A rapid profiling assay for avian leukosis virus subgroup E proviruses in chickens.

Endogenous retroviral elements (ERVs) are prolific components of the genomes of complex species, typically occupying more sequence space than do essential, protein-encoding genes. Much of what we know today about the structure and function, as well as the evolution and pathogenic potential, of ERVs was fleshed out over several decades during the last century using the avian leukosis virus subgroup E-related (ALVE) family of endogenous retroviruses of chickens as a model system. A critical enabling factor in the elucidation of ALVE structure and function is the ability to detect and unambiguously identify specific ALVE proviral elements and to develop accurate element profiles for individual chickens under study. Currently, the most common approach for ALVE locus detection involves element-specific PCR assays carried out using primers that target host DNA near the insertion site of the provirus (i.e., the upstream and downstream flanks of the unoccupied site). Here we describe a new approach for proviral detection that exploits restriction enzyme sites in flanking DNA to develop ALVE element profiles more rapidly than with assays currently in use. Moreover, unlike element-specific PCR tests, the "profiling" assay detects novel ALVEs for which insertion sites have not yet been identified as well as previously characterized elements.

Characterization of insertion sites and development of locus-specific assays for three broiler-derived subgroup E avian leukosis virus proviruses.

This report deals with the identification of novel elements belonging to a family of endogenous retroviruses, designated endogenous avian leukosis virus-type proviral elements (ALVE), that reside in the genome of the chicken and are closely related to exogenous avian leukosis viruses. The study of ALVE elements in the chicken genome serves as a model system for understanding the interplay between endogenous viruses and their vertebrate hosts in general, including humans. In this report, we characterize the insertion sites and describe locus-specific, diagnostic polymerase chain reaction-based assays for three previously discovered, but as yet not localized, ALVE elements. In addition, we assess the proviral integrity, provide the complete element sequence and examine the genomic environs of the three broiler-derived elements.

Molecular characterization of the Himalayan mink.

A rare color variant of the American mink (Neovison vison), discovered on a ranch in Nova Scotia and referred to as the "marbled" variety, carries a distinctive pigment distribution pattern resembling that found in some other species, e.g., the Siamese cat and the Himalayan mouse. We tested the hypothesis that the color pattern in question-light-colored body with dark-colored points (ears, face, tail, and feet)-is due to a mutation in the melanin-producing enzyme tyrosinase (TYR) that results in temperature-sensitive pigment production. Our study shows that marbled mink carry a mutation in exon 4 of the TYR gene (c.1835C > G) which results in an amino acid substitution (p.H420Q). The location of this substitution corresponds to the amino acid position that is also mutated in the TYR protein of the Himalayan mouse. Thus, the marbled variant is more aptly referred to as the Himalayan mink.

Simultaneous detection of eight single nucleotide polymorphisms in the ovine prion protein gene.

Amino acid polymorphisms in the prion protein gene (PrP) affect the susceptibility of sheep to scrapie, a transmissible spongiform encephalopathy (TSE). In particular, amino acid substitutions at codons 136, 154 and 171 of the ovine PrP gene are associated with different degrees of susceptibility to the classical form of scrapie, caused by 'typical' scrapie strains. Existing genotyping tests for scrapie susceptibility normally interrogate only the single nucleotide polymorphisms (SNPs) most relevant to 'typical' strains. Recently, however, a number of novel variants of the scrapie agent have been discovered. The ability of these new, 'atypical' scrapie variants to infect sheep that are resistant to 'typical' variants has raised concerns about the reduction in genetic variability that may result from intense selection for resistance to classical scrapie. Furthermore, a growing interest in a potential role for specific PrP genotypes in modulating performance traits is also driving a move toward more extensive characterization of haplotypes at the PrP locus. Here, we describe a single-tube method for the interrogation of eight SNPs within seven codons (112, 136, 141, 154, 171, 231 and 241) of the ovine PrP gene. This method is as accurate as sequencing, yet more affordable, and can easily be automated for high-throughput sample screening. Moreover, it can be modified to accommodate genetic variations that are found in local and heritage breeds.

Structural organization and chromosomal location of the chicken alpha-amylase gene family.

Characterization of the Gallus gallus alpha-amylase gene family revealed that the chicken genome contains two distinct amy loci. One of the two loci is expressed in the chicken pancreas while cDNA clones for the second locus were detected in a library constructed from liver mRNA. Fluorescent in situ hybridization to chromosome spreads showed that the two loci are both located on chromosome 8 within the chicken genome. Moreover, each locus contains both an intact, expressed gene copy as well as a pseudogene. The expressed gene and the pseudogene are arranged in a divergent configuration in the pancreatic amy locus, while in the hepatic locus the intact gene and the pseudogene are arranged in tandem. The data suggest a complex pattern of evolution for the chicken amylase gene family which includes multiple gene duplication events, insertion/deletion events, as well as changes in spatial expression patterns.