Establishment of cutaneous Leishmania enriettii infection in hamsters.

A model of a self-healing type of cutaneous leishmaniasis was established in hamsters using the guinea pig parasite Leishmania enriettii. L. enriettii was passaged several times in hamsters without losing its infectivity for guinea pigs or for hamsters. The course of the infection in hamsters resembled that of guinea pigs, with the exception that the lesion at the site of parasite inoculation did not ulcerate and no metastatic lesions developed spontaneously. Moreover, unlike guinea pigs, infected or recovered hamsters were skin test unresponsive to various preparations of L. enriettii antigens. However, histological examination of draining lymph nodes showed features of a cell-mediated immune response, and in vitro inhibition of macrophage migration was demonstrable using peritoneal exudate cells from recovered animals and specific leishmanial antigen. Antibody was demonstrable by indirect immunofluorescence starting 1 week after infection. Recovered animals were immune to reinfection; however, the passive transfer of peritoneal exudate cells or serum from recovered animals did not confer protection against L. enriettii infection in normal animals.     

Humoral and cellular immune response to a Microsporum canis recombinant keratinolytic metalloprotease (r-MEP3) in experimentally infected guinea pigs.

In order to better understand the host-fungus relationship in Microsporum canis dermatophytosis and to identify major fungal antigens, the immune response to a crude exoantigen preparation and to a purified recombinant keratinolytic metalloprotease (r-MEP3) was evaluated in guinea pigs experimentally infected with M. canis. Humoral and cellular immune responses were assessed from day 0 to day 57 post-infection (PI), the former by enzyme-linked immunosorbent assay (ELISA) and the latter via a lymphocyte proliferation assay. Infected guinea pigs developed humoral and cellular responses to both M. canis exoantigen and r-MEP3, while no specific immune response to these antigens was observed in control animals. This is the first report on the development of both humoral and cell-mediated immune responses to a purified keratinase in M. canis dermatophytosis.     

Antibody-mediated and delayed-type hypersensitivity reactions to Brucella skin test antigens in guinea pigs.

Cutaneous hypersensitivity responses to brucella antigens of different composition were studied in guinea pigs sensitized by infection with smooth brucella or immunization with killed rough brucella in adjuvant. These animals had circulating antibodies to smooth lipopolysaccharide or protein antigens, respectively. Intradermal skin tests, active cutaneous anaphylaxis, passive cutaneous anaphylaxis, and immunodiffusion tests were performed. Delayed-type hypersensitivity reactions uncomplicated by accompanying antibody-mediated reactions were seen only in infected guinea pigs with protein antigen that was entirely free of lipopolysaccharide. In the adjuvant-immunized animals, the protein antigen evoked overlapping antibody-mediated and delayed-type reactions. Lipopolysaccharide and polysaccharide preparations contained varying amounts of protein components. In infected animals, reactions of these antigens were clearly antibody mediated, but participation of delayed-type hypersensitivity could not be excluded. In adjuvant-immunized animals, the antibody-mediated reaction to the lipopolysaccharide preparation was caused by its protein component.     

Isolation of glycopeptides with skin test activity from dermatophytes.

By using ethylene glycol extraction of whole submerged cultures followed by Sephadex G-200 and diethylaminoethyl-Sephadex chromatography, we isolated four distinct glycopeptides from Trichophyton mentagrophytes, T. rubrum, and Microsporum canis. Chemical analyses revealed that these glycopeptides contained mostly carbohydrate (42.5 to 81.6%) and protein (4.3 to 11.3%), with lesser amounts of phosphorus (0.4 to 6.0%) and hexosamines (0.3 to 0.6%). Based upon total carbohydrate and monosaccharide content, these dermatophyte glycopeptides could be divided into two chemical groups: glucopeptides (DSI1) and mannopeptides (DSI2, DSII1, and DSII2). The mannopeptides and glucopeptides of each species of dermatophyte were not significantly different chemically from those derived from the other two dermatophyte species studied. Skin testing of DSI1-glycopeptides or DSI2-mannopeptides in immunized guinea pigs indicated that only the DSI2-mannopeptides elicited a delayed hypersensitivity reaction. Skin testing T. mentagrophytes 62-infected guinea pigs with the four purified DS-glycopeptides, as well as earlier fractions from the purification scheme, derived from T. mentagrophytes, T. rubrum, and M. canis, again indicated that only the DSI2-mannopeptides of the two Trichophyton species elicited a delayed hypersensitivity reaction. The number of infections or duration of infection had no effect on the size of the skin test response. DSI2-mannopeptides were non-cross-reactive between genera when tested in Trichophyton-immunized or -infected guinea pigs and Microsporum-immunized guinea pigs.     

Interactions Between Salmonellae and Macrophages of Guinea Pigs IV. Relationship Between Migration Inhibition and Antibacterial Action of Macrophages

The in vitro macrophage migration inhibition test was used to detect the development of delayed-type hypersensitivity in guinea pigs infected with Salmonella typhimurium. Four different preparations from supernatants of S. typhimurium cultures were used as the antigens in this test. They included the concentrated bacterial antigens, the high-molecular-weight (>50,000) antigens, the ammonium sulfate-precipitated antigens, and the ribonuclease-treated antigens. All four antigen preparations were shown to inhibit the migration of peritoneal macrophages of salmonella-infected (immune) guinea pigs from capillary tubes, in comparison with cells of normal control animals. By use of the high-molecular-weight antigens and the ammonium sulfate-precipitated antigens, the production of the migration inhibition factor(s) was elicited from cultures of lymphocytes obtained from the peripheral blood of immune guinea pigs. The activity of the migration inhibition factor(s) was demonstrated by its ability to inhibit the migration of peritoneal macrophages of normal guinea pigs from capillary tubes. In contrast, normal peritoneal macrophages exposed to products of antigen-stimulated immune lymphocytes did not exhibit an enhanced phagocytic or bactericidal action against virulent S. typhimurium as compared with those of the normal control. The present study indicated that the bacterial antigens responsible for the elicitation of the production of the migration inhibition factor from lymphocytes of immune guinea pigs are inactivated by proteolytic enzymes, but not by ribonuclease, and have molecular weights of >50,000.     

Cellular immunity to Legionella pneumophila in guinea pigs assessed by direct and indirect migration inhibition reactions in vitro

Spleen cell cultures from guinea pigs given legionella pneumophila vaccine in complete Freund adjuvant or as a sublethal infection were inhibited in their migration activity in vitro when incubated with specific antigen. Both direct and indirect migration inhibition assays revealed sensitization of the guinea pigs to the bacterium, with demonstrable reactivity 25 to 40 days or more after sensitization. No consistent reactions occurred when the guinea pigs were given the killed Legionella vaccine in incomplete Freund adjuvant in saline. However, spleen cells from guinea pigs injected with sublethal doses of the Legionella vaccine 3 to 4 weeks earlier showed positive migration inhibition factor reactivity. Cutaneous hypersensitivity and lymphocyte blastogenic responsiveness in vitro also developed in guinea pigs sensitized with killed Legionella vaccine in complete adjuvant or given a sublethal infection with the bacterium. These results indicate that in vitro assays for migration inhibitory activity may be utilized to monitor the development of the sensitization of guinea pigs to L. pneumophila, and such reactions correlate with skin reactivity and in vitro lymphocyte blastogenic responses.     

Delayed-type hypersensitivity measured as an increase of ear thickness in guinea pigs.

Determination of swelling at an intracutaneous test site in the pinna of the ear of guinea pigs immunized with protein antigens in complete Freund's adjuvant was found to be a more sensitive assay of delayed-type hypersensitivity than the measurement of flank skin erythema and induration. In fact, 100 times less specific antigen was needed to detect 24-hour reactivity in the pinna of the ear. Reactivity early after sensitization (cutaneous basophil hypersensitivity), however, was best revealed as an erythematous lesion of the flank skin 24 h after testing.     

In Vivo and In Vitro Studies of Delayed-Type Hypersensitivity to Toxoplasma gondii in Guinea Pigs

Delayed-type hypersensitivity develops late in the course of human toxoplasmosis, and a positive skin test is of some value for implicating chronic or eliminating acute forms of toxoplasmosis as a cause of disease. Toxoplasma-infected guinea pigs were studied to determine the onset and development of delayed-type hypersensitivity. Both the toxoplasmin skin test and the in vitro macrophage migration inhibition technique indicated that delayed hypersensitivity to toxoplasma antigen existed as early as 1 week after infection. The mechanism responsible for the observed inhibition of macrophage migration in vitro appeared to be an inhibitory factor(s) released from sensitized lymphoid cells in the presence of antigen.     

Cryptococcal culture filtrate antigen for detection of delayed-type hypersensitivity in cryptococcosis.

Previous studies on a cryptococcal culture filtrate (CneF) antigen have shown that the antigen is useful in detecting delayed-type hypersensitivity and that it is specific for Cryptococcus. This study further defined one more parameter of specificity, showing that the CneF antigen does not elicit delayed-type hypersensitivity responses in Cryptococcus albidus-sensitized guinea pigs. When the crude CneF antigen was subjected to ultrafiltration fractionation, the skin test active components were found to be in the 50,000 or greater molecular weight range fraction. The concentrated retentates of the XM50 ultrafiltration membrane were more sensitive antigens than the crude CneF antigens. Further fractionation of the XM50 retentate using 3% acrylamide gel electrophoresis separated the antigen into two bands. One band, the P fraction, migrated only a short distance into the gel; the fraction was carbohydrate-like and did not elicit significant skin test responses in sensitized guinea pigs. The other band, G fraction, appeared with the tracking dye, was glycoprotein-like, and elicited significantly positive skin tests in sensitized guinea pigs. G fractions prepared using three different serotypes of Cryptococcus neoformans elicited similar size indurations when used in skin testing guinea pigs sensitized with either the homologous serotype isolated of C. neoformans or the heterologous serotype isolate.     

Scanning electron microscopic observation on the parasitic form of the fungi in the horny layer in dermatophytosis

Electron microscopic techniques have been widely used to investigate the pathogenesis of dermatophytosis. In this article, morphological studies by scanning electron microscopy (SEM) and transmission electron microscopy (TEM) concerned with the dermatophyte infection process are literary reviewed and we introduced our morphological study observing the parasitic form of dermatophytes in the lesional cornified layer. Various experimental models have been established to study fungal adhesion and invasion to the skin surface in the early stage of infection by several authors.In these studies, arthroconidial adherence to corneocytes and germination was demonstrated by SEM and TEM. To understand the host-fungus relationship in dermatophytosis, it is also important to identify parasitic forms of fungi and morphological changes of corneocytes in the lesion. The three-dimensional structure of growing or parasitic dermatophytes in the lesional cornified cell layer was observed using the adhesive strip method in tinea cruris and tinea glabrosa. In tinea unguium, however, it is difficult to apply this method because of subungual hyperkeratosis. We introduce the alkaline treatment method for SEM for use in observing fungal elements in a subungual hyperkeratotic lesion and scales in dermatophytosis. With this technique, small pieces of nails or scales were fixed with 2.5% glutaraldehyde, and were treated with low concentrations of alkaline and subjected to the conventional procedure for SEM observation. This method is applicable to various skin lesions, such as tinea unguium, tinea pedis and tinea capitis to investigate the parasitic forms of dermatophytes and the spatial relationship with corneocytes and is useful to understand the infection process of dermatophytosis.     

Experimental infection and immune response of guinea pigs with varicella-zoster virus.

An immune response (fluorescent antibody to membrane antigen) was detected in guinea pigs inoculated with varicella-zoster virus (VZV) adapted to guinea pig embryonic cells, including the Oka vaccine strain, even when inoculation was by an external route, i.e., nasal or corneal. Live or UV-inactivated virus having the same virus titer before irradiation was administered to guinea pigs by the corneal route, and antibody induction was detected only with live virus. The transmission of VZV from infected guinea pigs to noninfected ones was suggested by the appearance of antibody in the serum of the latter, who were kept in the same cage. The time course of the appearance of humoral and cellular immune responses in guinea pigs was examined by the fluorescent antibody to membrane antigen test and the skin reaction, with varicella antigen representing delayed-type hypersensitivity. When VZV was injected subcutaneously, skin reaction appeared as early as 4 days after inoculation, which preceded the appearance of detectable antibody by 2 to 6 days. In in vitro studies, the Oka vaccine showed a higher adsorption rate and better growth in guinea pig embryonic cells than did other wild-type strains when assayed by the infectious center assay. These results suggest that a system of VZV adapted to guinea pig cells and guinea pigs provides a good animal experimental model for immunological study of VZV infection.     

In vitro and in vivo photosensitized inactivation of dermatophyte fungi by heterotricyclic dyes.

The ability of three heterotricyclic dyes to photosensitize dermatophyte fungi was studied with Trichophyton mentagrophytes and Microsporum gypseum. In vitro studies showed that methylene blue, neutral red, and proflavine were capable of killing these fungi when used in conjunction with broad-spectrum light. Proflavine, however, killed both fungi most rapidly and was used for further studies. Fungal killing by proflavine plus light was dependent on dye concentration, pH, light wavelength, and light intensity. Based on the in vitro studies, a treatment regimen was developed for in vivo use on experimentally infected animals. When treatment of guinea pigs inoculated with T. mentagrophytes was begun during fungal invasion, lesion formation at inoculated sites was either prevented or substantially reduced. When treatment was begun after lesion formation, however, light-plus-dyed treated sites showed only slightly faster curing than untreated sites.     

Immunological activity of a 14-kilodalton recombinant protein of Mycobacterium tuberculosis H37Rv.

A 14-kilodalton peptide antigen from Mycobacterium tuberculosis was isolated from an Escherichia coli lambda gt 11 recombinant DNA clone and was identified by Western blotting (immunoblotting) with monoclonal antibody TB68. Immunization of mice and guinea pigs with the recombinant peptide (rTB68) induced in vitro lymphoproliferative responses in draining lymph node lymphocyte cultures as well as in vivo delayed-type hypersensitivity reactions. Moreover, rTB68 was found both to induce and to cross-react with Mycobacterium leprae immune lymphocytes, but did not generate protective effects against live M. leprae challenge in mice. These findings showed that a 14-kilodalton peptide which has been characterized as specific for M. tuberculosis on the basis of B-cell recognition was capable of generating cell-mediated immune responses and moreover contained T-cell epitopes which were cross-reactive with M. leprae antigens.     

Ribosomes of Acid-Fast Bacilli: Immunogenicity, Serology, and In Vitro Correlates of Delayed Hypersensitivity

Ribosomal fractions obtained from Mycobacterium bovis (BCG) and M. smegmatis (strain butyricum) were studied to determine their antigenicity, their ability to stimulate the production of soluble mediators of delayed hypersensitivity (in vitro correlates) by sensitized peritoneal exudate cells, and the antigenic relations of ribosomal antigens of BCG to BCG protoplasm and H37Rv culture filtrates. The crude ribosomes and the 50-30S ribosomal subunit pool obtained from each of the organisms induced both delayed and immediate hypersensitivity when injected in incomplete Freund adjuvant into rabbits, and skin reactions could be elicited in sensitized rabbits with those antigens. The crude ribosomes and 50-30S ribosomal subunit pool of M. smegmatis stimulated lymphocytes of guinea pigs sensitized with viable organisms to produce macrophage migration inhibition factor. Comparable ribosomal fractions from BCG bacilli caused lymphocytes of guinea pigs sensitized with viable M. bovis (BCG) to produce skin reactive factor. Immunoelectrophoretic studies showed that H37Rv culture filtrate, protoplasm, crude ribosomes, and 50-30S ribosomal subunits of BCG contain multiple precipitinogens and that many of these were shared between the different antigen systems. Comparative electrophoresis revealed that BCG protoplasm and H37Rv culture filtrate shared a major portion of their components with each other and relatively few with ribosomal systems. The ribosomal systems shared the major portion of their components with each other and relatively few with the other antigen systems.     

Guinea pig cellular immune responses to proteins secreted by Mycobacterium tuberculosis.

To study the immunological activity of proteins secreted by Mycobacterium tuberculosis, we carried out comparative studies in guinea pigs infected intravenously with 2.5 x 10(3) CFU of this organism or with 2.5 x 10(4) CFU of Mycobacterium bovis BCG. Groups of infected guinea pigs were skin tested with fractions of secreted proteins covering well-defined narrow-molecular-mass regions, or such fractions were used for lymphocyte stimulation experiments. The lymphocyte stimulation experiments showed that the fraction containing proteins with molecular masses below 10 kDa had a superior stimulating capacity in tuberculous guinea pigs whereas the 24- to 30-kDa fraction gave significantly higher skin reactions in this group compared with BCG-vaccinated guinea pigs. A precise mapping within the region from 23 to 35 kDa by using a combination of narrow overlapping fractions and purified proteins enabled the identification of the 24-kDa antigen MPT64 as a molecule specific for tuberculous infection. Thus, MPT64 is a promising candidate for a specific diagnostic skin test reagent for human tuberculosis.     

Influenza virus infection of the guinea pig: Immune response and resistance

Guinea pigs were inoculated by intranasal inoculation with unadapted, influenza virus A/England/42/72, and virus was recovered from nasal washings between 3 and 10 days post-inoculation. Infected animals did not exhibit a febrile response to infection, did not produce local antibody and produced only relatively low levels of serum antibody. However, they developed delayed-type hypersensitivity to influenza virus, demonstrable by both skin tests and macrophage migration inhibition tests, which was similar to that of man. The relevance of the influenza virus specific delayed hypersensitivity in immunity to infection was examined in this model. Guinea pigs previously infected with virus or passively immunized with hyperimmune serum were relatively resistant to reinfection with influenza virus A/England/42/72. Inoculation of guinea pigs with spleen cells from immune donor animals, together with or without immune serum, did not give or enhance resistance to challenge virus infection. The results do not suggest a role for delayed hypersensitivity response in immunity to influenza virus infection.     

Delayed hypersensitivity responses in mice and guinea pigs to Mycobacterium leprae, Mycobacterium vaccae, and Mycobacterium nonchromogenicum cytoplasmic proteins.

Antigenic relationships between Mycobacterium vaccae, M. nonchromogenicum, and M. leprae were examined in mice and guinea pigs injected with M. vaccae or M. nonchromogenicum suspensions. The growth of both organisms in outbred ICR and four inbred mouse strains was followed up to 30 days. M. nonchromogenicum persisted in the livers and spleens of the inbred mice substantially better than did the M. vaccae population in the same mouse strains. A translucent colony variant of M. vaccae isolated from the opossum survived in vivo better than the opaque colony isolated from opossums and cattle. Persistence of M. vaccae and M. nonchromogenicum was not markedly increased in T-cell-depleted (nude) mice. Normal mice infected with increasing numbers of M. vaccae did not develop delayed-type hypersensitivity to the homologous M. vaccae cytoplasmic protein antigen. When heat-killed M. vaccae were incorporated into Freund adjuvant, both mice and guinea pigs developed delayed hypersensitivity to cytoplasmic antigens prepared from M. vaccae, M. nonchromogenicum and M. vaccae vaccines cross-sensitized guinea pigs to the M. leprae cytoplasmic antigens.     

Allergy and dermatophytes

Tinea pedis (athlete's foot) and onychomycosis (infection of the toenails) caused by the dermatophyte fungus Trichophyton are highly prevalent in adults. Several Trichophyton allergens have been identified based on elicitation of immunoglobulin E antibody-mediated immediate-hypersensitivity (IH) responses. Evidence of an etiologic role for Trichophyton in asthma in some subjects with IH and chronic dermatophytosis is provided by bronchial reactivity to Trichophyton. Improvement of asthma after systemic antifungal treatment corroborates this link. A unique feature of Trichophyton allergens is the ability of the same antigen to elicit delayed-type hypersensitivity (DTH) in individuals who lack IH reactivity. Delayed responses appear to confer protection, while IH responses do not, based on the association with acute versus chronic skin infection. The amino acid sequence identity of Trichophyton allergens with diverse enzyme families supports a dual role for these proteins in fungal pathogenesis and allergic disease. Characterizing the immunologic properties of Trichophyton allergens and defining immune mechanisms which drive dichotomous responses are pivotal to understanding the dermatophyte-allergy relationship. Recent studies have identified DTH-associated major T-cell epitopes which could facilitate the development of peptide vaccines. Characterization of additional molecular targets by using new techniques may aid not only in the eradication of infection but also in the resolution of allergic symptoms.