Use of ev loci as a measure of inbreeding in domestic fowls

Genome-wide SNP analysis identifies major QTL for Salmonella colonization in the chicken

Salmonella-infected poultry products are a major source of human Salmonella infection. The prophylactic use of antimicrobials in poultry production was recently banned in the EU, increasing the need for alternative methods to control Salmonella infections in poultry flocks. Genetic selection of chickens more resistant to Salmonella colonization provides an attractive means of sustainably controlling the pathogen in commercial poultry flocks and its subsequent entry into the food chain. Analysis of different inbred chickens has shown that individual lines are consistently either susceptible or resistant to the many serovars of Salmonella that have been tested. In this study, two inbred chicken lines with differential susceptibility to Salmonella colonization (61 ((R)) and N((S)) ) were used in a backcross experimental design. Unlike previous studies that used a candidate gene approach or low-density genome-wide screens, we have exploited a high-density marker set of 1255 SNPs covering the whole genome to identify quantitative trait loci (QTL). Analysis of log-transformed caecal bacterial levels between the parental lines revealed a significant difference at 1, 2, 3 and 4 days post-infection (P < 0.05). Analysis of the genotypes of the backcross (F1  × N) population (n = 288) revealed four QTL on chromosomes 2, 3, 12 and 25 for the two traits examined in this study: log-transformed bacterial counts in the caeca and presence of a hardened caseous caecal core. These included one genome-wide significant QTL on chromosome 2 at 20 Mb and three additional QTL, on chromosomes 3, 12 and 25 at 96, 15 and 1 Mb, respectively, which were significant at the chromosome-wide level (P < 0.05). The results generated in this study will inform future breeding strategies to control these pathogens in commercial poultry flocks.

Large scale variation in DNA copy number in chicken breeds

BACKGROUND

Detecting genetic variation is a critical step in elucidating the molecular mechanisms underlying phenotypic diversity. Until recently, such detection has mostly focused on single nucleotide polymorphisms (SNPs) because of the ease in screening complete genomes. Another type of variant, copy number variation (CNV), is emerging as a significant contributor to phenotypic variation in many species. Here we describe a genome-wide CNV study using array comparative genomic hybridization (aCGH) in a wide variety of chicken breeds.

RESULTS

We identified 3,154 CNVs, grouped into 1,556 CNV regions (CNVRs). Thirty percent of the CNVs were detected in at least 2 individuals. The average size of the CNVs detected was 46.3 kb with the largest CNV, located on GGAZ, being 4.3 Mb. Approximately 75% of the CNVs are copy number losses relatively to the Red Jungle Fowl reference genome. The genome coverage of CNVRs in this study is 60 Mb, which represents almost 5.4% of the chicken genome. In particular large gene families such as the keratin gene family and the MHC show extensive CNV.

CONCLUSIONS

A relative large group of the CNVs are line-specific, several of which were previously shown to be related to the causative mutation for a number of phenotypic variants. The chance that inter-specific CNVs fall into CNVRs detected in chicken is related to the evolutionary distance between the species. Our results provide a valuable resource for the study of genetic and phenotypic variation in this phenotypically diverse species.

Fine mapping of the chicken salmonellosis resistance locus (SAL1)

Salmonella enterica serovar Typhimurium is a Gram-negative bacterium that has a significant impact on both human and animal health. It is one of the most common food-borne pathogens responsible for a self-limiting gastroenteritis in humans and a similar disease in pigs, cattle and chickens. In contrast, intravenous challenge with S. Typhimurium provides a valuable model for systemic infection, often causing a typhoid-like infection, with bacterial replication resulting in the destruction of the spleen and liver of infected animals. Resistance to systemic salmonellosis in chickens is partly genetically determined, with bacterial numbers at systemic sites in resistant lines being up to 1000-fold fewer than in susceptible lines. Identification of genes contributing to disease resistance will enable genetic selection of resistant lines that will reduce Salmonella levels in poultry flocks. We previously identified a novel resistance locus on Chromosome 5, designated SAL1. Through the availability of high-density SNP panels in the chicken, combined with advanced back-crossing of the resistant and susceptible lines, we sought to refine the SAL1 locus and identify potential positional candidate genes. Using a 6(th) generation backcross mapping population, we have confirmed and refined the SAL1 locus as lying between 54.0 and 54.8 Mb on the long arm of Chromosome 5 (F = 8.72, P = 0.00475). This region spans 14 genes, including two very striking functional candidates; CD27-binding protein (Siva) and the RAC-alpha serine/threonine protein kinase homolog, AKT1 (protein kinase B, PKB).

The chicken proinflammatory cytokines interleukin-1beta and interleukin-6: differences in gene structure and genetic location compared with their mammalian orthologues

The genes encoding the chicken proinflammatory cytokines interleukin (IL)-1B and IL-6 were cloned, sequenced and mapped. The exon:intron structure of the coding region of chicken IL1B corresponds almost exactly to those of mammalian IL1B. As yet, we have no evidence for a 5'-UTR non-coding exon equivalent to that found in mammalian IL1B. The exon:intron structure of chicken IL6 differs from those of mammalian IL6, having one exon fewer (the first two exons in mammalian IL6 genes appear to be fused in the chicken gene). We were unable to clone or sequence the promoter of chicken IL1B. The chicken IL6 promoter shares a number of potential regulatory sequences similar to those found in the human IL6 promoter. These putative elements include (5'-3') a glucocorticoid response element (GRE), an AP-1 binding site, an NF-IL-6 binding site (albeit in the reverse orientation), an NF-kappaB binding site, a second AP-1 binding site and a TATAAA box. A further GRE, a cAMP response element and regions with homology to c-fos serum responsive elements or retinoblastoma control elements were absent. Promoter sequence polymorphisms were not identified in eight different inbred chicken lines. A restriction single-stranded conformational polymorphism was identified which enabled chicken IL1B to be genetically mapped to one end of chromosome 2. Chicken IL6 was mapped by fluorescent in situ hybridization also to chromosome 2, at an FLpter of 0.26.

Resistance to salmonellosis in the chicken is linked to NRAMP1 and TNC

Natural resistance to infection with Salmonella typhimurium in mice is controlled by two major loci, Bcg and Lps, located on mouse chromosomes 1 and 4, respectively. Both Bcg and Lps exert pleiotropic effects and contribute to cytostatic/cytocidal activities of the macrophage. Bcg encodes for a membrane phosphoglycoprotein designated Nrampl (natural resistance-associated macrophage protein 1), which belongs to an ancient family of membrane proteins, Lps has not been cloned yet, but its location on mouse chromosome 4 has been refined for positional cloning. As in mice, chicken inbred lines differ in their susceptibility to infection with Salmonella typhimurium. We have tested the candidacy of the chicken homologs of Nrampl and Tnc (a locus closely linked to Lps), in the differential resistance of chicken inbred lines to infection with S. typhimurium. We have first analyzed six inbred chicken lines of Salmonella-resistant or Salmonella-susceptible phenotypes for the presence of nucleotide sequence variations within the coding portion of NRAMP1. We have identified 11 sequence variations within NRAMP1 in the chicken inbred lines tested: 10 of these represented either silent mutations or conservative changes. However, one G-->A substitution at nucleotide 696 resulted in the nonconservative replacement of Arg223 to Gln223 within the predicted TM5-6 region. This allelic variant was specific to the susceptible line C and not observed in any of the resistant strains. To investigate the effect of NRAMP1 and TNC on resistance to infection with S. typhimurium, 425 (W1 x C)F1 x C chicken progeny were examined during a period of 15 days postinfection. Together, NRAMP1 and TNC explain 33% of the early differential resistance to infection with S. typhimurium of parental lines C and W1. Our data established that resistance to infection with S. typhimurium in chickens is inherited as a complex trait and that comparative mapping has proven to be useful to identify Salmonella-resistance genes in the chicken.

Genetic and physical mapping of the natural resistance-associated macrophage protein 1 (NRAMP1) in chicken

The chicken natural resistance-associated macrophage protein 1 (NRAMP1) gene has been mapped by linkage analysis by use of a reference panel to develop the chicken molecular genetic linkage map and by fluorescence in situ hybridization. The chicken homolog of the murine Nramp 1 gene was mapped to a linkage group located on Chromosome (Chr) 7q13, which includes three genes (CD28, NDUSF1, and EF1B) that have previously been mapped either to mouse Chr 1 or to human Chr 2q. Physical mapping by pulsed-field gel electrophoresis revealed that NRAMP1 is tightly linked to the villin gene and that the genomic organization (gene order and presence of CpG islands) of the chromosomal region carrying NRAMP1 is well conserved between the chicken and mammalian genomes. The regions on mouse Chr 1, human Chr 2q, and chicken Chr 7q that encompass NRAMP1 represent large conserved chromosomal segments between the mammalian and avian genomes. The chromosome mapping of the chicken NRAMP1 gene is a first step in determining its possible role in differential susceptibility to salmonellosis in this species.

Potential bias in inbreeding depression estimates when using pedigree relationships to assess the degree of homozygosity for loci under selection

A potential bias in estimation of inbreeding depression when using pedigree relationships to assess the degree of homozygosity for loci under selection is indicated. A comparison of inbreeding coefficients based on either pedigree or genotypic frequencies indicated that, as a result of selection, the inbreeding coefficient based on pedigree might not correspond with the random drift of allelic frequencies. Apparent differences in average levels of both inbreeding coefficients were obtained depending on the genetic model (additive versus dominance, initial allelic frequencies, heritability) and the selection system assumed (no versus mass selection). In the absence of selection, allelic frequencies within a small population change over generations due to random drift, and the pedigree-based inbreeding coefficient gives a proper assessment of the accompanying probability of increased homozygosity within a 'replicate' by indicating the variance of allelic frequencies over replicates. With selection, in addition to random drift, directional change in allelic frequencies is not accounted for by the pedigree-based inbreeding coefficient. This result implies that estimation of inbreeding depression for traits under either direct or indirect selection, estimated by a regression of performance on pedigree-based coefficients, should be carefully interpreted.

Association of endogenous avian viral and endogenous viral genes with feed conversion and six-week body weight in broilers

The consistency of the effect of selection on the frequencies of endogenous avian viral (eav) and endogenous viral (ev) specific restriction fragment length polymorphism (RFLP) bands was studied in two broiler lines selected from a single base population and in an F2 population derived from a reciprocal cross of both lines. One broiler line (FC line) was selected for low feed conversion ratio and the other line (GL line) was selected for high 6-wk body weight. In the F2 population, the band frequencies were determined in groups representing separate tails of the distribution of two production traits, namely, low feed conversion ratio between 29 and 42 d of age and body weight at 42 d of age. The F2 population consisted of 288 females belonging to 24 full-sib families. To rule out family effects, the tails for these production traits were composed by either the best or by the worst female performer for each trait in each full-sib family. In total, 29 HindIII-eav, 34 MspI-eav, and 21 BamHI-ev bands could be distinguished by RFLP analysis. This report describes the influence of selection on 11 potentially interesting bands. Two bands, the 9.5-kb HindIII-eav and the 15-kb MspI-eav band, which were found both in higher frequencies in the parental FC line, were also found in higher (P < or = .05) frequencies in the F2 tail with a favorable feed conversion ratio. A third band, the 6.5-kb HindIII-eav band, present in lower frequencies in the parental GL line, was also present in lower (P < or = .05) frequencies in the F2 tail of birds with heavy body weight.

Genetic differences in susceptibility of chicken lines to infection with infectious bursal disease virus

Mortality rates in 11 inbred and partially inbred chicken lines inoculated with a very virulent strain (CS89) of infectious bursal disease virus (IBDV) varied considerably, being highest (almost 80%) in a Brown Leghorn line (BrL). Bursa of Fabricius to body weight ratios were depressed in the survivors in each line, but no differences were observed between lines. However, histological examination of bursae from survivors showed that, although bursal damage occurred in every line, it was most severe in the two lines (BrL and White Leghorn W1) in which the highest mortality was recorded. Experiments with F1 matings between highly susceptible and highly resistant lines showed that resistance was partially dominant and that there were no maternal effects. Experiments using F2 and backcross chicks suggested the involvement of a single gene and indicated no involvement of the MHC. There was considerable variation between lines in IBDV-specific antibody, measured by ELISA, both in the vaccinated parent hens and in the amounts of inherited maternal antibody and its rate of decay in the progeny.

A preliminary linkage map of the chicken genome

We have used backcross progeny from a cross between two inbred lines of chickens to construct a linkage map of the chicken. The map currently consists of 100 loci, identified using either anonymous cloned fragments of genomic DNA or sequences corresponding to cloned genes. Parent birds were derived from two lines of White Leghorn chickens, which differ in susceptibility to a number of diseases. Restriction fragment length variants were identified by comparison of the DNA of these two parent birds using a panel of seven restriction enzyme digests and the segregation pattern observed in progeny of these two birds. Restriction fragment length variants were detected for approximately 41% of the clones tested, whether these were known genes or random genomic fragments. This high level of variability was also reflected in the presence of variation within the parental lines for some clones. The overall size of the linkage groups and the progressively higher incidence of linkage as further clones were added suggests that the map covers the majority of the genome, although it is unlikely that there are marker loci on all the microchromosomes. The present map will be of use in locating genes affecting disease resistance, but also illustrates the relative ease with which such maps for the chicken can be constructed.

Variation in susceptibility of inbred lines of chickens to seven species of Eimeria

The pattern of oocyst production of 8 inbred lines of chickens was compared for each of the 7 species of Eimeria which infect this host. Both the overall numbers and the pattern of oocyst production differed in the inbred lines, but there was no evidence of prolonged cycling of schizogenic developmental stages. Comparison of the numbers of oocysts produced by the different lines indicates that there may be common genetic factors affecting susceptibility to 6 of the 7 species. Surprisingly there appears to be an inverse relationship between susceptibility to E. tenella and susceptibility to the other species: lines which produced most oocysts of E. tenella produced least oocysts of the other species and vice-versa.

Endogenous viral genes in thirteen highly inbred chicken lines and in lines selected for immune response traits

Thirteen highly inbred lines of chickens of Leghorn, Spanish, and Egyptian Fayoumi origin, four partly inbred Leghorn lines selected for MHC alleles and immune response to GAT (Ir-GAT), and two replicated, noninbred Leghorn lines divergently selected for multiple immune response traits were subjected to molecular genotyping for endogenous viral (ev) gene sequences. In all highly inbred lines of Leghorn origin, ev1 alone or both ev1 and ev2 were observed. The Spanish and Fayoumi lines had three and five ev genes, respectively, most of which were not readily identifiable with standard Leghorn ev gene loci. The Leghorn lines selected for MHC and Ir-GAT had ev1 fixed in the population. Differences in ev3 and ev5 gene frequency were associated with Ir-GAT in the B1 haplotype, but not in the B19 haplotype. In the noninbred lines, which were divergently selected for multiple traits of immune responsiveness, ev6 and ev9 differed in frequency between lines, and both were in lower frequency in the lines selected for high immunoresponsiveness. These two ev genes are the only ones known in White Leghorns that have the gs-chf+ phenotype [expressing chicken helper factor (chf) but not expressing group-specific antigen (gs)].

Restriction fragment length polymorphism analysis of endogenous avian leukosis viral loci: determination of frequencies in commercial broiler lines

Four component lines of a commercial broiler stock were analyzed by restriction fragment length polymorphism (RFLP) analysis, for the presence of endogenous avian leukosis virus loci. The resulting RFLP patterns of endogenous virus (ev) loci for the four strains were further characterized in terms of number of loci per animal and frequency. Loci were also analyzed within limits for major structural alterations and deletions to discern whether certain loci were similar to previously identified loci in White Leghorn layer birds. The ev RFLP patterns for these broiler lines were found to be highly complex and contained many loci unreported in White Leghorn layer birds.