David J. Prieur

Trichinella spp.: differential expression of acid phosphatase and myofibrillar proteins in infected muscle cells.

Major alterations are induced in muscle cells infected by either Trichinella spiralis or Trichinella pseudospiralis. To investigate the response of muscle to these infections we have analyzed the expression of acid phosphatase (ACP, EC 3.1.3.2), adult skeletal muscle myosin heavy chain, and muscle tropomyosin proteins in infected mouse skeletal muscle cells. Using T. spiralis-infected cells, we provide strong evidence that the tartrate-sensitive ACP of these cells was synthesized by the infected cell and localized in lysosomes. Isoenzyme analysis indicated that the ACP activity was of host muscle cell origin and the specific activity of this ACP was 2.5 times greater than that in associated inflammatory cells. Increased ACP activity was also demonstrated in muscle cells infected by T. pseudospiralis. In synchronized muscle infections, increased ACP activity was detected at 5 days post-muscle infection for both parasites. ACP activity was further increased in infected muscle cells at later times tested. This increased infected cell ACP activity represents the earliest positive enzyme marker yet described indicating expression of the infected cell phenotype. In contrast, myofibrillar proteins were not detected in muscle cells chronically infected by T. spiralis but were detected in muscle cells infected by T. pseudospiralis. Decrease in myofibrillar protein levels was detected by 10 days post-muscle infection by T. spiralis. The data presented demonstrate significant differences and similarities in the phenotypes of muscle cells infected by these two parasites and establish criteria that could facilitate identification of parasite factors that may be involved in these phenomena.

Presentation and Binding Affinity of Equine Infectious Anemia Virus CTL Envelope and Matrix Protein Epitopes by an Expressed Equine Classical MHC Class I Molecule

Control of a naturally occurring lentivirus, equine infectious anemia virus (EIAV), occurs in most infected horses and involves MHC class I-restricted, virus-specific CTL. Two minimal 12-aa epitopes, Env-RW12 and Gag-GW12, were evaluated for presentation by target cells from horses with an equine lymphocyte Ag-A1 (ELA-A1) haplotype. Fifteen of 15 presented Env-RW12 to CTL, whereas 11 of 15 presented Gag-GW12. To determine whether these epitopes were presented by different molecules, MHC class I genes were identified in cDNA clones from Arabian horse A2152, which presented both epitopes. This horse was selected because it is heterozygous for the SCID trait and is used to breed heterozygous females. Offspring with SCID are used as recipients for CTL adoptive transfer, and normal offspring are used for CTL induction. Four classical and three putative nonclassical full-length MHC class I genes were found. Human 721.221 cells transduced with retroviral vectors expressing each gene had equine MHC class I on their surface. Following peptide pulsing, only cells expressing classical MHC class I molecule 7-6 presented Env-RW12 and Gag-GW12 to CTL. Unlabeled peptide inhibition of 125I-labeled Env-RW12 binding to 7-6-transduced cells demonstrated that Env-RW12 affinity was 15-fold higher than Gag-GW12 affinity. Inhibition with truncated Env-RW12 demonstrated that amino acid positions 1 and 12 were necessary for binding, and single substitutions identified positions 2 and 3 as possible primary anchor residues. Since MHC class I 7-6 presented both epitopes, outbred horses with this allele can be immunized with these epitopes to optimize CTL responses and evaluate their effectiveness against lentiviral challenge.

Ocular melanin pigmentation anomalies in cats, cattle, mink, and mice with Chediak-Higashi syndrome: Histologic observations

The Chediak-Higashi syndrome (CHS) is a hereditary disorder of man, with the homologous condition reported in five animal species. Multiple defects, including oculocutaneous hypopigmentation, are present in individuals with this syndrome. Giant cytoplasmic granules, including melanosomes and lysosomes, are characteristic. In this study, eyes from CHS affected and control cats, cattle, mink, and mice were examined histologically to determine: 1) degree of pigmentation; 2) structure and distribution of melanin granules; and 3) morphology of cells and tissues containing melanin. The CHS cattle were found to be the most ocularly hypopigmented species, whereas CHS mouse eyes contained considerably more melanin than those of the other species. Melanin granules of abnormal sizes and shapes were present in neuroepithelial and uveal tissues of CHS animals of all four species. Depigmentation apparently had occurred in the CHS eyes, since less melanin was present in eyes of old CHS animals of each species than was present in eyes of young animals. In addition, melanin containing macrophages were common in CHS eyes, and the numbers of melanocytes and pigmented epithelial cells were decreased in older CHS eyes.

Tissue specific deficiency of lysozyme in ruminants

The distribution of lysozyme in tissues and fluids of ruminants was examined and it was determined that, except for a few tissues, ruminants were deficient in lysozyme activity compared with other species. The prominent exception was the abomasum of cattle, which had high levels of lysozyme activity. Mixing and extraction studies indicated that the lysozyme deficiency of ruminants was due neither to the presence of inhibitors of lysozyme in ruminant tissue nor to the binding of lysozyme in a manner that interfered with its enzymatic activity or assay. Other investigations have indicated that isozymes of lysozyme are present in ruminants and this study suggests that ruminants have only low levels of the isozyme that is the major isozyme of lysozyme in non-ruminants.

Arlee line of rainbow trout (Oncorhynchus mykiss) exhibits a low level of nonspecific cytotoxic cell activity

Nonspecific cytotoxic cell (NCC) activity was assessed in the peripheral blood of four isogenic lines of rainbow trout (Oncorhynchus mykiss) which were derived by the chromosome set manipulation technique of androgenesis. In these fish, whose isogenicity was previously confirmed by multilocus DNA fingerprint analysis, NCC activity was studied by the release of 51Cr from YAC-1 targets. Two groups of trout (the homozygous Arlee 12 line and the heterozygous hybrid of the Arlee 63 and Arlee 12 lines) had significantly lower levels of NCC activity in peripheral blood than either outbred rainbow trout or other lines with Hot Creek or hybrid Arlee x Hot Creek ancestry. The low NCC activity in the Arlee line appears to be inherited as a recessive trait. Peripheral blood cells of the trout mediated lectin dependent cellular cytotoxicity (LDCC) with the addition of phytohemagglutinin to co-cultures of effector cells and YAC-1 cells. The low NCC activity in the peripheral blood of these fish is not due to a condition analogous to the NCC-deficient Chediak-Higashi syndrome of man or the beige mutation of mice.

Interspecific genetic complementation analysis of human and sheep fibroblasts withβ-galactosidase deficiency

Interspecific somatic cell hybrids were analyzed by genetic complementation to determine if a lysosomal storage disease in sheep associated with deficiencies of β-galactosidase and α-neuraminidase was homologous with any of four β-galactosidase-deficient human diseases. Fibroblasts from β-glactosidase-deficient sheep, cats, and human patients were fused and assayed histochemically for β-galactosidase, with 5-bromo-4-chloro-3-indolyl β-d-galactoside. We observed complementation in heterokaryons consisting of fibroblasts from β-galactosidase-deficient sheep and fibroblasts from patients with galactosialidosis or mucolipidosis type II, but no complementation in heterokaryons consisting of fibroblasts from β-galactosidase-deficient sheep and fibroblasts from human or feline GM1, gangliosidosis (type I) or from human mucopolysaccharidosis type IVB fibroblasts. We conclude that the ovine disease is due to a mutation at the genetic locus homologous with that of GM1, gangliosidosis and mucopolysaccharidosis type IVB, suggesting that the primary defect in the ovine disease is a mutation of the β-galactosidase structural gene.

Complement levels in dogs with familial canine dermatomyositis

CH50, C4, C2, and C3 levels were evaluated in 7 dogs affected with dermatomyositis and in 22 control dogs. Dogs with dermatomyositis did not have clinical evidence of active disease at the time of serum collection for complement assays. No absolute complement component deficiency was identified in dermatomyositis-affected dogs in this study; however, a statistical difference in C2 was identified between control dogs of non-collie breeds and control collies, suggesting there may be a breed difference in complement levels.

Aberrant melanosome development in the retinal pigmented epithelium of cats with Chediak-Higashi syndrome

The Chediak-Higashi syndrome is a genetic disorder characterized by greatly enlarged cytoplasmic granules, including lysosomes and melanosomes. Eyes of humans and animals with Chediak-Higashi syndrome are hypopigmented to various degrees. Intraocular melanin granules vary in size, with some being massively enlarged. Electron microscopic examination of retinal pigmented epithelium of kittens with Chediak-Higashi syndrome disclosed a number of abnormalities of premelanosomes and melanosomes. Few premelanosomes were present. Most of the melanin granules were giant sized, but their structures varied. Some of the giant granules were composed of several premelanosomes and melanosomes in different stages of maturation. Others contained randomly oriented melanofilaments between melanosomes. There were also complex giant granules consisting of both melanosomal and lysosomal components. Inappropriate fusion of cytoplasmic granules appears to be the most likely mechanism for formation of the giant granules. Fusion of premelanosomes with lysosomes and resultant destruction of the premelanosomes probably is a major cause of the ocular hypopigmentation of Chediak-Higashi syndrome.

β-galactosidase activity in fibroblasts and tissues from sheep with a lysosomal storage disease

Tissues and fibroblasts of sheep affected with an inherited, neuronal lysosomal storage disease expressed a deficiency of β-galactosidase activity. Cerebrum, kidney, lung, spinal cord, and spleen from affected sheep had less than 8% of the β-galactosidase activity present in the respective tissues of normal sheep. No evidence for the presence of an endogenous inhibitor in affected sheep was detected by mixing studies. Liver of affected sheep expressed a deficiency of β-galactosidase activity only in the presence of the β-d-glycosidase inhibitors, glucono-δ-lactone and 2,5-dihydroxymethyl-3,4-dihydroxypyrrolidine. In these studies, we demonstrated the existence of tissue-specific β-galactosidases in sheep and showed that the affected sheep have a deficiency of the lysosomal β-galactosidase. Our results suggest that the high residual β-galactosidase activity in liver of affected sheep can be attributed to a nonlysosomal β-galactosidase that has a neutralpH optimum and may be under temporal regulation.

Severe secondary amyloidosis in a dog with dermatomyositis

A male collie aged 5 years 10 months, which developed dermatomyositis at 2 months of age, died from severe secondary amyloidosis. Amyloid deposition was most severe in renal glomeruli and produced renal failure. Amyloidosis has been reported in man with immune-mediated disorders including rheumatoid arthritis, systemic lupus erythematosus and dermatomyositis. It is possible that the inflammation in this case of familial canine dermatomyositis may have predisposed to the development of amyloidosis.