Large animal models for chronic wasting disease.

Chronic wasting disease (CWD) is a fatal neurodegenerative prion disease of cervid species including deer, elk, moose and reindeer. The disease has shown both geographic and species expansion since its discovery in the late 1960's and is now recognized in captive and free-ranging cervid populations in North America, Asia and Europe. The facile transmission of CWD is unique among prion diseases and has resulted in growing concern for cervid populations and human public health. The development of native cervid host models with longitudinal monitoring has revealed new insights about CWD pathogenesis and transmission dynamics. More than 20 years of experimental studies conducted in these models, using biologically relevant routes of infection, have led to better understanding of many aspect of CWD infections. This review addresses some of these insights, including: (i) the temporal intra-host trafficking of CWD prions in tissues and bodily fluids, (ii) the presence of infectivity shed in bodily excretions that may help explain the facile transmission of CWD, (iii) mother-to-offspring CWD transmission, (iv) the influence of some Prnp polymorphisms on CWD susceptibility, and (vi) continued development of vaccine strategies to mitigate CWD.

Lesion profiling and subcellular prion localization of cervid chronic wasting disease in domestic cats.

Chronic wasting disease (CWD) is an efficiently transmitted, fatal, and progressive prion disease of cervids with an as yet to be fully clarified host range. While outbred domestic cats (Felis catus) have recently been shown to be susceptible to experimental CWD infection, the neuropathologic features of the infection are lacking. Such information is vital to provide diagnostic power in the event of natural interspecies transmission and insights into host and strain interactions in interspecies prion infection. Using light microscopy and immunohistochemistry, we detail the topographic pattern of neural spongiosis (the "lesion profile") and the distribution of misfolded prion protein in the primary and secondary passage of feline CWD (Fel(CWD)). We also evaluated cellular and subcellular associations between misfolded prion protein (PrP(D)) and central nervous system neurons and glial cell populations. From these studies, we (1) describe the novel neuropathologic profile of Fel(CWD), which is distinct from either cervid CWD or feline spongiform encephalopathy (FSE), and (2) provide evidence of serial passage-associated interspecies prion adaptation. In addition, we demonstrate through confocal analysis the successful co-localization of PrP(D) with neurons, astrocytes, microglia, lysosomes, and synaptophysin, which, in part, implicates each of these in the neuropathology of Fel(CWD). In conclusion, this work illustrates the simultaneous role of both host and strain in the development of a unique Fel(CWD) neuropathologic profile and that such a profile can be used to discriminate between Fel(CWD) and FSE.

Experimental chronic wasting disease (CWD) in the ferret.

Chronic wasting disease (CWD), a prion disease of North American deer, elk and moose, affects both free-ranging and captive cervids. The potential host range for CWD remains uncertain. The susceptibility of the ferret to CWD was examined experimentally by administering infectious brain material by the intracerebral (IC) or oral (PO) route. Between 15 and 20 months after IC inoculation, ferrets developed neurological signs consistent with prion disease, including polyphagia, somnolence, piloerection, lordosis and ataxia. Upon first sub-passage of ferret-adapted CWD, the incubation period decreased to 5 months. Spongiform change in the neuropil was most marked in the basal ganglia, thalamus, midbrain and pons. The deposition of PrP(CWD) was granular and was occasionally closely associated with, or localized within, neurons. There were no plaque-like or perivascular PrP aggregates as seen in CWD-infected cervids. In western blots, the PrP(CWD) glycoform profile resembled that of CWD in deer, typified by a dominant diglycosylated glycoform. CWD disease in ferrets followed IC but not PO inoculation, even after 31 months of observation. These findings indicate that CWD-infected ferrets share microscopical and biochemical features of CWD in cervids, but appear to be relatively resistant to oral infection by primary CWD inoculum of deer origin.

Feline immunodeficiency virus Gag- and Env-specific immune responses after vaginal versus intravenous infection.

To better understand the correlation of mucosal and systemic immune responses with lentiviral containment, we contrasted the early mucosal and systemic immune responses induced by vaginal versus intravenous exposure of cats to feline immunodeficiency virus (FIV) isolates of differing pathogenicity and clade (i.e., FIV-B-2542 and FIV-A-PPR). We found that despite divergence in viral genotype, the mucosal and systemic immune responses induced differed more with route of exposure than virus isolate. In intravenously exposed cats, Gag-specific antibody (both IgG and IgA isotype) predominated in the serum, saliva, and vaginal wash fluid irrespective of infecting virus isolate. While Env-specific responses were more variable, they were more often detected in vaginally infected cats. Both IgG and IgA directed against Gag and Env were consistently present in vaginal wash fluids independent of route of infection or virus isolate. FIV Gag- and Env-specific cytotoxic lymphocytes (CTLs) were detected in blood and tissue lymphocytes of cats infected with either virus strain but were greatest in intravenously infected animals. Likewise, FIV-specific CTLs were detected in CD8(+) vaginal lymphocytes of animals infected by either route but were also more frequent in intravenously inoculated animals. In summary, we found qualitative differences in the immune responses following vaginal infection but no evidence (1) that mucosal immune responses were enhanced in vaginally exposed cats, (2) that local mucosal infection led to measurably greater immune responses in either compartment; or (3) that more prominent immune responses correlated with lower viral burden.

In vivo monocyte tropism of pathogenic feline immunodeficiency viruses.

Virus-infected monocytes rarely are detected in the bloodstreams of animals or people infected with immunodeficiency-inducing lentiviruses, yet tissue macrophages are thought to be a major reservoir of virus-infected cells in vivo. We have identified feline immunodeficiency virus (FIV) clinical isolates that are pathogenic in cats and readily transmitted vertically. We report here that five of these FIV isolates are highly monocytotropic in vivo. However, while FIV-infected monocytes were numerous in the blood of experimentally infected cats, viral antigen was not detectable in freshly isolated cells. Only after a short-term (at least 12-h) in vitro monocyte culture were FIV antigens detectable (by immunocytochemical analysis or enzyme-linked immunosorbent assay). In vitro experiments suggested that monocyte adherence provided an important trigger for virus antigen expression. In the blood of cats infected with a prototype monocytotropic isolate (FIV subtype B strain 2542), infected monocytes appeared within 2 weeks, correlating with high blood mononuclear-cell-associated viral titers and CD4 cell depletion. By contrast, infected monocytes could not be detected in the blood of cats infected with a less pathogenic FIV strain (FIV subtype A strain Petaluma). We concluded that some strains of FIV are monocytotropic in vivo. Moreover, this property may relate to virus virulence, vertical transmission, and infection of tissue macrophages.