggests a potential sequence similarity of 64P with host skin proteins and may reflect previously reported sequence similarities of 64P with skin keratin and collagen proteins. Variability in the N-terminal signal peptide and in the C-terminal glycine-rich amino acid repeats of 64P protein was detected; previous studies showed the C-terminal region to be immunologically non-protective. Using in situ hybridisation and quantitative reverse transcriptase-PCR, 64P mRNA was detected in the types II and III salivary gland acini. The highest levels of 64P mRNA were observed in 1-day fed females, and 1- and 7-day fed males. Salivary glands of longer feeding females and unfed ticks as well as midguts of both sexes were negative. Early expression in tick salivary glands is consistent with previously published data that 64P is a cement protein, and contributes to its candidacy as a vaccine antigen. However, further studies are required to assess whether cross-reactivity with skin proteins may induce autoimmunity.

Global genetic diversity and evolution of var genes associated with placental and severe childhood malaria.

In Plasmodium falciparum, var genes encode adhesive proteins that are transported to the surface of infected erythrocytes and act as major virulence determinants for infected erythrocyte binding and immune evasion. Var genes are highly diverse and can be classified into five major groups (UpsA, B, C, D, and E). Previous serological studies have suggested that the UpsA var group may contain common antigenic types that have important roles in severe childhood malaria. Here, our analysis found that UpsA vars are highly diverse between 22 world-wide parasite isolates, although they could be grouped into two broad clusters that may be separately recombining. By comparison, orthologs of the UpsA-linked Type 3 var and UpsE-linked var2csa were detected in nearly all parasite isolates, and a var2csa ortholog was also present in a chimpanzee malaria P. reichenowi that diverged from P. falciparum approximately 5-7 million years ago. Although the specific function of Type 3 var genes is unknown, var2csa is a leading candidate for a pregnancy associated malaria vaccine. Compared to typical var genes, var2csa is unusually conserved but still had only 54-94% amino acid identity in extracellular binding regions. However, var2csa alleles have extensive gene mosaicism within polymorphic blocks that are shared between world-wide parasite isolates and recognizable in P. rechenowi suggesting a high rate of self-self recombination and an ancient and globally-related pool of var2csa polymorphism. These studies aid our understanding of the evolutionary mechanisms that shape var diversity and will be important to the development of vaccines against pregnancy associated malaria and severe malaria.

An antivector vaccine protects against a lethal vector-borne pathogen.

Vaccines that target blood-feeding disease vectors, such as mosquitoes and ticks, have the potential to protect against the many diseases caused by vector-borne pathogens. We tested the ability of an anti-tick vaccine derived from a tick cement protein (64TRP) of Rhipicephalus appendiculatus to protect mice against tick-borne encephalitis virus (TBEV) transmitted by infected Ixodes ricinus ticks. The vaccine has a "dual action" in immunized animals: when infested with ticks, the inflammatory and immune responses first disrupt the skin feeding site, resulting in impaired blood feeding, and then specific anti-64TRP antibodies cross-react with midgut antigenic epitopes, causing rupture of the tick midgut and death of engorged ticks. Three parameters were measured: "transmission," number of uninfected nymphal ticks that became infected when cofeeding with an infected adult female tick; "support," number of mice supporting virus transmission from the infected tick to cofeeding uninfected nymphs; and "survival," number of mice that survived infection by tick bite and subsequent challenge by intraperitoneal inoculation of a lethal dose of TBEV. We show that one dose of the 64TRP vaccine protects mice against lethal challenge by infected ticks; control animals developed a fatal viral encephalitis. The protective effect of the 64TRP vaccine was comparable to that of a single dose of a commercial TBEV vaccine, while the transmission-blocking effect of 64TRP was better than that of the antiviral vaccine in reducing the number of animals supporting virus transmission. By contrast, the commercial antitick vaccine (TickGARD) that targets only the tick's midgut showed transmission-blocking activity but was not protective. The 64TRP vaccine demonstrates the potential to control vector-borne disease by interfering with pathogen transmission, apparently by mediating a local cutaneous inflammatory immune response at the tick-feeding site.

A cross-reactive tick cement antigen is a candidate broad-spectrum tick vaccine.

Truncated constructs of 64P (64TRPs), a secreted cement protein from salivary glands of the tick Rhipicephalus appendiculatus, provided cross-protection against Rhipicephalus sanguineus and Ixodes ricinus, apparently by targeting antigens in the midgut and salivary glands of adults and nymphs, causing mortality. Tick feeding on 64TRP-immunised animals stimulated local inflammatory immune responses (involving basophils, eosinophils, lymphocytes, mast cells, macrophages and dendritic-like cells) that boosted the immune status of vaccinated animals. The vaccine trial results, and antigenic cross-reactivity of 64TRPs with R. sanguineus, I. ricinus, Amblyomma variegatum and Boophilus microplus, indicate the potential of 64TRPs as a broad-spectrum anti-tick vaccine.

Identification of multiple chondroitin sulfate A (CSA)-binding domains in the var2CSA gene transcribed in CSA-binding parasites.

Malaria in pregnancy is a serious complication associated with parasitized erythrocyte (PE) sequestration in the placenta. Recent work suggests that var genes could play an important role in PE binding to chondroitin sulfate A (CSA), a primary placental adherence receptor. Here, we confirm that var2CSA is transcriptionally up-regulated in CSA-binding parasites and define CSA-binding domains in var2CSA. The identification of multiple binding domains in var2CSA strengthens the evidence for their involvement in malaria during pregnancy and may have applications for the development of a vaccine against malaria in pregnancy.

Dual action ectoparasite vaccine targeting 'exposed' and 'concealed' antigens.

Blood-feeding ectoparasites, such as mosquitoes, sandflies and ticks, transmit many disease agents. Their control relies on large-scale, repeated use of chemical pesticides. An alternative, targeted and environmentally friendly approach is to develop anti-ectoparasite vaccines. We describe a vaccine to control ticks that targets an 'exposed' tick saliva antigen and cross-reacts with 'concealed' tick midgut antigens. Ticks feeding on immunised animals induced a cutaneous inflammatory response and increased antibody titer, while engorged ticks died following damage to their midgut. This dual action, acting at the feeding site and in the midgut, offers a self-sustaining strategy for ectoparasite control boosted by natural infestations.