State-of-the-art review of goat TSE in the European Union, with special emphasis on PRNP genetics and epidemiology.

Scrapie is a fatal, neurodegenerative disease of sheep and goats. It is also the earliest known member in the family of diseases classified as transmissible spongiform encephalopathies (TSE) or prion diseases, which includes Creutzfeldt-Jakob disease in humans, bovine spongiform encephalopathy (BSE), and chronic wasting disease in cervids. The recent revelation of naturally occurring BSE in a goat has brought the issue of TSE in goats to the attention of the public. In contrast to scrapie, BSE presents a proven risk to humans. The risk of goat BSE, however, is difficult to evaluate, as our knowledge of TSE in goats is limited. Natural caprine scrapie has been discovered throughout Europe, with reported cases generally being greatest in countries with the highest goat populations. As with sheep scrapie, susceptibility and incubation period duration of goat scrapie are most likely controlled by the prion protein (PrP) gene (PRNP). Like the PRNP of sheep, the caprine PRNP shows significantly greater variability than that of cattle and humans. Although PRNP variability in goats differs from that observed in sheep, the two species share several identical alleles. Moreover, while the ARR allele associated with enhancing resistance in sheep is not present in the goat PRNP, there is evidence for the existence of other PrP variants related to resistance. This review presents the current knowledge of the epidemiology of caprine scrapie within the major European goat populations, and compiles the current data on genetic variability of PRNP.

Design and validation of a high-throughput assay to detect codon 146 polymorphisms in the caprine prion protein gene.

In sheep, scrapie susceptibility is so strongly associated with single nucleotide polymorphisms (SNPs) in the gene encoding the prion protein (PrP) that this linkage constitutes the basis for selective breeding strategies directed toward controlling the disease. For goats, in contrast, the association between scrapie susceptibility/resistance and variations in the PrP gene is far weaker, with only a few identified SNPs showing an influence on scrapie susceptibility. A recent survey of PrP genotypes in Cypriot goats, however, revealed the existence of a robust association between polymorphisms at codon 146 of the caprine PrP gene and resistance/susceptibility to natural scrapie. Here we describe here a high-throughput assay, based on homogeneous MassExtend technology coupled with mass spectrometry, for genotyping codon 146 of the caprine PrP gene. Our results demonstrate that this assay exhibits high accuracy, reproducibility, and repeatability, thereby making it suitable for large-scale SNP genotyping, as required for scrapie surveillance programs.

Interactions of the antizyme AtoC with regulatory elements of the Escherichia coli atoDAEB operon.

AtoC has a dual function as both an antizyme, the posttranslational inhibitor of polyamine biosynthetic enzymes, and the transcriptional regulator of genes involved in short-chain fatty acid catabolism (the atoDAEB operon). We have previously shown that AtoC is the response regulator of the AtoS-AtoC two-component signal transduction system that activates atoDAEB when Escherichia coli is exposed to acetoacetate. Here, we show that the same cis elements control both promoter inducibility and AtoC binding. Chromatin immunoprecipitation experiments confirmed the acetoacetate-inducible binding of AtoC to the predicted DNA region in vivo. DNase I protection footprinting analysis revealed that AtoC binds two 20-bp stretches, constituting an inverted palindrome, that are located at -146 to -107 relative to the transcription initiation site. Analyses of promoter mutants obtained by in vitro chemical mutagenesis of the atoDAEB promoter verified both the importance of AtoC binding for the inducibility of the promoter by acetoacetate and the sigma54 dependence of atoDAEB expression. The integration host factor was also identified as a critical component of the AtoC-mediated induction of atoDAEB.

Molecular characterization of a cDNA from the gilthead sea bream (Sparus aurata) encoding a fish prion protein.

We have identified and characterized a cDNA from the brain tissue of the highly commercial marine fish species, the gilthead sea bream (Sparus aurata), which encodes a 496 amino acid residue protein sharing the organizational and structural features of the mammalian prion proteins. Tissue mRNA expression analyses revealed the presence of this transcript in various tissues of the gilthead sea bream including the brain, the spleen, and the heart. Sequence comparison and phylogenetic analysis showed the gilthead sea bream protein to be the homologue of one of the long form prion proteins identified from the model fish species Takifugu rubripes and Danio rerio. Unique to this fish prion protein is an extended Gly-Tyr-Pro-rich region, a structural feature that apparently resulted from multiple duplications of a core motif. The presence of this feature in other seemingly unrelated proteins suggests the involvement of common mechanism(s) in its formation and infers possible evolutionary trends related to its function.

Involvement of the AtoS-AtoC signal transduction system in poly-(R)-3-hydroxybutyrate biosynthesis in Escherichia coli.

The AtoS-AtoC signal transduction system in E. coli, which induces the atoDAEB operon for the growth of E. coli in short-chain fatty acids, can positively modulate the levels of poly-(R)-3-hydroxybutyrate (cPHB) biosynthesis, a biopolymer with many physiological roles in E. coli. Increased amounts of cPHB were synthesized in E. coli upon exposure of the cells to acetoacetate, the inducer of the AtoS-AtoC two-component system. While E. coli that overproduce both components of the signal transduction system synthesize higher quantities of cPHB (1.5-4.5 fold), those that overproduce either AtoS or AtoC alone do not display such a phenotype. Lack of enhanced cPHB production was also observed in cells overexpressing AtoS and phosphorylation-impaired AtoC mutants. The results were not affected by the nature of the carbon source used, i.e., glucose, acetate or acetoacetate. An E. coli strain with a deletion in the atoS-atoC locus (delta atoSC) synthesized lower amounts of cPHB compared to wild-type cells. When the delta atoSC strain was transformed with a plasmid carrying a 6.4-kb fragment encoding the AtoS-AtoC system, cPHB biosynthesis was restored to the level of the atoSC+ cells. Introduction of a multicopy plasmid carrying a functional atoDAEB operon, but not one with a promoterless operon, resulted in increased cPHB synthesis only in atoSC+ cells in the presence of acetoacetate. These results indicate that the presence of both a functional AtoS-AtoC two-component signal transduction system and a functional atoDAEB operon is critical for the enhanced cPHB biosynthesis in E. coli.

Disparate evolution of prion protein domains and the distinct origin of Doppel- and prion-related loci revealed by fish-to-mammal comparisons.

Prions result from the misfolding and selective accumulation of the host-encoded prion protein (PrP) in the brain. Despite intensive research on mammalian models, basic questions about the biological role of PrP and the evolutionary origin of prion disease remain unanswered. Following our previous identification of novel fish PrP homologues, here we generated new fish PrP sequences and performed genomic analysis to demonstrate the existence of two homologous PrP loci in bony fish, which display extensive molecular variation and are highly expressed in adult and developing fish brains. The fish PrP genomic regions contain PrP-related loci directly downstream of each PrP locus, suggesting an independent origin of prion-related proteins in fish and mammals. Our structural prediction analysis uncovers a conserved molecular "bauplan" for all vertebrate PrPs. The C- and N-terminal protein domains have evolved independently from one another, the former having retained its basic globular structure despite high sequence divergence and the latter having undergone differential expansion-degeneration cycles in its repetitive domains. Our evolutionary analysis redefines fundamental concepts on the functional significance of PrP domains and opens up new possibilities for the experimental analysis of prion misfolding and neurodegeneration in a non-mammalian model like the zebrafish.

Phosphorylation activity of the response regulator of the two-component signal transduction system AtoS-AtoC in E. coli.

Antizyme, long known to be a non-competitive inhibitor of ornithine decarboxylase, is encoded by the atoC gene in Escherichia coli. The present study reveals another role for AtoC, that of a response regulator of the AtoS-AtoC two component system regulating the expression of the atoDAEB operon upon acetoacetate induction. This operon encodes enzymes involved in short-chain fatty acid catabolism in E. coli. Evidence is presented to show that AtoS is a sensor kinase that together with AtoC constitutes a two-component signal transduction system. AtoS is a membrane protein which can autophosphorylate and then transfer that phosphoryl group to AtoC. This process can also be reproduced in vitro. AtoC contains in its amino acid sequence a conserved aspartic acid (D55), which is the putative phosphorylation site, as well as an unexpected "H box" consensus sequence (SHETRTPV), common to histidine kinases, with the histidine contained therein (H73) being a second potential target for phosphorylation. Substitution of either D55 or H73 in His10-AtoC diminished but did not abrogate AtoC phosphorylation suggesting that either both residues can be phosphorylated independently or that the phosphate group can be transferred between them. However, the D55 mutation in comparison to H73 had a more pronounced effect in vivo, on the activation of atoDAEB promoter after acetoacetate induction, although it was the presence of both mutations that rendered AtoC totally unresponsive to induction. These data provide evidence that the gene products of atoS and atoC constitute a two-component signal transduction system, with some unusual properties, involved in the regulation of the atoDAEB operon.

Prion protein gene polymorphisms in natural goat scrapie.

A total of 51 goats, including seven clinical cases, from the first herd in Greece reported to have scrapie was examined to discern an association between scrapie susceptibility and polymorphisms of the gene encoding the prion protein (PrP). Each animal was evaluated for clinical signs of the disease, histopathological lesions associated with scrapie, the presence of detectable protease-resistant PrP in the brain and PrP genotype. Eleven different PrP genotypes encoding at least five unique predicted mature PrP amino acid sequences were found. These genotypes included the amino acid polymorphisms at codons 143 (H-->R) and 240 (S-->P) and 'silent' nucleotide alterations at codons 42 (a-->g) and 138 (c-->t). Additionally, novel caprine amino acid polymorphisms were detected at codons 21 (V-->A), 23 (L-->P), 49 (G-->S), 154 (R-->H), 168 (P-->Q) and 220 (Q-->H) and new silent mutations were found at codons 107 (g-->a) and 207 (g-->a). The following variants were found in scrapie-affected goats: VV(21), LL(23), GG(49,) SS(49), HH(143), HR(143), RR(154), PP(168), PP(240), SP(240) and SS(240). All scrapie-affected animals carried the HH(143)RR(154) genotype, with the exception of two goats (HR(143)), both of which had detectable protease-resistant PrP but showed no clinical signs or histopathological lesions characteristic of scrapie.