Use of chicken microsatellite markers in turkey: a pessimistic view

Cross-species testing and utility of microsatellite loci in Indirana frogs

BACKGROUND

Microsatellite loci are widely used in population and conservation genetic studies of amphibians, but the availability of such markers for tropical and subtropical taxa is currently very limited. In order to develop resources for conservation genetic studies in the genus Indirana, we tested amplification success and polymorphism in 62 previously developed microsatellite loci, in eight Indirana species - including new candidate species. Developing genomic resources for this amphibian taxon is particularly important as it is endemic to the Western Ghats biodiversity hotspot, and harbours several endangered species.

FINDINGS

The cross-species amplification success rate varied from 11.3 % to 29.0 % depending on the species, with 29 - 80 % of the amplifying loci being polymorphic. A strong negative correlation between cross-species amplification success (and polymorphism) and genetic distance separating target from source species was observed.

CONCLUSIONS

Our results provide additional genetic support for the existence of genetically divergent cryptic species within the genus Indirana. The tested markers should be useful for population and conservation genetic studies in this genus, and in particular, for species closely related to the source species, I. beddomii.

Preliminary linkage map of the turkey (Meleagris gallopavo) based on microsatellite markers

The turkey is an agriculturally important species for which, until now, there is no published genetic linkage map based on microsatellite markers--still the markers most used in the chicken and other farm animals. In order to increase the number of markers on a turkey genetic linkage map we decided to map new microsatellite sequences obtained from a GT-enriched turkey genomic library. In different chicken populations more than 35-55% of microsatellites are polymorphic. In the turkey populations tested here, 43% of all turkey primers tested were found to be polymorphic, in both commercial and wild type turkeys. Twenty linkage groups (including the Z chromosome) containing 74 markers have been established, along with 37 other unassigned markers. This map will lay the foundations for further genetic mapping and the identification of genes and quantitative trait loci in this economically important species. Genome comparisons, based on genetic maps, with related species such as the chicken would then also be possible. All primer information, polymerase chain reaction (PCR) conditions, allele sizes and genetic linkage maps can be viewed at http://roslin.thearkdb.org/. The DNA is also available on request through the Roslin Institute.

Expressed sequence tags for the chicken genome from a normalized, ten-day-old white leghorn whole embryo cDNA library. 2. Comparative DNA sequence analysis of guinea fowl, quail, and turkey genomes

Accelerated efforts to develop a high-utility chicken genome map have resulted in the development of resources that may be useful for genetic analysis in other economically important poultry species. Here we describe a total of 26 comparative genomic DNA sequences (CGS) for the guinea fowl, Japanese quail, and domestic turkey developed using 10 primer pairs specific for 10 previously reported, unique, chicken expressed sequence tags (EST). The total length of CGS developed for each of the three species was 4,193, 4,597, and 6,057 bp in quail, turkey, and guinea fowl, respectively. About 70% of the CGS showed significant sequence similarity to reference database sequences, including the reference chicken EST and other avian and nonavian genes. A majority of the between-species comparisons of the CGS from all but two primer pairs were significant and ranged from 81 to 99%. The percentage similarity of the CGS appears to be a function of phylogenetic relatedness and was generally higher for comparisons between the chicken, quail, and turkey and lower between the guinea fowl and chicken, quail, or turkey. Maximum likelihood estimation of the phylogenetic relationships using CGS from two primer pairs also showed a closer relationship, as expected, among chicken, quail, and turkey than between guinea fowl and either chicken, quail, or turkey. Within the guinea fowl, quail, and turkey CGS developed, the total number of single nucleotide polymorphisms detected was 28, 17, and 14, respectively. Together, these resources represent tools that will facilitate genetic analysis of species that have been studied very little and our understanding of their genomes and genome evolution.

Chicken microsatellite primers are not efficient markers for Japanese quail

Domestic fowl or chicken (Gallus gallus) and Japanese quail (Coturnix japonica) belong to the family Phasianidae. The exchange of marker information between chicken and quail is an important step towards the construction of a high-resolution comparative genetic map in Phasianidae, which includes several poultry species of agricultural importance. We tested chicken microsatellite markers to see if they would be suitable as genetic linkage markers in Japanese quail. Twenty-six per cent (31/120) of chicken primers amplified individual loci in Japanese quail and 65% (20/31) of the amplified loci were found to be polymorphic. Eleven of the polymorphic loci were excluded as uninformative because of the lack of amplification in some individuals or high frequency of nonspecific amplification. The sequence information of the remaining nine loci revealed six of them to contain microsatellites that were nearly identical with those of the orthologous regions in chicken. For these six loci, allele frequencies were estimated in 50 unrelated quails. Although the very few chicken markers that do work well in quail could be used as anchor points for a comparative mapping, most chicken markers are not useful for studies in quail. Therefore, more effort should be committed to developing quail-specific markers rather than attempting to adapt chicken markers for work in quail.

Comparative analysis of microsatellite loci in chicken and turkey

Cross-species amplification of 520 chicken microsatellite markers was tested by polymerase chain reaction with genomic DNA of the turkey (Meleagris gallopavo). Each primer pair was tested at six different combinations of annealing temperature and MgCl2 concentration. A total of 280 (54%) of the primer pairs produced amplification products. The majority of these products were similar, if not identical in size to those expected based on the fragment sizes of the corresponding chicken loci. Structure of the dinucleotide repeat and flanking sequences was examined for 13 turkey fragments (amplified with chicken primers) and 5 chicken fragments (amplified with turkey primers). Sequence analysis found a wide array of mutations between species in addition to differences in repeat length. To estimate the usefulness of the amplified loci for genetic mapping in the turkey, allelic polymorphism was determined for 57 of the 280 amplified loci. A total of 20 of 57 markers (35%) were polymorphic with an average of 1.4 alleles per locus. The results of this study suggest that approximately 20% of the chicken microsatellite markers will be useful for mapping the turkey genome.Key words: microsatellite, chicken, turkey, Meleagris gallopavo.

Utility of chicken-specific microsatellite primers for mapping the turkey genome

As part of the University of Minnesota's initiative to map the turkey genome, we are currently evaluating chicken microsatellite loci for use in mapping the turkey genome. To date, 141 primer pairs have been tested for amplification at six different combinations of temperature and MgCl2 concentration. Microsatellite primer pairs from the Chicken Comprehensive Mapping Kit #2, and additional unpublished chromosome 1 and 2 primers were screened. Analyzable PCR products were produced from 78 of the 141 (55%) primer combinations. In the majority of cases (68%), PCR fragments obtained from the turkey were similar in size to respective chicken loci. The presence of dinucleotide repeats (CA/TG repeats) was determined by Southern hybridization with a (TG)15, oligonucleotide probe. Five of 12 (41.63%) turkey fragments hybridized under low stringency conditions. The length of the dinucleotide repeats in the turkey, relative to the chicken sequences, were found to correspond directly with hybridization intensity. Amplification of homologous loci was confirmed by direct sequencing and subsequent alignment of the turkey and chicken sequences. The results of this study indicate that the use of chicken-specific microsatellite primers will rapidly and significantly enhance construction of a genetic map for the turkey.

Development and characterization of expressed sequence tags for the turkey (Meleagris gallopavo) genome and comparative sequence analysis with other birds

Twenty-one randomly selected clones from a turkey (Meleagris gallopavo) pituitary complementary DNA (cDNA) library were sequenced to develop expressed sequence tags (ESTs) for this economically important avian species whose genome is among the least understood. Primers specific for the ESTs were used to produce amplicons from the genomic DNA of turkey, chicken (Gallus gallus), guinea fowl (Numidia meleagris), pigeon (Columba domestica), and quail (Corturnix japonica). The amplicons were sequenced and analyzed for sequence variation within- and similarity among-species and with GenBank database sequences. The proportion of shared bases between the turkey sequence and the consensus sequence from each of the other species ranged from 72% to 93% between turkey and pigeon and quail and between turkey and chicken, respectively. The total number of single nucleotide polymorphisms (SNPs) observed ranged from 3 in quail to 18 in chicken out of 4898 and 5265 bases analyzed, respectively. The most frequent nucleotide variation observed was a C-->T transition. Linkage analysis of one such SNP in the backcross progeny of the East Lansing reference DNA panel, localized TUS0005, the chicken sequence derived from primers specific for turkey TUT2E EST, to chromosome 4. The ESTs reported, as well as the SNPs may provide a useful resource for ongoing efforts to develop high utility genome maps for the turkey and chicken. The primers described can also be used as a tool in future investigations directed at further understanding the biology of the guinea fowl, pigeon and quail and their relatedness to the turkey.

Applicability of bovine microsatellite markers for population genetic studies on African buffalo (Syncerus caffer)

The applicability of bovine autosomal microsatellite markers for population genetic studies on African buffalo was investigated. A total of 168 microsatellite markers were tested for PCR amplification on a test panel of seven African buffalo. Amplification was observed for 139 markers (83%), and 101 markers were studied further with 91 (90%) being polymorphic. The mean number of alleles per marker was 5.0 (SE = 0.2) and the mean heterozygosity per marker was 0.61 (SE = 0.03). Considering the overall high level of polymorphism, it was concluded that most bovine microsatellite markers are applicable in African buffalo.

Japanese quail microsatellite loci amplified with chicken-specific primers

Forty-eight primer pairs for chicken (Gallus gallus) microsatellite loci were tested in polymerase chain reaction (PCR) amplification of Japanese quail (Coturnix japonica) genomic DNA. Amplification products were obtained from 28 primer-pairs (58.3%) after optimizing the PCR conditions. Eleven (22.9%) of these generated specific products and 17 yielded non-specific amplification products. Eight markers (ADL0037, ADL0038, ADL0142, ADL0143, ADL0206, ADL0315, ADL0366, and HUJ0006) were polymorphic and three were monomorphic (ADL0023, ADL0024, and ADL0257) in four Japanese quail populations. Specific amplification products from each of the 11 PCR primers were sequenced. Seven of the eight polymorphic and one of three monomorphic markers contained simple tandem repeats. Six of these microsatellite loci (ADL0037, ADL0315, ADL0142, ADL0143, ADL0366 and ADL0257) may be homologous to the corresponding chicken loci from which the markers were developed.