Early cell-mediated immune responses to Marek's disease virus in two chicken lines with defined major histocompatibility complex antigens.

N2a and P2a chickens, resistant and susceptible to Marek's disease (MD), respectively, were used to examine relationships between major histocompatibility complex (MHC)-restricted cytotoxic T lymphocytes (CTL) and natural killer (NK)-like cell activity with resistance to infection with Marek's disease virus (MDV). Ten-day-old chickens were infected with MDV and euthanatized at selected times to evaluate for NK cell and MHC-restricted cytotoxicity. The N2a MDV-infected chickens had an early cell-mediated immune response characterized by a sustained NK-like cytotoxicity that coincided with a measurable MHC-cytotoxicity that was lower than controls. Although MHC-restricted and NK cell cytotoxicity was demonstrated in P2a MDV-infected chickens at 8 dpi, both abruptly decreased and remained low for the remainder of the 20-day experiment. The critical time point that may determine the resistance to MD appears to be within the first 2 weeks post-infection. Improvement of the chicken NK cell activity may be a good candidate for both selection and immunomodulation MD control programs.

Autoantibodies in canine masticatory muscle myositis recognize a novel myosin binding protein-C family member.

Inflammatory myopathies are a group of autoimmune diseases that affect muscles. In humans, the most common inflammatory myopathies are polymyositis, dermatomyositis, and inclusion body myositis. Autoantibodies may be found in humans with inflammatory myopathies, and these play an important role in diagnosis and disease classification. However, these Abs are typically not muscle specific. Spontaneously occurring canine inflammatory myopathies may be good parallel disorders and provide insights into human myositis. In dogs with inflammatory myopathy, muscle-specific autoantibodies have been found, especially in masticatory muscle myositis. We have identified the major Ag recognized by the autoantibodies in canine masticatory muscle myositis. This Ag is a novel member of the myosin binding protein-C family, which we call masticatory myosin binding protein-C (mMyBP-C). mMyBP-C is localized not only within the masticatory muscle fibers, but also at or near their cell surface, perhaps making it accessible as an immunogen. The gene for mMyBP-C also exists in humans, and mMyBP-C could potentially play a role in certain human inflammatory myopathies. Understanding the role of mMyBP-C in this canine inflammatory myopathy may advance our knowledge of mechanisms of autoimmune inflammatory muscle diseases, not only in dogs, but also in humans.

Immunoblotting assays for keratan sulfate.

The detection of microquantities of glycosaminoglycans (GAGs) in biological samples has been hampered by the lack of sensitive methods. In this paper we describe the modification and development of three sensitive assays capable of detecting nanogram quantities of GAGs in biological samples. The first assay detects total GAGs. It is a modified Alcian blue dye precipitation assay in which the dye binds to the negatively charged GAGs in CsCl-fractionated extracts from chicken tendons. This assay compares favorably with the widely used uronic acid assay in terms of its sensitivity and ability to detect all classes of GAGs, including keratan sulfate (KS). Two other assays, dot-blotting and immunoblotting, detect KS in complex mixtures and can be easily adapted for the detection of other GAGs. Both take advantage of binding of carboxyl and sulfate groups of GAGs to trivalent neodymium. In dot-blotting, samples were directly blotted onto nitrocellulose membrane soaked in Nd(2)(SO(4))(3) buffer, and KS was detected with the monoclonal anti-KS 5-D-4 antibody and an avidin-biotin complex detection system. In immunoblotting, the samples were first separated in 28% polyacrylamide gels, transferred onto a Nd(2)(SO(4))(3)-soaked nitrocellulose membrane using a phosphate buffer system, and stained and developed using the same protocol as in dot-blotting. Whereas dot-blotting allows the use of very low quantities of samples because of its high sensitivity (lower detection limit was 5 ng), immunoblotting provides more specificity.

The effects of enrofloxacin on decorin and glycosaminoglycans in avian tendon cell cultures.

Tendonitis and tendon rupture have been reported to occur during or following therapy with fluoroquinolone antibiotics. Though the pathogenesis is unknown, several studies suggest that fluoroquinolone antibiotics alter proteoglycan content in soft tissues, including tendons, and thereby alter collagen fibrillogenesis. To better understand the mechanism of action of fluoroquinolones, we studied the effects of enrofloxacin, a widely used fluoroquinolone in veterinary medicine, on avian tendon cell cultures established from gastrocnemius tendons from 18-day-old chicken embryos. We found that cell proliferation was progressively inhibited with increasing concentrations of enrofloxacin. This was accompanied by changes in morphology, extracellular matrix content and collagen fibril formation as detected by electron microscopy. We also observed a 35% decrease in the content of total monosaccharides in enrofloxacin-treated cells. The ratio of individual monosaccharides was also altered in enrofloxacin-treated cells. Enrofloxacin also induced the synthesis of small amounts of keratan sulfate in tendon cells. Moreover we observed enrofloxacin-induced changes in glycosylation of decorin, the most abundant tendon proteoglycan, resulting in the emergence of multiple lower molecular bands that were identifiable as decorin after chondroitinase ABC and N-glycanase treatment of extracts from enrofloxacin-treated cells. Medium conditioned by enrofloxacin-treated cells contained less decorin than did medium conditioned by control cells. We hypothesize that enrofloxacin induces either changes in the number of N-linked oligosaccharides attached to the core protein of decorin or changes in decorin degradation process. In conclusion, our data suggest that enrofloxacin affects cell proliferation and extracellular matrix through changes in glycosylation.

Proteoglycans in chicken gastrocnemius tendons change with exercise.

Growth, loading, and mobilization lead to changes in tendon structure. Recent studies have shown that proteoglycans (PGs) regulate the organization of collagen fibrils, the main structural components of tendons. We hypothesized that moderate exercise alters PG synthesis in the avian gastrocnemius tendon. To test our hypothesis we compared the PG content in gastrocnemius tendons from control 6.5-week-old chickens with that in tendons from 6.5-week-old chickens that underwent exercise. Our results show high levels and a wide variety of glycosaminoglycans (GAGs) in 6.5-week-old tendons. Chondroitin-4-sulfate disaccharide was the major GAG disaccharide in control and exercised 6.5-week-old gastrocnemius tendons. Exercise led to an increase in the size of the tendons, the content of hyaluronic acid, and the level of decorin. High levels of keratan sulfate (KS) were found in the lower halves of gastrocnemius tendons, although the amount of KS decreased with exercise. This corresponded well with lower content of aggrecan in the lower halves of exercised tendons. In conclusion, our data support the hypothesis that exercise alters the content of PGs in chicken tendons.