Temporal distribution of transmissible mink encephalopathy virus in mink inoculated subcutaneously.

Information was sought on the temporal distribution of transmissible mink encephalopathy virus in royal pastel mink inoculated subcutaneously with 10(3.0) 50% intracerebral lethal doses of the Idaho strain. As determined by intracerebral assay in mink, extremely little replication of the virus occurred during the preclinical stage of infection. It seemed largely limited to lymph nodes draining the site of inoculation. Virus first appeared in the central nervous system (CNS) at 20 weeks, when all mink were still clinically normal. Early spongiform degeneration, limited to the posterior sigmoid gyrus of the frontal cortex, was first found at 28 weeks, or a few weeks before onset of clinical disease in most of the mink. Once virus reached the CNS, where greater concentrations occurred than elsewhere, it appeared in many extraneural sites (spleen, liver, kidney, intestine, mesenteric lymph node, and submandibular salivary gland). These seemingly anomalous findings, especially the limited extraneural replication of virus as a prelude to infection of the CNS, suggest that mink are not natural hosts of the virus. The results of this study support the generally held view that transmissible mink encephalopathy arises from chance or inadvertent infection of ranch mink with an exogenous virus, most likely feed-borne wild scrapie virus.     

Retrograde axonal transport and motor neuron disease

Transport of material between extensive neuronal processes and the cell body is crucial for neuronal function and survival. Growing evidence shows that deficits in axonal transport contribute to the pathogenesis of multiple neurodegenerative diseases, including amyotrophic lateral sclerosis (ALS). Here we review recent data indicating that defects in dynein-mediated retrograde axonal transport are involved in ALS etiology. We discuss how mutant copper-zinc superoxide dismutase (SOD1) and an aberrant interaction between mutant SOD1 and dynein could perturb retrograde transport of neurotrophic factors and mitochondria. A possible contribution of axonal transport to the aggregation and degradation processes of mutant SOD1 is also reviewed. We further consider how the interference with axonal transport and protein turnover by mutant SOD1 could influence the function and viability of motor neurons in ALS.     

Breaking an absolute species barrier: transgenic mice expressing the mink PrP gene are susceptible to transmissible mink encephalopathy

Transmissible mink encephalopathy (TME) is a rare disease of the North American mink, which has never been successfully transmitted to laboratory mice. We generated transgenic mice expressing the mink prion protein (PrP) and inoculated them with TME or the mouse-adapted scrapie strain 79A. TME infected mink PrP-transgenic mice on a murine PrP knockout background. The absolute species barrier between the infectious agent of TME and mice was therefore broken. Following TME and 79A infection of mice carrying both mink and murine PrP(C), only proteinase-resistant PrP homologous to the incoming agent was detectable. The presence of the murine PrP(C) prolonged the incubation time of TME substantially.     

Adaptation and selection of prion protein strain conformations following interspecies transmission of transmissible mink encephalopathy

Interspecies transmission of the transmissible spongiform encephalopathies (TSEs), or prion diseases, can result in the adaptation and selection of TSE strains with an expanded host range and increased virulence such as in the case of bovine spongiform encephalopathy and variant Creutzfeldt-Jakob disease. To investigate TSE strain adaptation, we serially passaged a biological clone of transmissible mink encephalopathy (TME) into Syrian golden hamsters and examined the selection of distinct strain phenotypes and conformations of the disease-specific isoform of the prion protein (PrP(Sc)). The long-incubation-period drowsy (DY) TME strain was the predominate strain, based on the presence of its strain-specific PrP(Sc) following interspecies passage. Additional serial passages in hamsters resulted in the selection of the hyper (HY) TME PrP(Sc) strain-dependent conformation and its short incubation period phenotype unless the passages were performed with a low-dose inoculum (e.g., 10(-5) dilution), in which case the DY TME clinical phenotype continued to predominate. For both TME strains, the PrP(Sc) strain pattern preceded stabilization of the TME strain phenotype. These findings demonstrate that interspecies transmission of a single cloned TSE strain resulted in adaptation of at least two strain-associated PrP(Sc) conformations that underwent selection until one type of PrP(Sc) conformation and strain phenotype became predominant. To examine TME strain selection in the absence of host adaptation, hamsters were coinfected with hamster-adapted HY and DY TME. DY TME was able to interfere with the selection of the short-incubation HY TME phenotype. Coinfection could result in the DY TME phenotype and PrP(Sc) conformation on first passage, but on subsequent passages, the disease pattern converted to HY TME. These findings indicate that during TSE strain adaptation, there is selection of a strain-specific PrP(Sc) conformation that can determine the TSE strain phenotype.     

Distinct PrP properties suggest the molecular basis of strain variation in transmissible mink encephalopathy.

The molecular basis of strain variation in scrapie diseases is unknown. The only identified component of the agent is the posttranslationally modified host prion protein (PrPSc). The biochemical and physical properties of PrP from two strains of transmissible mink encephalopathy (TME), called hyper (HY) and drowsy (DY), were compared to investigate if PrP heterogeneity could account for strain diversity. The degradation rate of PrPTME digested with proteinase K was found to be strain specific and correlated with inactivation of the TME titer. Edman protein sequencing revealed that the major N-terminal end of HY PrPTME commenced at least 10 amino acid residues prior to that of DY PrPTME after digestion with proteinase K. Analysis of the brain distribution of PrPTME exhibited a strain-specific pattern and localization of PrPTME to the perikarya of specific neuron populations. Our findings are consistent with HY and DY PrPTME having distinct protein conformations and/or strain-specific ligand interactions that influence PrPTME properties. We propose that PrPTME conformation could play a role in targeting TME strains to different neuron populations in which strain-specific formation occurs. These data are consistent with the idea that PrPTME protein structure determines the molecular basis of strain variation.     

Biochemical and physical properties of the prion protein from two strains of the transmissible mink encephalopathy agent.

Transmissible mink encephalopathy (TME) has been transmitted to Syrian golden hamsters, and two strains of the causative agent, HYPER (HY) and DROWSY (DY), have been identified that have different biological properties. During scrapie, a TME-like disease, an endogenous cellular protein, the prion protein (PrPC), is modified (to PrPSc) and accumulates in the brain. PrPSc is partially resistant to proteases and is claimed to be an essential component of the infectious agent. Purification and analysis of PrP from hamsters infected with the HY and DY TME agent strains revealed differences in properties of PrPTME sedimentation in N-lauroylsarcosine, sensitivity to digestion with proteinase K, and migration in polyacrylamide gels. PrPC and HY PrPTME can be distinguished on the basis of their relative solubilities in detergent and protease sensitivities. PrPTME from DY-infected brain tissue shared solubility characteristics of PrP from both uninfected and HY-infected tissue. Limited protease digestion of PrPTME revealed strain-specific migration patterns upon polyacrylamide gel electrophoresis. Prolonged proteinase K treatment or N-linked deglycosylation of PrPTME did not eliminate such differences but demonstrated the PrPTME from DY-infected brain was more sensitive to protease digestion than HY PrPTME. Antigenic mapping of PrPTME with antibodies raised against synthetic peptides revealed strain-specific differences in immunoreactivity in a region of the amino-terminal end of PrPTME containing amino acid residues 89 to 103. These findings indicate that PrPTME from the two agent strains, although originating from the same host, differ in composition, conformation, or both. We conclude that PrPTME from the HY and DY strains undergo different posttranslational modifications that could explain differences in the biochemical properties of PrPTME from the two sources. Whether these strain-specific posttranslational events are directly responsible for the distinct biological properties of the HY and DY agent strains remains to be determined.     

Retrograde degeneration within the dorsal motor vagal nucleus following bilateral vagotomy in rabbits

The effects of unilateral and bilateral intrathoracic vagotomy on the neuronal structure of the dorsal motor nucleus of the vagus were studied in rabbits. Degeneration affected mainly the small neurones which disintegrated and vanished from dorsal motor nucleus relative to the survival time after operation. A substantial proportion of large neurones was lost or degenerated, but some were preserved unchanged. In unilaterally vagotomized rabbits the dorsal motor nucleus of the intact side showed scattered neurones with axonal reaction which stands up for peripheral crossing of the vagi. The degree of retrograde degeneration was largely determined by the survival time. The nucleus ambiguus was bilaterally preserved unchanged.     

Vestibular responses of neurons of the descending tracts during locomotion

Responses of vestibulo-, reticulo-, and rubro-spinal neurons to tilting decerebrate cats in the frontal plane were investigated. Tilting was carried out both at rest and during induced locomotion (walking and running on a treadmill). During locomotion the vestibular responses were greatly reduced or they disappeared completely.M. V. Lomonosov Moscow State University. Translated from Neirofiziologiya, Vol. 4, No. 3, pp. 311–316, May–June, 1972.     

Retrograde axonal transport in lateral motor neurons of the chick embryo prior to limb bud innervation

Horseradish peroxidase was injected into the distal limb buds of 3-, 3.5-, and 4-day chick embryos and was allowed to diffuse into the path of outgrowing axons. In the majority of the embryos injected, reaction product was found in cells of the ventral spinal cord ipsilateral to the injection site. The reaction product in the most clearly stained cells appeared smooth and diffuse rather than the typical granular appearance found in later embryos and adults. A granular background was seen in 4-day embryos, however, although distinct granular cell outlines were infrequent. This study indicates that retrograde axonal transport is a very early cellular feature during neurogenesis, demonstrable almost from the inception of neurite outgrowth. It is speculated that this transport capacity might function in relaying positional information from growing fiber tips back to cell bodies to aid in the formation of specific synaptic connections or in guiding directed axonal growth, or it may provide a means for trophic interactions vital to the survival of the young neuroblast.     

Retrograde axoplasmic transport of neurosecretory material

The axonal transport of neurosecretory material was studied in neurosecretory axons of the supraoptico-posthypophyseal system after in-situ transection of the median eminence. Two hours, 8 h, and 18 h after the lesion, both vasopressin and oxytocin antibodies revealed progressive accumulations of immunoreactive material not only in the proximal but also in the distal stumps of the transected axons. The electron-microscopic examination of these axonal portions revealed that such intense immunopositive labelings could be correlated, in both stumps, to a conspicuous accumulation of neurosecretory granules. It is concluded that, under normal physiological conditions, a significant amount of axoplasmic neurosecretory material is transported in retrograde direction and that such a retrograde transport mainly involves neurosecretory granules.     

传染性海绵状脑病的诊断进展和存在的问题

传染性海绵状脑病是由朊病毒引起的人和多种哺乳动物以神经退行性变化为主要特征的一种慢性致死性传染病。引起这类疾病的病原因子是一种编码宿主蛋白的PrPC转变为异常的PrPSC沉积在大脑,导致传染性海绵状脑病的发生。本文从临床症状识别、组织病理学诊断、致病性朊蛋白检测、生物学测定以及毒株鉴定等几个方面作一回顾和总结,为揭示朊病毒疾病致病机理和诊断研究提供借鉴。     

The clearance of viruses and transmissible spongiform encephalopathy agents from biologicals

The viral and transmissible spongiform encephalopathy (TSE) safety of therapeutics of biological origin (biologicals) is greatly influenced by the nature and degree of variability of the source material and by the mode of purification. Plasma-derived and recombinant DNA products currently have good viral safety records, but challenges remain. In general, large enveloped viruses are easier to remove from biologicals than small 'naked' viruses. Monoclonal antibodies and recombinant DNA biopharmaceuticals are derived from relatively homogeneous source materials and purified by multistep schemes that are robust and amenable to scientific analysis and engineering improvement. Viral clearance is more challenging for blood and cell products, as they are complex and labile. Source selection (e.g. country of origin, deferral for CJD risk factors) currently occupies the front line for ensuring that biologicals are free of TSE agents, but robust methods for their clearance from products are under development.     

Cre-loxP mediated control of PrP to study transmissible spongiform encephalopathy diseases

Expression of the PrP glycoprotein is essential for the development of the transmissible spongiform encephalopathy (TSE) or prion diseases. Although PrP is widely expressed in the mouse, the precise relevance of different PrP-expressing cell types to disease remains unclear. To address this, we generated two lines of floxed PrP gene-targeted transgenic mice using the Cre recombinase-loxP system. These floxed mice allow a functional PrP allele to be either switched "on" or "off." We demonstrate control of PrP expression for both alleles following Cre-mediated recombination, as determined by PrP mRNA and protein expression in the brain. Moreover, we show that Cre-mediated alteration of PrP expression in these mice has a major influence on the development of TSE disease. These floxed PrP mice will allow the involvement of PrP expression in specific cell types following TSE infection to be defined, which may identify potential sites for therapeutic intervention.     

Treatment of transmissible spongiform encephalopathy by intraventricular drug infusion in animal models

The therapeutic efficacy of direct drug infusion into the brain, the target organ of transmissible spongiform encephalopathies, was assessed in transgenic mice intracerebrally infected with 263K scrapie agent. Pentosan polysulfate (PPS) gave the most dramatic prolongation of the incubation period, and amphotericin B had intermediate effects, but antimalarial drugs such as quinacrine gave no significant prolongation. Treatment with the highest dose of PPS at an early or late stage of the infection prolonged the incubation time by 2.4 or 1.7 times that of the control mice, respectively. PPS infusion decreased not only abnormal prion protein deposition but also neurodegenerative changes and infectivity. These alterations were observed within the brain hemisphere fitted with an intraventricular infusion cannula but not within the contralateral hemisphere, even at the terminal disease stage long after the infusion had ended. Therapeutic effects of PPS were also demonstrated in mice infected with either RML agent or Fukuoka-1 agent. However, at doses higher than that providing the maximal effects, intraventricular PPS infusion caused adverse effects such as hematoma formation in the experimental animals. These findings indicate that intraventricular PPS infusion might be useful for the treatment of transmissible spongiform encephalopathies in humans, providing that the therapeutic dosage is carefully evaluated.     

Inactivation of transmissible spongiform encephalopathy (prion) agents by environ LpH

Agents causing transmissible spongiform encephalopathy (TSE) diseases are resistant to inactivation by several conventional decontamination methods. Using an animal bioassay, we compared the TSE agent disinfectant efficacy of a commercially available product referred to alternatively as LpH-SE, LpH-AG, or LpH-st to that of a similarly named but differently formulated product, Environ LpH, which was found to be an effective TSE agent disinfectant in a previous study. Here, we found LpH-SE to be at least 10(4)-fold to 10(5)-fold less effective than Environ LpH.     

Retrograde transport of neurotrophins: fact and function

Retrograde signals generated by nerve growth factor (NGF) and other neurotrophins promote the survival of appropriately connected neurons during development, and failure to obtain sufficient retrograde signals may contribute to neuronal death occurring in many neurodegenerative diseases. The discovery over 25 years ago that NGF supplied to the axon terminals is retrogradely transported to the cell bodies suggested that NGF must reach the cell body to promote neuronal survival. Research during the intervening decades has produced a refinement of this hypothesis. The current hypothesis is that NGF bound to TrkA at the axon terminal is internalized into signaling endosomes, with NGF in their lumens bound to phosphorylated TrkA in their membranes, which are retrogradely transported to the cell bodies, where TrkA activates downstream signaling molecules that promote neuronal survival and regulate many aspects of neuronal gene expression. This model has been extrapolated to retrograde signaling by all neurotrophins. We consider the evidence for this model, focusing on results of experiments with neurons in compartmented cultures. Results to date indicate that while the transport of signaling endosomes containing NGF bound to TrkA may carry retrograde signals, retrograde survival signals can be carried by another mechanism that is activated by NGF at the axon terminal surface and travels to the cell body unaccompanied by the NGF that initiated it. It is hypothesized that multiple mechanisms of retrograde signaling exist and function under different circumstances. The newly discovered potential for redundancy in retrograde signaling mechanisms can complicate the interpretation of experimental results.