Profiling the cellular immune response to multiple Brugia pahangi infections in a susceptible host.

Human lymphatic filariasis is caused primarily by Brugia malayi and Wuchereria bancroffi. Unraveling this disease is complex, as people living in endemic areas exhibit a vast array of clinical states and immune responses. The Mongolian gerbil (Meriones unguiculatus)-B. pahangi model of human lymphatic filariasis has provided much information on immune parameters associated with filarial infection. Prior investigations in our laboratory have shown that gerbils closely mimic a subset of patients classified as microfilaremic but asymptomatic, a group that comprises the majority of people living in endemic areas. Worm recovery data suggest that gerbils carrying current B. pahangi infections do not show any resistance to subsequent subcutaneous B. pahangi infections. The aim of the present studies was to investigate the T cell cytokine response in gerbils receiving multiple infections of B. pahangi as a means of mimicking the conditions experienced by people in endemic areas. The T cell cytokine profile generated by multiply infected gerbils was not different from that previously generated by gerbils infected only once with B. pahangi. Gerbils infected multiple times with B. pahangi showed a transient increase in IL-5, which corresponded to the increased eosinophil levels previously reported from multiply infected gerbils. Chronically infected gerbils showed elevated IL-4 mRNA levels, as has been reported from gerbils infected only once with B. pahangi. Chronic infections were also associated with a state of immune hyporesponsiveness, as determined by the characterization of lymphatic thrombi and lymphoproliferation of spleen and renal lymph node cells to worm antigen.

Kinetics of T cell cytokine gene expression in gerbils after a primary subcutaneous Brugia pahangi infection.

The majority of patients infected with lymphatic filariae are microfilaremic but tend to manifest little obvious pathology because of the infections. Data collected from the Mongolian gerbil-Brugia spp. model for human lymphatic filariasis suggest this experimental animal model system most closely represents this patient group and will be useful in studying immunological parameters associated with chronic infections. This article reports the quantitation of interleukin (IL)-4, IL-5, IL-10, IL-13, and interferon (IFN)-gamma messenger RNA (mRNA) in gerbils after a primary subcutaneous infection with Brugia pahangi. Chronically infected gerbils showed elevated IL-4 in all tissues, compared with earlier time points, linking this Th2 cytokine to the downregulation of responsiveness, which develops in gerbils and humans. Both IL-5 and IL-13 mRNA expression were transient in all tissues. The peak in IL-5 at 14-28 days postinfection reflects the peak of peripheral eosinophilia observed in B. pahangi-infected gerbils. Little IFN-gamma mRNA was reported from chronically infected gerbils. The data collected thus far suggest that the expression profile of many of the measured cytokines in B. pahangi-infected gerbils reflects what is seen in an important subset of humans infected with lymphatic filariae, the microfilaremic, asymptomatic patient.

The filarial endosymbiont Wolbachia sp. is absent from Setaria equina.

Wolbachia sp. was first reported in filarial nematodes over 25 yr ago. Today, much research is focused on the role of these bacteria in filarial worm biology. The filarial symbionts are closely related to arthropod symbionts, which are known to modify host reproduction and biology through various mechanisms. Similarly, it has been suggested that Wolbachia sp. is essential for long-term survival and reproduction of filariae. We report that Wolbachia sp. 16S rDNA was not found in the equine filarial nematode Setaria equina, using either polymerase chain reaction (PCR) or DNA hybridization. In addition, ultrastructural analysis of adult worms did not reveal the presence of Wolbachia sp. in hypodermal cords or reproductive tissues. These data suggest that like Onchocerca flexuosa and Acanthocheilonema vitae, S. equina may not be dependent on Wolbachia sp. for survival.

Killing of Borrelia burgdorferi by antibody elicited by OspA vaccine is inefficient in the absence of complement.

A Lyme disease vaccine, based on the Borrelia burgdorferi lipoprotein OspA, has recently undergone phase III trials in humans. The results of one of these trials indicate that vaccine efficacy positively correlates with anti-OspA antibody titer. Spirochete killing within the tick vector midgut, upon which vaccine efficacy appears to depend, may occur chiefly via a mechanism that involves antibody alone, as it has been reported that complement is degraded by tick saliva decomplementing factors. We compared the in vitro killing efficiencies of anti-OspA antibody elicited in rhesus monkeys by the OspA vaccine, in the presence and in the absence of monkey complement. Killing in the absence of complement was between 14 and 3,800 times less efficient than with complement present, depending on the spirochete strain. The relative inefficiency of the complement-independent killing mechanism by anti-OspA antibody may explain why OspA vaccine efficacy is critically dependent on antibody titer.

Cryptic and exposed invariable regions of VlsE, the variable surface antigen of Borrelia burgdorferi sl.

Borrelia burgdorferi, the Lyme disease spirochete, possesses a surface protein, VlsE, which undergoes antigenic variation. VlsE contains two invariable domains and a variable one that includes six variable and six invariable regions (IRs). Five of the IRs are conserved among strains and genospecies of B. burgdorferi sensu lato. IR(6) is conserved, immunodominant, and exposed at the VlsE surface but not at the spirochete surface, as assessed in vitro. In the present study, the remaining conserved IRs (IR(2) to IR(5)) were investigated. Antisera to synthetic peptides based on each of the IR(2) to IR(5) sequences were produced in rabbits. Antipeptide antibody titers were similarly high in all antisera. Native VlsE was immunoprecipitable with antibodies to IR(2), IR(4), and IR(5) but not to IR(3), indicating that the first three sequences were exposed at the VlsE surface. However, negative surface immunofluorescence and in vitro antibody-mediated killing results indicated that none of the IRs were accessible to antibody at the spirochetal surface in vitro.

An immunodominant conserved region within the variable domain of VlsE, the variable surface antigen of Borrelia burgdorferi.

Antigenic variation is an effective strategy evolved by pathogenic microbes to avoid immune destruction. Variable Ags such as the variable major protein of Borrelia hermsii, the variant surface glycoprotein of African trypanosomes, and the pilin of Neisseria gonorrhoeae include an immunodominant variable domain and one or more invariable domains that are not antigenic. Short, nonantigenic, invariable regions also may be present within the variable domain. VlsE (variable major protein-like sequence, expressed), the variable surface Ag of Borrelia burgdorferi, the Lyme disease spirochete, also contains both variable and invariable domains. In addition, interspersed within the VlsE variable domain there are six invariable regions (IR1-6) that together amount to half of this portion's primary structure. We show here that these IRs are conserved among strains and genospecies of the B. burgdorferi sensu lato complex. Surprisingly, unlike the invariable regions of variable major protein, variant surface glycoprotein, and pilin, which are not antigenic in natural infections, the most conserved of the IRs, IR6, is immunodominant in Lyme disease patients and in monkeys infected with B. burgdorferi. IR6 is exposed on the surface of VlsE, as assessed by immunoprecipitation experiments, but is inaccessible to Ab on the spirochete's outer membrane, as demonstrated by immunofluorescence and in vitro killing assays. VlsE thus significantly departs from the antigenic variation paradigm, whereby immunodominance is only manifest in variable portions. We submit that IR6 may act as a decoy epitope(s) and contribute to divert the Ab response from other, perhaps protective regions of VlsE.