The host range of chronic wasting disease is altered on passage in ferrets.

Chronic wasting disease (CWD), a member of the transmissible spongiform encephalopathies (TSEs), was first identified in captive mule and black-tail deer in 1967. Due to the failure to transmit CWD to rodents, we investigated the use of ferrets (Mustela putorius furo) as a small animal model of CWD. The inoculation of CWD into ferrets resulted in an incubation period of 17-21 months on primary passage that shortened to 5 months by the third ferret passage. The brain tissue of animals inoculated with ferret-passaged CWD exhibited spongiform degeneration and reactive astrocytosis. Western blot analysis of ferret-passaged CWD demonstrated the presence of PrP-res. Unlike mule deer CWD, ferret-passaged CWD was transmissible to Syrian golden hamsters (Mesocricetus auratus). Increasing the passage number of CWD in ferrets increased the pathogenicity of the agent for hamsters. This increase in host range of a field isolate on interspecies transmission emphasizes the need for caution when assessing the potential risk of transmission of TSEs, such as bovine spongiform encephalopathy, to new host species.

Transmissible mink encephalopathy species barrier effect between ferret and mink: PrP gene and protein analysis.

Experimental infection of transmissible mink encephalopathy (TME) in two closely related mustelids, black ferret (Mustela putorius furo) and mink (Mustela visa), revealed differences in their susceptibility to the TME agent. When challenged with the Stetsonville TME agent, a longer incubation period was observed in ferrets (28 to 38 months) than mink (4 months). Western blot analysis of ferret and mink prion proteins (PrP) demonstrated no detectable differences between the proteins. Northern blot analysis of ferret brain RNA indicated that PrP mRNA abundance is similar in infected and uninfected individuals. We amplified the PrP coding region from ferret DNA using the polymerase chain reaction and compared the deduced amino acid sequence of the ferret PrP gene with the mink PrP gene. This comparison revealed six silent base changes and two amino acid changes between mink and ferret: Phe-->Lys at codon 179 and Arg-->Gln at codon 224, respectively. These changes may indicate the region of PrP that is responsible for the species barrier effect between mink and ferret.

Multiple age-associated mitochondrial DNA deletions in skeletal muscle of mice.

Multiple mitochondrial DNA (mtDNA) deletions have been associated with aging in humans and monkeys. Since the inbred mouse strain, C57BL/6, has been extensively studied gerontologically, we sought to investigate its utility as a model for examining the importance of mtDNA deletions in aging. Using the polymerase chain reaction (PCR), we analyzed hind limb skeletal muscle from mice of three age groups (5, 16 and 25 months) for the presence of age-associated mtDNA deletions. We observed multiple mtDNA deletions in all three age groups. Further, the number of deletions detected per mouse increased greatly with advancing age.

Golden hamster embryonic genome activation occurs at the two-cell stage: correlation with major developmental changes.

The earliest time of onset of embryonic genome activation in golden hamsters was investigated. The inhibition of transcription by alpha-amanitin (11 micrograms/ml) in cultured embryos resulted in a total arrest of development of early 2-cell embryos (26 hr post-egg activation); under similar conditions, immediate cleavage divisions of 1-, late 2-, 4-, and 8-cell embryos were not affected. Electrophoretic analysis of [35S]methionine-labeled embryonic proteins showed that alpha-amanitin treatment apparently inhibited transcription-dependent protein synthesis in early 2-cell and, to some extent, in late 2-cell when compared to 4-cell embryos. Analysis of total RNA synthesis, using [alpha 32P]-UTP or [32P]-orthophosphate, showed that there was a high proportion of radioactivity associated with the macromolecular fraction (RNA) at the early and late 2-cell stages and at the 4-cell stage compared to that at the 1-cell stage. These results indicate that the de novo synthesis of RNA, encoded by the embryonic genome, occurs at the 2-cell stage and that the second and subsequent cleavage divisions of hamster preimplantation embryos are dependent on new transcriptional activity. This initial activity of the embryonic genome in hamsters is coincident with several characteristic features of in vitro development such as a block to development, synthesis of major proteins, change in energy substrate preference, phosphate-inhibition of development and a requirement for amino acids.

Persistence and expression of Microplitis demolitor polydnavirus in Pseudoplusia includens.

Persistence and expression of Microplitis demolitor polydnavirus (MdPDV) was examined in parasitized and virus-injected Pseudoplusia includens larvae. Viral DNA persisted in P. includens larvae for 6 days, but no increase in the amount of viral DNA present was detected. Viral transcripts were observed in parasitized and virus-injected larvae 4 h post-parasitism and expression continued for 6 days. When specific host tissues were examined, more viral DNA and RNA was detected in haemocytes than in the gut, nervous system and fat body. 32P-labelled MdPDV DNA hybridized to approximately six different size classes of mRNAs on Northern blots of RNA from haemocytes of parasitized larvae. MdPDV transcription was first detected in haemocytes at 4 h post-parasitism and continued for 6 days. Similar transcripts were observed in haemocytes from larvae that had been injected with calyx fluid or MdPDV plus venom. First-strand cDNA probes of haemocyte-specific MdPDV transcripts hybridized to only certain MdPDV viral DNAs, suggesting that only part of the MdPDV genome is expressed in this host cell type.

Lack of glyconeogenesis in pancreatic islets: expression of gluconeogenic enzyme genes in islets.

Studies were performed to obtain evidence for glyconeogenesis from pyruvate to the triose phosphates in pancreatic islets. Inability to show this evidence would be consistent with the fact that glyceraldehyde, but not pyruvate, is a potent insulin secretagogue. Synthesis of 14C-labelled glucose from 14C-labelled pyruvate could not be detected. Since this might have been due to lack of sensitivity required to measure 14C-glucose production in such a scarce tissue as islets, cDNA probes were used to estimate the relative expression of genes coding for gluconeogenic enzymes. Islets expressed pyruvate carboxylase mRNA, but even islets from rats which had been starved (a condition which induces phosphoenolpyruvate carboxykinase (PEPCK) in liver, kidney and adipose tissue) showed no PEPCK mRNA. This is consistent with our previous work showing the absence of PEPCK enzyme activity in islets. Therefore, islets can convert pyruvate to oxalacetate, but since they lack PEPCK, neither the beta nor alpha cell can convert oxalacetate to phosphoenolpyruvate and carry out glyconeogenesis. Pyruvate carboxylase mRNA was increased in islets that possessed the capacity for glucose-induced insulin release versus islets that lacked the capacity to respond to glucose, such as islets from fed rats (versus starved rats) and in islets cultured at a high concentration of glucose (versus at low glucose). Pyruvate carboxylase, therefore, must be involved in pyruvate metabolism and not glyconeogenesis in the pancreatic islet.

Glucose regulates leucine-induced insulin release and the expression of the branched chain ketoacid dehydrogenase E1 alpha subunit gene in pancreatic islets.

Much evidence has accumulated to support the idea that leucine can stimulate insulin release by allosterically activating glutamate dehydrogenase thus enhancing glutamate metabolism. It is less clear how the metabolism of leucine itself contributes to the signal for insulin release. We recently found that culturing pancreatic islets for 1 day at low glucose (1 mM) suppressed glucose-induced insulin release, but preserved leucine-induced insulin release. When islets were cultured at high glucose (20 mM), glucose-induced insulin release was preserved, but leucine-induced insulin release was suppressed (MacDonald, M. J., Fahien, L. A., McKenzie, D. I., and Moran, S. M. (1990) Am. J. Physiol., 259, E548-E554). The suppression of leucine-induced insulin release can be explained by glucose's suppression of the synthesis of the enzyme that catalyzes the first committed step of leucine metabolism, branched chain ketoacid dehydrogenase complex (BCKDH). High glucose suppressed the enzyme activity of the E1 component of the BCKDH complex, as well as the total activity of the BCKDH complex, to usually negligible levels in islets and decreased by an average of 90% the mRNA which encodes E1 alpha, the catalytic subunit of the E1 component of BCKDH, in islets and rat insulinoma cells. Time course studies showed that about 24 h in culture was required to maximally induce or suppress the expression of BCKDH E1 alpha. Culture at high glutamine with or without leucine mimicked to a lesser and more variable degree the effects of high glucose on leucine-induced insulin release and BCKDH E1 alpha mRNA. Leucine-plus-glutamine-induced insulin release was present after culture of islets with glucose and with or without any other secretagogue. Also, glutamate dehydrogenase transcripts and enzyme activity were not significantly altered by varying the concentration of glucose in the culture medium. Thus, leucine's insulinotropism via activation of glutamate dehydrogenase is constitutive. Preproinsulin mRNA levels were markedly increased at high glucose and glyceraldehyde phosphate dehydrogenase transcripts were either unaffected or slightly increased by glucose. Glutamine did not significantly effect the expression of genes other than BCKDH E1 alpha, and leucine had little or no effect on the expression of any of the four genes.(ABSTRACT TRUNCATED AT 400 WORDS)

Novel effects of insulin secretagogues on capacitation of insulin release and survival of cultured pancreatic islets.

Agents that stimulate insulin release from fresh pancreatic islets were tested for their ability to capacitate pancreatic islets to secrete insulin and to support beta-cell survival in tissue culture. Capacitation was defined as the ability to release insulin after 24 h in culture in the presence of an insulinotropic concentration of a secretagogue. Viable islets that lose glucose-induced insulin release gradually regain it during culture for 24 h in 20 mM glucose. Survival was defined as the ability to regain glucose-induced insulin release. To measure insulin release after culture, islets were incubated with various secretagogues in Krebs-Ringer buffer for 1 h. Examples of the diverse patterns of responses included the following. Glucose was the only secretagogue that capacitated glucose-induced release. Leucine-, leucine plus glutamine-, and glyceraldehyde-induced release remained capacitated after culture with no secretagogue. Culture at high glucose completely inhibited leucine-induced release. Culture at low glucose (1 mM) or at both high leucine and glutamine abolished glucose-induced release. Only leucine and glutamine capacitated monomethyl succinate-induced release. All agents including subinsulinotropic glucose (1 mM), except D-glyceraldehyde, permitted islet survival. Thus the metabolic pathways for initiation, capacitation, and survival are not identical between and within secretagogues. There is a reciprocal relationship between leucine and glucose with respect to capacitation. Capacitation follows a time course, which suggests that it is regulated by enzyme induction.

Tandem repeats of a specific alternating purine-pyrimidine DNA sequence adjacent to protamine genes in the rainbow trout that can exist in the Z form.

We have located an extensive (AC)n-rich but specific sequence downstream of three rainbow trout protamine genes. Although sharing considerable sequence homology, including a perfectly conserved 46 base pair repeat, the sequences exhibit a regular heterogeneity in the length of the (AC)n-rich tracts. Radioimmunoassay experiments, S1 nuclease sensitivity studies, two-dimensional electrophoretic analysis, and immunoelectron microscopy studies have been used to determine if the region could assume a Z DNA conformation. It was found that, in a supercoiled plasmid, the (AC)n-rich region has the ability to attain the Z DNA conformation under physiological conditions.

Catechol oxygenases of Pseudomonas putida mutant strains.

Investigation of a mutant strain of Pseudomonas putida NCIB 10015, strain PsU-E1, showed that it had lost the ability to produce catechol 1,2-oxygenase after growth with catechol. Additional mutants of both wild-type and mutant strains PsU-E1 have been isolated that grow on catechol, but not on benzoate, yet still form a catechol 1,2-oxygenase when exposed to benzoate. These findings indicate that either there are separately induced catechol 1,2-oxygenase enzymes, or that there are two separate inducers for the one catechol 1,2-oxygenase enzyme. Comparisons of the physical properties of the catechol 1,2-oxygenases formed in response to the two different inducers show no significant differences, so it is more probable that the two proteins are the product of the same gene. Sufficient enzymes of the ortho-fission pathway are induced in the wild-type strain by the initial substrate benzoate (or an early intermediate) to commit that substrate to metabolism by ortho fission exclusively. A mechanism exists that permits metabolism of catechol by meta fission if the ortho-fission enzymes are unable to prevent its intracellular accumulation.