Effects of higher-order nuclear structure and Rad51 overexpression on radiation-induced chromosome rearrangements

The microchromosomes (MICs) in chicken DT40 lymphocytes are usually clustered in the center of the nucleus, whereas the macrochromosomes (MACs) are preferentially located toward the nuclear periphery. This compartmentalized architecture of the nucleus is associated with a low frequency of translocations between MICs and MACs after induction of DNA breaks by a radiation track(s). In contrast, the MICs in chick embryo fibroblasts (CEFs) tend to be located throughout the entire nuclear volume. The resulting side-to-side arrangement of MIC and MAC territories favors radiation-induced MIC/MAC translocations, which occur more frequently in CEF cells than MIC/MIC or MAC/MAC rearrangements. Collectively, our results suggest that preformed physical contacts are a prerequisite for the generation of chromosome rearrangements through recombinational repair of DNA damage. Cell type-specific higher-order nuclear organization may prevent or stimulate the formation of particular chromosome aberrations in pathology and evolution. Ectopic expression of the recombination protein Rad51 can protect cells from radiation-induced translocations. The repair activity of overexpressed Rad51 is more important for cells that are irradiated in S/G(2) phase than for cells in G(1) phase. Evidently, homologous recombination between sister chromatids of a replicated chromosome is more frequent than that between homologous or heterologous chromosomes during G(1) phase.     

Analyses of chicken immunoglobulin light chain cDNA clones indicate a few germline V lambda genes and allotypes of the C lambda locus.

cDNA libraries of chicken spleen and Harder gland (a gland enriched with immunocytes) constructed in pBR322 were screened by differential hybridization and by mRNA hybrid-selected translation. Eleven L-chain cDNA clones were identified from which VL probes were prepared and each was annealed with kidney DNA restriction digests. All VL probes revealed the same set of bands, corresponding to about 15 germline VL genes of one subgroup. The nucleotide sequences of six VL clones showed greater than or equal to 85% homology, and the predicted amino acid sequences were identical or nearly identical to the major N-terminal sequence of L-chains in chicken serum. These findings, and the fact that the VL clones were randomly selected from normal lymphoid tissues, strongly indicate that the bulk of chicken L-chains is encoded by a few germline VL genes, probably much less than 15 since many of the VL genes are known to be pseudogenes. Therefore, it is likely that somatic mechanisms operating prior to specific triggering by antigen play a major role in the generation of antibody diversity in chicken. Analysis of the constant region locus (sequencing of CL gene and cDNAs) demonstrate a single CL isotype and suggest the presence of CL allotypes.     

Microisolation of the chicken Z chromosome and construction off microclone libraries.

A simple method was used to adapt a standard light microscope for the collection of chicken Z chromosomes from mitotic-metaphase spreads. The DNA of the collected chromosomes was enzymatically amplified using a partially degenerate primer. The resulting sequences, within a size range of 200-800 bp, were cloned to produce a Z chromosome DNA library, using blunt-end ligation into a SmaI-digested pUC18 plasmid (the SureClone system; Pharmacia, U.S.A.). The microcloning experiments produced 1250 clones; the size range of the cloned inserts was 250-800 bp, with an average of 480 bp (176 clones examined). Using male chicken genomic DNA as a probe, 10 out of 17 randomly selected clones showed strong positive signals on Southern blots, confirming the origin of the inserts as chicken DNA. In addition, the Z-chromosome origin of a selected microclone was verified in a semiquantitative Southern blot hybridization that showed positive signals with intensities that were approximately twice as strong for male (ZZ) as for female (ZW) chicken genomic DNA when the clone was used as a probe. The value of these libraries in further analysis of the chicken Z chromosome is discussed.     

Isolation of chicken cellular DNA sequences with homology to the region of viral oncogenes that encodes the tyrosine kinase domain.

A library of chicken genomic DNA was screened for sequences that could hybridize to a cloned DNA fragment containing the transforming gene (v-fps) of Fujinami sarcoma virus. In addition to c-fps, two unique chicken cellular DNA sequences were isolated that hybridized weakly to v-fps. These sequences hybridized with many other viral oncogenes encoding tyrosine kinases. Sequence analysis of the region where homology was detected revealed a region that is highly conserved among the tyrosine kinases both at the nucleotide and amino acid levels. Although we were unable to detect expression of either chicken cellular DNA sequence in a variety of avian tissues, the data suggest the existence of additional members of the tyrosine kinase gene family. Screening genomic libraries for sequences that hybridize weakly to functional regions of other genes may prove useful for the isolation and characterization of additional members of other gene families.     

Isolation of duplicated human c-src genes located on chromosomes 1 and 20.

The oncogene (v-src) of Rous sarcoma virus apparently arose by transduction of the chicken gene known as c-src(chicken). We isolated DNA fragments representative of two src-related loci from recombinant DNA bacteriophage libraries of the human genome. One of these loci, c-src1(human), appeared to direct the synthesis of a 5-kilobase polyadenylated RNA that presumably encodes pp60c-src(human). Probes specific for the other locus, c-src2(human), did not hybridize to polyadenylated RNA prepared from a variety of human cell lines. Partial nucleotide sequence determinations of the loci demonstrated that c-src1(human) is highly related to chicken c-src and that c-src2(human) is slightly more divergent. The sequences imply that the final two coding exons of each human locus are identical in length to those of chicken c-src and that the location of an amber stop codon is unchanged in all three loci. c-src1(human) has been mapped to chromosome 20, and the second locus is located on chromosome 1. We conclude that c-src1(human) is the analog of c-src(chicken) and that the duplicated locus, c-src2(human), may also be expressed.     

Molecular cloning and characterization of the chicken DNA locus related to the oncogene erbB of avian erythroblastosis virus.

Chicken cell DNA contains sequences which are homologous to the avian erythroblastosis virus oncogene v-erb. These cellular sequences (c-erb) have been isolated from a library of chicken cell DNA fragments generated by partial digestion with AluI and HaeIII and shown to be shared by at least two loci in the chicken DNA. One of them, denoted c-erbB, contains approximately 1.8 kilobase pairs of chicken DNA homologous to the 3' part of the v-erb oncogene (v-erbB). Restriction mapping studies show that the c-erbB DNA sequences homologous to v-erbB are distributed among six EcoRI fragments located in a single genomic region. Heteroduplexes between v-erbB in viral RNA and cloned c-erbB DNA show that the chicken DNA sequences homologous to v-erbB are interrupted by 11 DNA sequences not present in the v-erb oncogene. We conclude from our data that the c-erbB locus might represent the cellular progenitor for the v-erbB domain of the v-erb oncogene.     

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.     

DNA sequence organisation in avian genomes

By means of renaturation kinetics of DNA of the three avian species Cairina domestica, Gallus domesticus and Columba livia domestica the following major DNA repetition classes were observed: a very fast reannealing fraction comprising about 15% of the DNA, a fast or intermediate reannealing fraction that makes up 10%, and a slow reannealing fraction of about 70%, which apparently renatures with single copy properties. — Comparing the reassociation behaviour of short (0.3 kb) and long (>2 kb) DNA fragments of duck and chicken it becomes apparent that only 12% (duck) and 28% (chicken) of the single copy DNA are interspersed with repetitive elements on 2 to 3 kb long fragments. The lengths of the repetitive sequences were estimated by optical hyperchromicity measurements, by agarose A-50 chromatography of S₁ nuclease resistant duplexes and by electron microscopic measurements of the S₁ nuclease resistant duplexes. It was found that in the case of the chicken DNA the single copy sequences alternating with middle repetitive ones are at least 2.3 kb long; the interspersed moderate repeats have a length average of at least 1.5 kb. The sequence length of the moderate repeats in duck DNA is smaller. The results show that the duck and the chicken genomes do not follow the short period interspersion pattern of genome organisation, characteristic of the eucaryotic organisms studied so far.     

Census of orthologous genes and self-organizing maps of biologically relevant transcriptional patterns in chickens (Gallus gallus)

The launch of large-scale chicken expressed sequence tags (EST) projects has placed the chicken in the lead for the number of EST sequences in agriculturally important animals. More than 451,000 chicken ESTs derived from over 158 libraries have been deposited in the NCBI dbEST database as of December 2003. But how many genes these ESTs represent and how they are expressed in different chicken tissues/organs remain undetermined. In the present research, we developed a human gene-based strategy for census of chicken orthologous genes and identification of their expression patterns. Among 34,157 human coding genes used in the study, BLAST analysis revealed that 11,066 genes provisionally matched 248,628 chicken ESTs. Based on the average EST abundance of the orthologous genes, the current public repository of chicken ESTs could represent 20,000 provisional genes. Analysis of gene expression in 14 single tissues/organs showed that approximately 15% of genes were expressed exclusively in single tissue/organ whereas the remaining 85% of genes were co-expressed in two or more tissues/organs. A majority (91.15%) of genes expressed in chicken embryos were also expressed at post-hatch stages, indicating that most genes activated in chicken embryos could serve housekeeping functions. Self-organizing maps (SOM) analysis organized 8807 provisional genes in selected chicken tissues into 98 clusters with each cluster being indicative of common regulatory factors and pathways. A total of 969 provisional orthologous genes were identified as preferentially expressed genes (PEGs) in various chicken tissues/organs (LOD>3.0). No doubt, the present study on gene expression patterns will provide insight into dynamics of metabolic pathways and tissue/organ programming and reprogramming in chickens.     

Incremental truncation as a strategy in the engineering of novel biocatalysts

The application and success of combinatorial approaches to protein engineering problems have increased dramatically. However, current directed evolution strategies lack a combinatorial methodology for creating libraries of hybrid enzymes which lack high homology or for creating libraries of highly homologous genes with fusions at regions of non-identity. To create such hybrid enzyme libraries, we have developed a series of combinatorial approaches that utilize the incremental truncation of genes, gene fragments or gene libraries. For incremental truncation, Exonuclease III is used to create a library of all possible single base-pair deletions of a given piece of DNA. Incremental truncation libraries (ITLs) have applications in protein engineering as well as protein folding, enzyme evolution, and the chemical synthesis of proteins. In addition, we are developing a methodology of DNA shuffling which is independent of DNA sequence homology.     

Homology of single copy and repeated sequences in chicken, duck, Japanese quail, and ostrich DNA.

The extent of reassociation of 3H-labeled repetitive or single copy DNA sequences from the chicken with excess unlabeled DNA from the duck, the Japanese quail, and the ostrich, respectively, was measured by hydroxylapatite chromatography. Chicken repetitive DNA reassociated to an equal or greater extent than chicken single copy DNA with the DNA of each of the other birds. Using an isolated subfraction of chicken repetitive DNA representing those DNA sequences common to the chicken and ostrich genomes, we determined that many repetitive DNA sequences that occur at high repetition frequency in the chicken genome have a much lower repetition frequency in ostrich DNA. The data indicate that there has been a striking change in the number of copies of many repetitive DNA sequences during avian evolution.     

MC1R是控制鸡黑色素形成的候选主效基因

黑素皮质素受体1 (melanocortin 1-receptor, MC1R)基因是控制动物黑色素合成的重要基因.采用多聚酶链反应-单链构象多态性分析(PCR-SSCP)以及DNA测序的方法,在由丝羽乌骨鸡与明星肉鸡为亲本建立的中国农业大学资源家系群体鸡MC1R基因的编码区检测到3个单核苷酸多态位点,并对该单核苷酸多态性进行了分析.结果显示,鸡MC1R基因编码区引物3扩增片段多态性是由G→A（867位）点突变引起的,引物5扩增片段的多态性是由C→T（1 292位）与C→G（1 377位）两个点突变引起的,最后对单核苷酸多态性与肤色、肉色、胫色与内脏膜色等黑色素性状进行了卡方独立性分析,结果显示,MC1R基因编码区867处突变与鸡的肤色性状显著相关（P＜0.05）,1 292处突变与鸡的活体胫色性状显著相关（P＜0.05）,1 377处突变与鸡的肉色性状显著相关（P＜0.05）.研究表明,MC1R基因可能是鸡黑色素性状的主效基因或者与鸡控制黑色素性状的主效基因连锁.     

Infectivity of Proviral DNA from Avian Sarcoma Virus-Transformed Mammalian Cells

The number of Rous viral genomes in the cellular DNA from two subclones (RS2/3, RS2/6) derived from the same clone of hamster BHK-21 cells transformed by Rous sarcoma virus was determined by hybridization with viral complementary DNA made in vitro, and the capacity of the cellular DNA to infect (transfect) chicken embryo fibroblasts was compared before and after shearing this DNA to about the size of the provirus (6 x 10(6) to 7 x 10(6) daltons). The two subclones differed widely both in their capacity to give rise to virus (inducibility) after fusion with chicken embryo fibroblasts and in level of expression of viral proteins. It was shown that cells of both subclones contain a single copy of Rous DNA and yield infectious DNA. However, whereas transfection of chicken embryo fibroblasts was successful with both unsheared (>/=18 x 10(6) daltons) and sheared DNA from the most inducible subclone (RS2/3 subclone), which also expresses viral proteins to an appreciable amount, transfection with DNA from the least inducible subclone (RS2/6 subclone), in which viral proteins are not expressed, succeeded only with sheared DNA. It was then about as successful as with sheared or unsheared RS2/3 DNA. The lack of infectivity of unsheared RS2/6 DNA may be explained by the hypothesis proposed by Cooper and Temin (G. M. Cooper and H. T. Temin, J. Virol. 17:422-430, 1976) to explain the lack of infectivity of DNA from certain chicken cells producing spontaneously low amounts of RAV-0 and resistant to exogenous RAV-0 infection, that is, that the viral genome (proviral DNA) is linked to a cis-acting control element which blocks its expression. This linkage might originate, in RS2/6 cells, from translocation of cellular DNA containing the single proviral copy.     

Clustering and methylation of repeated DNA: persistence in avian development and evolution.

In the chicken genome, clusters of repeated DNA sequences occur which have alternate arrangements of the component sequence elements. Many of these clustered, repeated sequences are extensively methylated. We have established that both their arrangement and their methylation are invariant regardless of the source of chicken DNA. Comparisons included DNA from sperm, from a series of embryonic stages, from tissues of single adult individuals, and from thirty individual chickens of two strains. These same sequences are found in the DNA of some avian species related to chickens, and there they show the same clustered, methylated form. In related species, some of the arrangements found in chicken DNA are different or missing.     

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.     

Cloning of chicken embryo tRNA genes using single stranded nucleosomal DNA highly enriched for tRNA complementary sequences

DNA from chicken embryo nucleosome tetramers (about 760 base pairs in size) was enriched for tRNA genes by RPC-5 chromatography. The enriched DNA was hybridized with chicken embryo total tRNA and the hybridized DNA isolated utilizing a) avidinbiotin interaction, b) diazobenzyloxymethyl paper, and c) high temperature RPC-5 chromatography. The obtained single stranded DNA highly enriched for tRNA complementary sequences was hybridized with total DNA from nucleosome monomers (140--190 base pairs in size) and the excess of non hybridized monomer nucleosome DNA removed by Sepharose 4B chromatography. The hybrid molecules obtained were made fully double stranded by incubation with E. coli DNA polymerase I, DNA ligase, and exonuclease III. DNA was inserted into plasmid pBR322 by G-C joining procedure and the recombinant DNA used to transform the E. coli strain chi 1776. More than 70% of the transformants obtained hybridize to chicken embryo total tRNA.