Immunophenotypic analysis of foal bronchoalveolar lavage lymphocytes.

The purpose of this study was to define the normal immunophenotype of equine lymphocytes present within the pulmonary air spaces, and to determine if this changes as foals age from one to ten weeks. Six pairs of mares and foals underwent sequential bronchoalveolar lavage (BAL) between 1 and 10 weeks of age. Data were grouped according to foal age (1, 1-3, 3-6, or 6-10 weeks of age) and were compared to adult control values obtained from the mares. BAL cells were harvested and stained with antibodies to the equine homologues of CD5, CD4, CD8, CD44, MHC I, MHC II and to equine IgG. Data, including percent positive staining and mean fluorescence intensity, were acquired on a flow cytometer gated for viable lymphocytes. All foals had significantly fewer CD5+ lymphocytes than mares, with the largest differences in the youngest animals. The percentage of CD4+ lymphocytes increased as the foals aged, approaching adult levels by 3 weeks of age, while the percentage of CD8+ lymphocytes increased more slowly and approached adult levels by 10 weeks of age. The CD4:CD8 ratio changed from 1.26 at one week of age to 0.78 by 10 weeks of age, compared to an adult value of 0.66. Lymphocytes from foals less than 6 weeks of age expressed MHC II and CD44 at lower levels than adults. The lymphocytic populations within the airways of foals are significantly different from adult animals. This may account for the susceptibility of foals to certain respiratory infections during the first few months of life.

Role of CD4+, CD8+ and double negative T-cells in the protection of SCID/beige mice against respiratory challenge with Rhodococcus equi.

To evaluate the contributions of T-lymphocyte subsets in pulmonary immunity against Rhodococcus equi, C.B-17 SCID/beige mice were adoptively transferred with splenic lymphocytes from congenic BALB/c mice previously infected with R. equi. Spleen cells were enriched for either CD4+ or CD8+ populations before inoculation, Flow cytometry showed that each enriched population contained less than 0.5% cross contamination. Groups of adoptively transferred SCID/beige mice were sacrificed 6 and 13 d after intranasal infection with R. equi. Bacterial clearance was measured in the lungs, liver and spleen. Lesion development was assessed by gross and histopathological score and the fate of transferred cells assessed by flow cytometry and by immunohistochemistry. SCID/beige mice receiving either CD4+ or CD8+ T-cells were able to clear the infection better than control mice. On d 6 post-infection, bacterial numbers were significantly lower in the lungs of CD4+ transferred mice as compared to CD8+ mice. By d 13, both groups had cleared R. equi from all organs. CD4+ cells were however identified in the lung and spleen of CD8+ recipients at d 13 making conclusions about the role of CD8+ cells in R. equi clearance impossible. By contrast, no significant increases in CD8+ lymphocytes were observed in the organs of CD4+ recipients. All mice developed suppurative bronchopneumonia but lesions were most severe in the CD4+ group. Immunohistochemistry and flow cytometry confirmed that CD4+ and CD8+ cells had migrated to the lungs of adoptively transferred mice. Serum antibody against R, equi was not detected by ELISA in the recipients. SCID/beige mice receiving CD4-CD8- cells were unable to clear R. equi. The study supports the suggestion that CD4+ cells have a central role in R. equi clearance in mice.

Demonstration of equine immunoglobulin in sera from severe combined immunodeficiency/beige mice inoculated with equine lymphocytes.

Peripheral blood lymphocytes were isolated from four normal adult horses on Ficoll-Hypaque density gradients for intraperitoneal inoculation into 16 C.B-17 severe combined immunodeficiency/beige mice in an attempt to create a xenogeneic lymphoid chimera for modeling the equine immune system. The recipient mice had been preconditioned by prior exposure to 200 cGy of gamma irradiation. The mice were monitored for the presence of equine IgG using an ELISA technique. Equine IgG was detected in the sera of 91.7% of murine recipients and in at least one mouse inoculated from each donor horse. The levels of IgG detected in the mice ranged from 2 micrograms ml-1 to over 1000 micrograms ml-1 and showed steady decline from the time of inoculation to the end of the trial. The half-life of equine IgG in the SCID/beige mouse was determined to be 12.1 days by the intravenous injection of 9.1 mg of semi-purified equine IgG into 21 normal SCID/beige mice and taking serial blood samples to obtain the decay curve. The half-life of equine IgG was compared with the extinction curve obtained for the engrafted mice and showed that continuous production within the mice must have been occurring since the slopes of the two lines were different. These results are compared with those achieved in equine PBL-SCID/beige chimeras not preconditioned by irradiation and to those achieved in human and bovine PBL-SCID chimeras.

The effect of experimental infection with Rhodococcus equi on immunodeficient mice.

To investigate the pathogenesis of respiratory lesions caused by the facultative intracellular pathogen, Rhodococcus equi, pulmonary clearance was compared in four groups of genetically defined mice, chosen for their specific deficits in immune and inflammatory responses. Complement-deficient A/J, immunodeficient nu/nu (nude), scid/scid.bg/bg (SCID/beige), C57BI/6J.bg/bg (beige) and normal Swiss mice (SW) received approximately 10(7) R. equi intranasally on day 0. Bacterial clearance was assessed in lung, liver and spleen on days 1, 4, 7 and 14. Pulmonary clearance was not significantly different between SW and A/J mice. Beige mice cleared R. equi more rapidly and completely than A/J and SW, indicating that deficits in phagocytic and NK cell function associated with the bg/bg gene did not compromise clearance. Pulmonary clearance in immunodeficient SCID/beige mice paralleled that of the SW and A/J mice initially but bacterial proliferation produced significant differences from SW mice at day 14. Nude mice were unable to clear R. equi from day 1, resulting in the death of two nude mice at day 11. Both SCID/beige and nude mice developed severe pyogranulomatous bronchopneumonia, whereas A/J and SW mice developed transient pulmonary lesions. Beige mice developed minimal lung lesions. Significant systemic bacterial proliferation occurred only in nude and SCID/beige mice. We conclude that deficiencies in complement components, phagocytic and NK cells do not impair the pulmonary clearance of R. equi but that a competent cellular immune system is required to prevent pneumonia and death. The difference in early phase pulmonary clearance in nude and SCID/beige mice indicates two phases are important for clearance. An acapsular mutant of R. equi was completely cleared from the lungs of SCID/beige mice suggesting an important role for the capsule in virulence for mice.