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.     

Genetic analysis of three loci homologous to human G9a: evidence for linkage of a class III gene with the chicken MHC

The cDNA clones of two newly discovered genes in the class III region of the human major histocompatibility complex (MHC) were hybridized to chicken DNA. One of these cDNA clones (pG9a-4C7), which detects the single-copy human G9a (BAT8) gene, gave a repeatable restriction pattern. This heterologous cDNA clone was used to detect and map three different Pst I restriction fragment length polymorphisms among the two internationally recognized chicken reference populations. Two of the loci were unlinked to previously mapped markers, but one polymorphism cosegregated with the EaB locus in the Compton mapping population. These results provide evidence that some genes of the mammalian class III region, such as G9a, may be linked to the MHC in chickens.     

Chicken B-cell marker chB6 (Bu-1) is a highly glycosylated protein of unique structure

 The chB6 molecule is expressed on chicken B cells throughout most of their development, as well as on some non-lymphoid cells. It has long been used as an allotypic marker in important studies of B-cell development, though its function is unknown. We isolated a chB6 cDNA by expression cloning and sequenced two further alleles following polymerase chain reaction amplification. The results show that chB6 is a typical type I transmembrane protein, highly glycosylated in the extracellular region and carrying a large intracellular region. It has no recognizable similarity to known mammalian molecules and thus represents a unique B-cell marker. Its presence in chickens may be related to differences in the properties of B-cell development between chickens and mammalian species. The sequences of the different alleles of this gene revealed a higher level of polymorphism than expected. A restriction fragment length polymorphism linked to the CHB6 gene has been used to determine its location on the linkage map of the chicken genome, which will allow the definitive evaluation of reported associations with disease resistance. Received: 21 February 1996 / Revised: 26 March 1996     

Molecular cloning of chicken metallothionein. Deduction of the complete amino acid sequence and analysis of expression using cloned cDNA.

A cDNA library was constructed using RNA isolated from the livers of chickens which had been treated with zinc. This library was screened with a RNA probe complementary to mouse metallothionein-I (MT), and eight chicken MT cDNA clones were obtained. All of the cDNA clones contained nucleotide sequences homologous to regions of the longest (376 bp) cDNA clone. The latter contained an open reading frame of 189 bp, and the deduced amino acid sequence indicates a protein of 63 amino acids of which 20 are cysteine residues. Amino acid composition and partial amino acid sequence analyses of purified chicken MT protein agreed with the amino acid composition and sequence deduced from the cloned cDNA. Amino acid sequence comparisons establish that chicken MT shares extensive homology with mammalian MTs, but is more closely related to the MT-II than to the MT-I isoforms from various mammals. The nucleotide sequence of the coding region of chicken MT shares approximately 70% homology with the consensus sequence for the mammalian MTs. Southern blot analysis of chicken DNA indicates that the chicken MT gene is not a part of a large family of related sequences, but rather is likely to be a unique gene sequence. In the chicken liver, levels of chicken MT mRNA were rapidly induced by metals (Cd2+, Zn2+, Cu2+), glucocorticoids and lipopolysaccharide. MT mRNA was present in low levels in embryonic liver and increased to high levels during the first week after hatching before decreasing again to the basal levels found in adult liver. The results of this study establish that MT is highly conserved between birds and mammals and is regulated in the chicken by agents which also regulate expression of mammalian MT genes. However, in contrast to the mammals, the results suggest the existence of a single isoform of MT in the chicken.     

Isolation and characterization of cDNA clones for chicken major histocompatibility complex class II molecules

The chicken major histocompatibility complex (MHC), the B complex, is being intensively analysed at the DNA level. To further probe the molecular structure of chicken MHC class II genes, cDNA clones coding for chicken MHC class II (B-L) p chain molecules were isolated from an inbred G-B2 Leghorn chicken spleen and liver. Twenty-nine cDNA clones were isolated from the spleen and eight cDNA clones were isolated from the liver. Based on restriction maps, most clones could be clustered into one family of genes. Four cDNA clones were sequenced (S7, S10 and S19 from the spleen and L1, which was identical to S19, from the liver). Complete amino acid sequences of B-Lβ chain molecules were predicted from the nucleotide sequences of the cDNA clones. Although both the nature and the location of the conserved residues were similar in chicken and mammalian sequences, some species-specific differences were found, suggesting that the structures of the B-L molecules of this haplotype are similar, but not identical, to their mammalian counterparts.     

A first-generation map of the turkey genome.

A primary linkage map of the domestic turkey (Meleagris gallopavo) was developed by segregation analysis of genetic markers within a backcross family. This reference family includes 84 offspring from one F1 sire mated to two dams. Genomic DNA was digested using one of five restriction enzymes, and restriction fragment length polymorphisms were detected on Southern blots using probes prepared from 135 random clones isolated from a whole-embryo cDNA library. DNA sequence was subsequently determined for 114 of these cDNA clones. Sequence comparisons were done using BLAST searches of the GenBank database, and redundant sequences were eliminated. High similarity was found between 23% of the turkey sequences and mRNA sequences reported for the chicken. The current map, based on expressed genes, includes 138 loci, encompassing 113 loci arranged into 22 linkage groups and an additional 25 loci that remain unlinked. The average distance between linked markers is 6 cM and the longest linkage group (17 loci) measures 131 cM. The total map distance contained within linkage groups is 651 cM. The present map provides an important framework for future genome mapping in the turkey.     

A comparative map of chicken chromosome 24 and human chromosome 11

To improve the physical and comparative map of chicken chromosome 24 (GGA24; former linkage group E49C20W21) bacterial artificial chromosome (BAC) contigs were constructed around loci previously mapped on this chromosome by linkage analysis. The BAC clones were used for both sample sequencing and BAC end sequencing. Sequence tagged site (STS) markers derived from the BAC end sequences were used for chromosome walking. In total 191 BAC clones were isolated, covering almost 30% of GGA24, and 76 STS were developed (65 STS derived from BAC end sequences and 11 STS derived within genes). The partial sequences of the chicken BAC clones were compared with sequences present in the EMBL/GenBank databases, and revealed matches to 19 genes, expressed sequence tags (ESTs) and genomic clones located on human chromosome 11q22-q24 and mouse chromosome 9. Furthermore, 11 chicken orthologues of human genes located on HSA11q22-q24 were directly mapped within BAC contigs of GGA24. These results provide a better alignment of GGA24 with the corresponding regions in human and mouse and identify several intrachromosomal rearrangements between chicken and mammals.     

Chicken immunoglobulin gamma-heavy chains: limited VH gene repertoire, combinatorial diversification by D gene segments and evolution of the heavy chain locus

cDNA clones encoding the variable and constant regions of chicken immunoglobulin (Ig) gamma-chains were obtained from spleen cDNA libraries. Southern blots of kidney DNA show that the variable region sequences of eight cDNA clones reveal the same set of bands corresponding to approximately 30 cross-hybridizing VH genes of one subgroup. Since the VH clones were randomly selected, it is likely that the bulk of chicken H-chains are encoded by a single VH subgroup. Nucleotide sequence determinations of two cDNA clones reveal VH, D, JH and the constant region. The VH segments are closely related to each other (83% homology) as expected for VH or the same subgroup. The JHs are 15 residues long and differ by one amino acid. The Ds differ markedly in sequence (20% homology) and size (10 and 20 residues). These findings strongly indicate multiple (at least two) D genes which by a combinatorial joining mechanism diversify the H-chains, a mechanism which is not operative in the chicken L-chain locus. The most notable among the chicken Igs is the so-called 7S IgG because its H-chain differs in many important aspects from any mammalian IgG. The sequence of the C gamma cDNA reported here resolves this issue. The chicken C gamma is 426 residues long with four CH domains (unlike mammalian C gamma which has three CH domains) and it shows 25% homology to the chicken C mu. The chicken C gamma is most related to the mammalian C epsilon in length, the presence of four CH domains and the distribution of cysteines in the CH1 and CH2 domains. We propose that the unique chicken C gamma is the ancestor of the mammalian C epsilon and C gamma subclasses, and discuss the evolution of the H-chain locus from that of chicken with presumably three genes (mu, gamma, alpha) to the mammalian loci with 8-10 H-chain genes.     

Comparative map between chicken Chromosome 15 and human chromosomal region 12q24 and 22q11-q12

The physical and comparative map of GGA15 was improved by the construction of 9 BAC contigs around loci previously mapped on GGA15 by linkage analysis. In total, 240 BAC clones were isolated, covering 30–35% of GGA15, and 120 STS were developed (104 STS derived from BAC end sequences and 18 STS derived within genes). Seventeen chicken orthologues of human genes located on human Chr 22q11-q12 were directly mapped within BAC contigs of GGA15. Furthermore, the partial sequences of the chicken BAC clones were compared with sequences present in the EMBL/GenBank databases and revealed matches to 26 genes, ESTs, and genomic clones located on HSA22q11-q12 and HSA12q24. These results provide a better alignment of GGA15 with the corresponding regions in human and mouse, and improve our knowledge of the evolution and dynamics of the vertebrate genome. GenBank Accession Numbers: The nucleotide sequence data reported in this paper have been submitted to GenBank and have been assigned the accession numbers BZ592394-BZ592544.     

Extending the chicken-human comparative map by placing 15 genes on the chicken linkage map

To increase the number of type I loci on the chicken linkage map, chicken genes containing microsatellite sequences (TAn, CAn, GAn, An) were selected from the nucleotide sequence database and primers were developed to amplify the repeats. Initially, 40 different microsatellites located within genes were tested on a panel of animals from diverse breeds, and identified 17 polymorphic microsatellites. These polymorphisms allowed us to add 15 new genes to the chicken linkage map. In addition, two genes were added to the chicken map by fluorescent in situ hybridization. As the map position of the human homologues of 13 of these genes is known, these markers extend the comparative map between chicken and man. Our results confirm and refine conserved regions between chicken and man on chicken chromosomes 2 and 7 and on linkage group E29C09W09. Furthermore, an additional conserved region is identified on chromosome 7.     

Isolation of a genomal clone containing chicken histone genes.

We have used enriched chicken histone cDNA to select genomal clones from a chicken library. Because the cDNA probe also contained other sequences, a further screening of positive plagues with negative probes eliminated most non-histone gene clones. One 'positively-selected' genomal clone, lambda CH-01, hybridised with cloned sea-urchin histone genes and also detected histone genes in EcoRI-digested genomal sea-urchin DNA. Limited DNA sequencing of HaeIII fragments identified two sequences within the coding region of chicken histone H2A. A third fragment predicted an amino acid sequence with strong homology to an H1 histone sequence.     

Moss (Physcomitrella patens) Expressed Sequence Tags Include Several Sequences which are Novel for Plants*

The moss Physcomitrella patens (Hedw.) B.S.G. is the first land plant in which gene disruption by homologous recombination Is directly accessible. In order to obtain cloned sequences which may be used in such an approach, complementary DNAs (cDNAs) have been isolated by subtractlve hybridisation of representative cDNA libraries from cytoklnin-treated tissue. Sequencing of these clones from both ends yielded over 35 kb of non-redundant sequence Information, of which 20 kb results from clones which appear to be novel to plants. Database comparisons have revealed that 39 of the expressed sequence tags (ESTs) generated show significant homology to identified sequences. Analysis of these ESTs shows a high degree of conservation between Physcomitrella and seed plant sequences, and codon usage is found to be very similar to that In dicotyledonous species. Furthermore, 43 sequences showing no significant homology to sequences in the databases represent previously unidentified expressed genes.     

Human thymidine kinase gene: molecular cloning and nucleotide sequence of a cDNA expressible in mammalian cells.

A cDNA containing the entire coding region of the human thymidine kinase gene has been molecularly cloned. The cDNA is under the control of a simian virus 40 promoter and is expressible in mammalian cells. The complete nucleotide sequence of the human thymidine kinase cDNA has been determined. The cDNA is 1,421 base pairs in length and has a large open reading frame of 702 base pairs capable of specifying a protein with a molecular weight of 25,504. Genomic Southern blotting experiments show that sequences homologous to the human thymidine kinase cDNA are conserved among many vertebrates, including prosimians (lemur), tree shrews, rats, mice, and chickens. Direct comparison of the nucleotide sequences of the human thymidine kinase cDNA and the chicken thymidine kinase gene reveals ca. 70% overall homology. This homology is extended further at the amino acid sequence level, with greater than 74% amino acid residues matched between the human and chicken thymidine kinase proteins.     

An expressed sequence tag database of T-cell-enriched activated chicken splenocytes: sequence analysis of 5251 clones

The cDNA and gene sequences of many mammalian cytokines and their receptors are known. However, corresponding information on avian cytokines is limited due to the lack of cross-species activity at the functional level or strong homology at the molecular level. To improve the efficiency of identifying cytokines and novel chicken genes, a directionally cloned cDNA library from T-cell-enriched activated chicken splenocytes was constructed, and the partial sequence of 5251 clones was obtained. Sequence clustering indicates that 2357 (42%) of the clones are present as a single copy, and 2961 are distinct clones, demonstrating the high level of complexity of this library. Comparisons of the sequence data with known DNA sequences in GenBank indicate that approximately 25% of the clones match known chicken genes, 39% have similarity to known genes in other species, and 11% had no match to any sequence in the database. Several previously uncharacterized chicken cytokines and their receptors were present in our library. This collection provides a useful database for cataloging genes expressed in T cells and a valuable resource for future investigations of gene expression in avian immunology. A chicken EST Web site (http://udgenome. ags.udel. edu/chickest/chick.htm) has been created to provide access to the data, and a set of unique sequences has been deposited with GenBank (Accession Nos. AI979741-AI982511). Our new Web site (http://www. chickest.udel.edu) will be active as of March 3, 2000, and will also provide keyword-searching capabilities for BLASTX and BLASTN hits of all our clones.     

Chicken microsatellite markers isolated from libraries enriched for simple tandem repeats

The total number of microsatellite loci is considered to be at least 10-fold lower in avian species than in mammalian species. Therefore, efficient large-scale cloning of chicken microsatellites, as required for the construction of a high-resolution linkage map, is facilitated by the construction of libraries using an enrichment strategy. In this study, a plasmid library enriched for tandem repeats was constructed from chicken genomic DNA by hybridization selection. Using this technique the proportion of recombinant clones that cross-hybridized to probes containing simple tandem repeats was raised to 16%, compared with < 0·1% in a non-enriched library. Primers were designed from 121 different sequences. Polymerase chain reaction (PCR) analysis of two chicken reference pedigrees enabled 72 loci to be localized within the collaborative chicken genetic map, and at least 30 of the remaining loci have been shown to be informative in these or other crosses.     

Molecular cloning of a multifunctional chicken protein acting as the prolyl 4-hydroxylase beta-subunit, protein disulphide-isomerase and a cellular thyroid-hormone-binding protein. Comparison of cDNA-deduced amino acid sequences with those in other species.

Several recent studies indicate that a single polypeptide may act as the beta-subunit of prolyl 4-hydroxylase, the enzyme protein disulphide-isomerase and a cellular thyroid-hormone-binding protein. We report here the isolation and characterization of cDNA clones encoding this multifunctional protein in the chicken. All the coding sequences were determined on the basis of nucleotide sequencing of five cDNA clones and amino acid sequencing of the N-terminal end of the chicken beta-subunit. The processed polypeptide contains 493 amino acid residues, the size of the respective mRNA being about 2.7 kb. The chicken beta-subunit cDNA sequences were 78% homologous to the previously reported human beta-subunit cDNA sequences at the nucleotide level and 85% homologous at the amino acid level. The homology of the chicken beta-subunit sequences to those reported for bovine thyroid-hormone-binding protein and rat protein disulphide-isomerase was also 85% at the amino acid level. Primary-structure comparisons between the four species indicated that the two proposed active sites of protein disulphide-isomerase, the two Trp-Cys-Gly-His-Cys-Lys sequences, are located within highly conserved regions, which are also homologous to the active sites of a number of thioredoxins. The middle of the polypeptide has an additional conserved region 100 amino acid residues in length in which the degree of homology between the four species is 94% at the amino acid level. This long conserved region may also be important for some of the multiple functions of the protein. The four extreme C-terminal amino acids of the polypeptide in all four species are Lys-Asp-Glu-Leu, a sequence that has been suggested to function as a signal for the retention of a protein in the endoplasmic reticulum.     

Characterization and Genetic Mapping of Simple Sequence Repeats in the Rice Genome

We searched partial sequences of over 22,706 rice cDNA and 1220genomic DNA clones to find and characterize simple sequencerepeats (SSRs) in the rice genome. The most frequently foundrepeated SSR motif in both cDNA and genomic DNA sequences wasd(CCG/CGG)n. The second most frequently found SSR was d(AG/CT)n.In contrast with mammalian genomes, in which d(AC/GT)n sequencesare the most abundant, d(AC/GT)n sequences were not frequentlyobserved in rice. Sequences containing d(CCG/CGG)n, d(AG/CT)nrepeats, and other SSRs were chosen for polymorphism detection.It was predicted that 17 of 20 SSRs in cDNA sequences were locatedin 5'-untranslated regions near initiation codons. Twenty-twoloci can be mapped on our RFLP linkage map by these SSRs. Sixmarkers were tested with 16 japonica rice varieties as templatesfor PCR. Two markers exhibited amplified fragment length polymorphismamong these rice varieties, implying that SSRs are polymorphicamong rice varieties which have similar genetic backgrounds.Even these polymorphic SSRs are located within or around geneswhich code ubiquitous proteins.     

Isolation and characterization of the complete chicken beta-globin gene region: frequent deletion of the adult beta-globin genes in lambda.

A library of bacteriophage lambda clones containing chicken chromosomal DNA was screened, using the adult beta-globin cDNA plasmid pHb 1001 as a probe. Sixteen overlapping clones were isolated containing 35 kilobase pairs (kbp) of chicken DNA. Characterization of these clones revealed four beta-like globin genes, some genomically repeated sequences, but no pseudo-genes. The four beta-like genes have an average intergenic distance of less than half of that found for the mammalian beta-like globin gene clusters so far characterized. The overall features of the map were confirmed by genomic Southern analysis. Frequent deletions were shown to occur between the various beta-like globin genes during phage propagation. The presumptive hatching gene in particular was always associated with abnormal lambda clones although we were able to find one such clone that did contain a normal copy of the hatching gene itself. Probably such deletions explain the failure to recover this gene in previous attempts.