Tick saliva in anti-tick immunity and pathogen transmission

When feeding on vertebrate host ticks (ectoparasitic arthropods and potential vectors of bacterial, rickettsial, protozoal, and viral diseases) induce both innate and specific acquired host-immune reactions as part of anti-tick defenses. In a resistant host immune defense can lead to reduced tick viability, sometimes resulting in tick death. Tick responds to the host immune attack by secreting saliva containing pharmacologically active molecules and modulating host immune response. Tick saliva-effected immunomodulation at the attachment site facilitates both tick feeding and enhances the success of transmission of pathogens from tick into the host. On the other hand, host immunization with antigens from tick saliva can induce anti-tick resistance and is seen to be able to induce immunity against pathogens transmitted by ticks. Many pharmacological properties of saliva described in ticks are shared widely among other blood-feeding arthropods.     

Anaplasma phagocytophilum subverts tick salivary gland proteins

Anaplasma phagocytophilum is a bacterium that is transmitted by Ixodes spp. ticks, in which it resides in salivary glands. Ticks inoculate the pathogen into hosts together with an array of salivary molecules that reduce host anti-tick inflammation. Sukumaran et al. recently showed that A. phagocytophilum uses a tick salivary protein, Salp16, to enhance its uptake from the host and into the salivary gland. Occupation and exploitation of tick salivary glands have implications for the maintenance and detection of A. phagocytophilum in its vector and early pathogen interactions with its hosts.     

The impact of gene knock-down and vaccination against salivary metalloproteases on blood feeding and egg laying by Ixodes ricinus

Two cDNAs coding homologous putative metalloproteases (Metis 1 and Metis 2, expected molecular weights of 55.6 and 56.0kDa, respectively) were identified from the hard tick Ixodes ricinus. The expression of Metis genes was induced in salivary glands during tick blood meal. RNA interference was used to assess the role of both Metis 1 and Metis 2 in tick feeding. It was found that salivary gland extracts lacking Metis 1-2 had a restricted ability to interfere with fibrinolysis. RNAi against Metis 1-2 also induced a high mortality rate. An immune reaction was raised in repeatedly bitten animals against Metis 1 and 2. Vaccination of hosts with the recombinant Metis 1 protein produced in a eukaryotic system partially interfered with completion of the blood meal. Although vaccination did not alter the survival rate or feeding time of ticks, their weight gain and oviposition rate were reduced. This will affect their reproductive fitness in the field. We believe this is the first report of an anti-tick vaccine trial using a metalloprotease derived from I. ricinus.     

Nestling development and the timing of tick attachments

Parasites exposed to fast-developing hosts experience a variety of conditions over a short time period. Only few studies in vertebrate-ectoparasite systems have integrated the timing of ectoparasite infestations in the host's development into the search for factors explaining ectoparasite burden. In this study we examined the temporal pattern of attachment in a nidicolous tick (Ixodes arboricola) throughout the development of a songbird (Parus major). In the first experiment, we exposed bird clutches at hatching to a mix of the 3 tick instars (larvae, nymphs and adults), and monitored the ticks that attached in relation to the average broods' age. In a complementary experiment we focused on the attachment in adult female ticks--the largest and most significant instar for the species' reproduction--after releasing them at different moments in the nestlings' development. Our observations revealed a positive association between the size of the attached instar and the broods' age. Particularly, adult females were less likely to be found attached to recently hatched nestlings, which contrasts with the smaller-sized larvae and nymphs. These differences suggest either an infestation strategy that is adapted to host physiology and development, or a result of selection by the hosts' anti-tick resistance mechanisms. We discuss the implications of our results in terms of tick life-history strategies.     

Characterization of tick antigens inducing host immune resistance. I. Immunization of guinea pigs with Amblyomma americanum-derived salivary gland extracts and identification of an important salivary gland protein antigen with guinea pig anti-tick antibodies

Guinea pigs immunized by subcutaneous injection of an emulsion of incomplete Freund's adjuvant (IFA) containing tick salivary gland extract antigens (SGA) from partially fed female ticks expressed a significant level of tick rejection when challenged 17 days later. This level of tick rejection was similar to animals actively sensitized by tick feeding and challenged at the same time. SGA emulsified with complete Freund's adjuvant (CFA) or administered with saline was ineffective. However, ticks that fed on animals immunized with SGA+IFA or SGA+CFA expressed significant reductions in engorgement weight. SGA was active when prepared with or without protease inhibitors. The minimum effective immunizing dose of SGA was between 100 and 280 micrograms per animal. Extracts made from salivary gland-derived cement material (CA) from partially fed female ticks administered at 50 micrograms in IFA induced levels of tick rejection comparable to animals immunized with 280 micrograms of SGA+IFA. Sodium dodecylsulfate polyacrylamide gel electrophoresis (SDS/PAGE) of 35S- and 125I-radiolabeled SGA and CA extracts immunoprecipitated by guinea pig anti-tick serum that transferred immune resistance demonstrated a unique protein of 20,000 m.w. Serum from animals immunized with SGA+IFA (successful immunization) recognized this same protein, whereas serum from animals immunized with SGA+CFA (unsuccessful immunization) did not. The results of this study suggest that a 20,000 m.w. protein derived from the tick salivary gland may be responsible for the induction and perhaps elicitation of host immune resistance responses to Amblyomma americanum ticks.     

Amblyomma americanum (L): Tick macrophage migration inhibitory factor peptide immunization lengthens lone star tick feeding intervals in vivo

Immunizations of New Zealand White rabbits with specific macrophage migration inhibitory factor (MIF) tick peptide (PEP) produced circulating anti-tick PEP antibodies in the hosts. Antibody titers of greater than 1:5000 to tick MIF peptide were observed for crude sera from PEP-immunized rabbits. PEP- and BSA-vaccinated rabbits were infested with Amblyomma americanum adults. Feeding intervals, female weights, egg masses and percent egg hatch were measured for ticks feeding on control and immunized hosts. Feeding intervals were significantly lengthened to 13.3 days for PEP-vaccinated hosts compared to BSA-vaccinated controls at 12.4 days, while female engorgement weights and egg masses were unchanged. By immunizing hosts using specific tick PEP, we were able to alter the length of time the ticks fed on their hosts.     

Amblyomma americanum: physiochemical isolation of a protein derived from the tick salivary gland that is capable of inducing immune resistance in guinea pigs

Crude salivary gland derived proteins from Amblyomma americanum ticks were analyzed by physiochemical (gel filtration and ion exchange chromatography) and immunochemical guinea pig IgG1 (anti-tick immunoaffinity column) techniques for the presence of antigens responsible for the induction of host immune resistance responses. Gel filtration (G-75 Sephadex) and ion exchange (diethyl aminoethyl cellulose) chromatography of crude salivary gland antigen yielded multiple fractions, but only one fraction from each procedure induced significant cutaneous anaphylaxis bluing reactions when used for skin tests in tick sensitized animals treated intravenously with 0.5% Evans blue dye. Salivary gland antigen (200 ng) eluted from the immunoaffinity column by 0.2 M Na2CO3, pH 11.3, and emulsified with incomplete Freund's adjuvant conferred a significant level of tick rejection (24%, P less than 0.001) on naive guinea pigs compared with that seen in controls, but less than (P less than 0.01) the level of immunity conferred by crude salivary gland antigen (380 micrograms). The immunizing dose of immunoaffinity purified salivary gland antigen was 1/1900 the dose of the crude antigen preparation representing 99.9% purification. Furthermore, engorged ticks from animals immunized with salivary gland antigen exhibited a significant decrease (P less than 0.001) in weight compared with ticks from naive animals. Sodium dodecyl sulfate-polyacrylamide gel electrophoresis of 125I labeled proteins in the Na2CO3 eluate and the skin reactive fraction from gel filtration and ion-exchange chromatography, after immunoprecipitation with a guinea pig IgG1 antibody to the tick that transferred resistance, revealed the presence of a 20 kDa weight protein reported previously to be the antigen responsible for the induction of host resistance. These studies present physiochemical and immunochemical procedures for the purification of an important tick protein that induces skin reactions in tick sensitized guinea pigs, is recognized by antibody to the tick, and most importantly, is capable of immunizing naive guinea pigs against tick challenge.     

Investigations into lymphocyte transformation and histamine release by basophils in sheep repeatedly infested with Rhipicephalus evertsi evertsi ticks

The immune response of a natural host of Rhipicephalus evertsi evertsi to feeding by this tick species was investigated with respect to the effects of tick salivary gland extracts on the transformation of peripheral blood lymphocytes and the release of histamine by basophils obtained from repeatedly infested sheep.The results indicated that there was no stimulation of lymphocyte transformation but that histamine release was elevated 10 fold after four infestations.Although this suggests a hypersensitivity reaction, believed to be a major factor in resistance to tick feeding, it was observed that ticks fed normally even after four infestations with 28 day intervals in between. These results emphasize the adaptation of ticks to feeding on their natural hosts.     

Generalized selection to overcome innate immunity selects for host breadth in an RNA virus

Virus‐host coevolution has selected for generalized host defense against viruses, exemplified by interferon production/signaling and other innate immune function in eukaryotes such as humans. Although cell‐surface binding primarily limits virus infection success, generalized adaptation to counteract innate immunity across disparate hosts may contribute to RNA virus emergence potential. We examined this idea using vesicular stomatitis virus (VSV) populations previously evolved on strictly immune‐deficient (HeLa) cells, strictly immune competent (MDCK) cells, or on alternating deficient/competent cells. By measuring viral fitness in unselected human cancer cells of differing innate immunity, we confirmed that HeLa‐adapted populations were specialized for innate immune‐deficient hosts, whereas MDCK‐adapted populations were relatively more generalized for fitness on hosts of differing innate immune capacity and of different species origin. We also confirmed that HeLa‐evolved populations maintained fitness in immune‐deficient nonhuman primate cells. These results suggest that innate immunity is more prominent than host species in determining viral fitness at the host‐cell level. Finally, our prediction was inexact that selection on alternating deficient/competent hosts should produce innate viral generalists. Rather, fitness differences among alternating host‐evolved VSV populations indicated variable capacities to evade innate immunity. Our results suggest that the evolutionary history of innate immune selection can affect whether RNA viruses evolve greater host‐breadth.     

Perspectives of creation of vaccines against tick bite for nonspecific prophylaxis of vector borne diseases

Prophylaxis of infectious diseases transferred by ticks is an important problem of contemporary medicine. One of the perspective approaches to solve this problem is the creation of vaccines against tickbite (anti-tickvaccines). Contemporary methods of the control of infectious diseases transferred by ticks are described in the review. Features of naturally and artificially acquired immunity against ticks are examined. Candidate tick antigens for the construction of vaccines against genus Ixodes tick bite are described. Perspectives of use of anti-tick vaccines against tick vector borne diseases are evaluated.     

Factors influencing the toxicity of salivary gland extracts of Ixodes holocyclus Neumann

A bioassay using mice was developed to compare the toxin content of extracts of salivary glands of I. holocyclus at various stages of feeding. The quantity of toxin increased rapidly from the third day of feeding. Toxin production continued and increased in ticks removed after 3–5 days on mice and held at 30°C at 92% RH for 24 h, whereas no toxin was detected in the salivary glands of ticks fed for 3 days and treated similarly. It is suggested that major physiological changes occur in the salivary glands of I. holocyclus on the third day, which once stimulated continue independently of feeding. Toxin production in ticks was not suppressed by passively immunizing mice with anti-tick toxin but was in ticks fed upon hosts with a previous experience of tick feeding.Thus, to obtain salivary glands containing high concentrations of toxin for chemical analysis, it is necessary for salivary glands to develop 5 days from the initial attachment of the tick to a host with no previous experience of tick feeding. This can be achieved by passively immunizing mice against toxin, thus enabling the tick to feed 5 days without killing the mouse or by keeping the tick for 24 h at 30°C at 92% RH following the death of the mouse on the fourth day.     

Genetic variation at the vlsE locus of Borrelia burgdorferi within ticks and mice over the course of a single transmission cycle

The Lyme disease spirochete, Borrelia burgdorferi, causes a persistent infection in the vertebrate host even though infected animals mount an active immune response against the spirochete. One strategy used by the spirochete to evade vertebrate host immunity is to vary the structure and expression of outer membrane antigens. The vlsE locus represents the best-studied example of antigenic variation in B. burgdorferi. During vertebrate host infection, recombination between the active vlsE locus and silent, partial vlsE copies leads to gene conversion events and the generation of novel alleles at the expression site. In the present study, we followed a population of B. burgdorferi organisms moving through vertebrate host and tick stages to complete one transmission cycle. The major goal of the study was to determine if the vlsE locus was subject to different selective pressure and/or recombination frequency at different stages of the spirochete's life cycle. We report here that the vlsE genetic diversity generated within the rodent host was maintained through the larval and nymphal tick stages. Therefore, naturally infected ticks are likely to transmit spirochete populations with multiple vlsE alleles into naive vertebrate hosts. Although vlsE genetic diversity in mice was maintained through tick stages, the dominant vlsE alleles were different between tick stages as well as between individual ticks. We propose that population-level bottlenecks experienced by spirochetes, especially during the larval-to-nymphal molt, are responsible for individual infected ticks harboring different dominant vlsE alleles. Although vlsE genetic diversity is maintained through tick stages, the VlsE protein is unlikely to be of functional importance in the vector, because the protein was expressed by very few (<1%) bacteria in the vector.     

Expression of acquired immunity to immature stages of the tick Rhipicephalus evertsi evertsi by rabbits and guinea-pigs

Acquired immunity in guinea-pigs and rabbits to immature stages of the two-host tick Rhipicephalus evertsi evertsi Neumann was demonstrated. Repeated infestations of both hosts with larvae resulted in a significant reduction in the weight of later engorged nymphs. A sharp decline in the numbers of nymphs which successfully fed on both hosts was also observed. This study provides evidence for a gradual decrease in the mean weight of engorged nymphs towards the end of the detachment period suggesting that, in two-host ticks, the onset of nymphal feeding acts as an immune booster in a host already primed by the larval feed and that this results in a reduced feeding performance.     

Interspecific variations in attachment sites and density assessment in femaleIxodes rubicundus (Acari: Ixodidae) on domestic and natural hosts

The attachment sites of female Karoo paralysis ticks (Ixodes rubicundus) and equations to assess tick burdens on domestic (sheep and goats) and natural (mountain reedbuck) hosts were determined. No intraspecific differences in attachment sites for Merino sheep and Angora goats could be observed, but interspecific differences were evident.Ixodes rubicundus in general attaches on the ventral aspects of the host. More than 50% of these ticks attached to the fron quarters of the body of the domestic host, and 60% to the hindquarters of the natural host. The length of Merino sheep wool had no affect on either the attachment site or number of attached ticks. In general, more ticks were found attached to the woollen than non-woollen body areas. Equations are provided which can estimate tick burdens on hosts by counting the ticks on two or three selected body areas of the host. To facilitate sampling procedures, approximate sample sizes for the various hosts needed to estimate average tick burdens have been provided. Depending on the level of precision required (with bounds on the error of estimation equal to 1, 2 or 5 ticks), the number of animals in a flock of 200 Angora goats that must be examined varied from 26 to 85.     

Experimental evidence for host preference in a tick parasitizing songbird nestlings

Mechanisms of host preference in ectoparasites are important to the understanding of host‐parasite interactions. Since ectoparasites negatively affect the condition of their hosts, while the hosts’ condition itself may affect the parasites’ choice, separating the factors that drive host preference from parasite impact asks for experiments. We combined the data of two choice experiments to investigate the preference of the nidicolous tick Ixodes arboricola when exposed to the nestlings of a passerine bird (Parus major). In the first experiment, in which complete broods at hatching were exposed to an ecologically relevant number of ticks, the relationship between tick loads and nestlings’ developmental status was characterized by a distribution with the highest tick loads on the more developed nestlings. Host preference became more apparent at a smaller brood size, suggesting a role for host density. In a second experiment we evaluated host choice in a pairwise choice experiment, exposing pairs of siblings with contrasting developmental status to eight ticks. In the first and the second pair, a median developed nestling was linked with the most developed and the least developed nestling, respectively. Seventy‐two h after tick exposure we measured the innate constitutive humoral immunity and haematocrit. No differences were found in innate immunity, but the least developed nestlings had on average a lower haematocrit than the median and most developed nestlings. Significantly fewer ticks attached on the least developed nestling compared to the median nestling, and this difference was more pronounced when the innate immunity of the median developed nestling was higher. No difference in tick load was found among the median and best developed nestlings. The linkage between host preference and host physiological condition provide further insight in the mechanisms driving ectoparasite aggregation, which is important for the population dynamics of host, ticks and tick‐transmitted pathogens.     

共生菌与昆虫的免疫

共生菌可通过产生抗菌物质、调控宿主免疫相关基因和微生物种间竞争作用等方式保护昆虫宿主免受病原体的侵染。为维持共生关系,昆虫进化出精细的调控机制避免对共生菌的过激免疫应答,共生菌通过免疫识别信号多态性或化学拟态来降低或躲避宿主免疫系统对自身的伤害。本文在分析共生菌对宿主免疫的功能及其机制的基础上,探讨宿主对免疫应答的精准调控以及共生体系的协同进化,以期为共生菌对宿主免疫影响的深入研究提供参考。     

Vaccination with 'concealed' antigens for tick control

Ticks are responsible for substantial economic losses to the livestock industry, necessitating intensive use of chemical acoricides in many parts of the world. Problems of chemical residues, cost of acoricides, and development of resistance by ticks, have long been recognized and have helped to stimulate interest in tick control by immunological means (see Box 1). One approach has been to seek ways to enhance the natural immunity often acquired by animals in response to tick infestation. An alternative, discussed here by Peter Willadsen and David Kemp, is to vaccinate with 'concealed' tick antigens not normally encountered by the host, and so stimulate a different immune effector mechanism.     

Ecology of Anaplasma phagocytophilum and Borrelia burgdorferi in the western United States.

We discuss the ecology of Anaplasma phagocytophilum and Borrelia burgdorferi in the western U.S. These agents, while emerging in the eastern U.S., remain stable or rare in the west. In the western U.S., tick vectors and mammalian hosts for B. burgdorferi and A. phagocytophilum are distinct from those in the eastern U.S. and considerably more variable. Spatial complexity, local extinctions, and low levels of movement among foci may determine the distribution and prevalence of these agents. High-prevalence A. phagocytophilum patches may be transient, possibly as host individuals become immune. Thus, A. phagocytophilum in California could exist in a metapopulation of interacting patches. Local dynamics are sensitive to host population sizes and minimum tick infestation levels. Determining critical values for these key factors and their interactions will be important for predicting the level and distribution of future infections in the western U.S.