Organization of the sex-linked late-feathering haplotype in chickens

Nucleotide sequence analysis of polymerase chain reaction products confirmed that ev 21 integrated into one of two large homologous elements on the Z chromosome of late-feathering (LF) White Leghorn chickens. Southern blots of Not I-, Nae I-, Ksp I- and Bam HI-digested DNA from early-feathering (EF) and LF White Leghorns, that had been hybridized with a probe that flanks ev 21, indicated a 180 kb duplication of an unoccupied repeat in the LF genotype of White Leghorns. A Ksp I fragment that carries ev 21 was about 32 kb smaller than the Ksp I fragment found in EF DNA. In the evolution of LF, retroviral insertion into one of two large repeats and a 32 kb deletion may have generated LF.     

Cytologic and molecular analysis of 46,XXq- cells to identify a DNA segment that might serve as a probe for a putative human X chromosome inactivation center

Summary Cloned human X chromosome-specific DNA segments, derived from a recombinant phage library enriched for the human X and previously localized to different regions of the X, were used as probes in Southern blots to confirm the nature of a deletion of the long arm of the X chromosome as del (X)(q13) in a patient with some features of Turner's syndrome and suspected from cytologic studies to have a 46,XXq^- karyotype. Two dimensional scanning densitometry of autoradiograms of the Southern blots was used to quantitate hybridization of the ³²P-labeled probes, reinforcing visual analysis and permitting distinction between sequences present at one or two copies per diploid genome. Once thus characterized, DNA from the patient's cells was used in quantitatively analyzed Southern blots to refine the location of an additional DNA segment, previously mapped to somewhere in the proximal part of the long arm of the X chromosome, to the juxtacentromeric region of Xq, which has been hypothesized to be critical for X-inactivation. Cloned DNA probes such as that localized to the juxtacentromeric region of Xq should be useful for evaluating this hypothesis.     

Identification and isolation of transcribed human X chromosome DNA sequences

A human X chromosome specific phage library has been used as a source of X-specific genomic DNA clones which hybridize with cellular RNA. Random cDNA clones were mapped for X chromosome sequence localization and 8 were identified as hybridizing to X chromosome Hind III fragments. All eight also hybridized with autosomal Hind III fragments. The X chromosome genomic sequences corresponding to two of these cDNA clones were isolated from a phage library constructed with the Hind III endonuclease digest products of X enriched DNA. One genomic DNA segment, localized to the short area of the X, shared sequence homology with at least one region of the human Y chromosome. The methodology developed represents a rapid means to obtain a specific genomic DNA clone from a single chromosome when multiple different genomic loci homologous to an expressed DNA sequence exist.     

Cloning of DNA from double minutes of Y1 mouse adrenocortical tumor cells: Evidence for gene amplification

We have isolated a metaphase chromosome fraction highly enriched in double minutes (dm) from a mouse adrenocortical tumor cell line (Y1-DM). We have cloned DNA from this dm-enriched fraction in the λ vector Charon 4A, and have characterized two randomly chosen recombinant bacteriophage clones from this dm DNA library. When ³²P-labeled DNA from each recombinant was hybridized to Southern blots of restriction endonuclease-digested DNA from different mouse cell lines, large differences were seen in the intensity of the resulting autoradiographic images, depending on the source of the genomic DNA. A very strong signal was obtained with DNA from the Y1-DM cells and with DNA from a related Y1 subline that lacks dm but contains a marker chromosome bearing a large homogeneously staining region (HSR). Hybridization to DNA from parental inbred mice and from two unrelated mouse cell lines produced a significantly weaker signal than that obtained with DNA from the Y1 cells, but the DNA fragments from these sources were of similar size. Based on results from filter hybridization analysis, we estimate that sequences homologous to the cloned fragments are approximately 100- to 200-fold more abundant in the genome of the Y1-DM cells than in the parental mouse cells. The data are consistent with the hypothesis that dm and HSRs in these cells contain amplified genes.     

Construction and analysis of an EMBL-3 phage library containing partially digested human chromosome 21-specific DNA inserts (15-20 kb)

In the mouse-human hybrid cell line SCC 16-5, chromosome 21 is the only human chromosome present. Fractions highly enriched for this chromosome were obtained by applying the chromosome velocity sedimentation technique to this cell line. DNA prepared from these chromosomal fractions was partially digested with Mbo I, size fractionated on an NaCl gradient, and cloned in the EMBL-3 phage vector. The phage library thus prepared was highly enriched for human chromosome 21-specific recombinant DNA sequences 15-20 kb long. Of the approximately 21,000 phage clones obtained, at least 99% were recombinant. Following phage plaque filter hybridization and Southern blotting, it was found that half of the recombinants were positive for human repetitive DNA. Almost all phages harbored highly or middle repetitive human or mouse DNA sequences owing to the large size of the recombinant inserts. In this library, the human chromosome 21 is represented approximately four times. All human recombinants studied thus far contained DNA inserts originating from chromosome 21 only. The employed cloning strategy is discussed with regard to utility, purity, quality, and completeness of chromosome-specific recombinant DNA libraries.     

Construction and characterization of a DNA library from mouse chromosomes 19 purified by flow cytometry

In spite of the constant development concerning physical mapping of eukaryotic genomes, the mouse chromosome 19 remains poorly characterized. In order to improve the possibilities for studying this chromosome, we have constructed a chromosome-specific EcoRI DNA fragment library from mouse chromosomes 19 sorted by flow cytometry. The resulting library contains about 3 X 10(4) recombinant clones. The identified inserts range in size from about 0.2-10 kb, with a 4 kb average size and with no observable redundancy. The purity of the library has been analyzed by flow-blot. For that purpose, chromosomes from 2 cell lines, 1 with a normal karyotype and 1 with translocated chromosome 19, were sorted on nylon filters and hybridized with 9 clones of the library. Results show that 5 clones out of the 9 clearly originate from sorted chromosomes 19 and 3 and are likely to be derived from its DNA, thus indicating that the library of chromosome 19 is of high purity.     

Human pregnancy-specific beta 1 glycoprotein is encoded by multiple genes localized on two chromosomes.

A human genomic library was screened with a mixture of two cDNA probes, with one covering the 5' coding sequence and the other containing the 3'-end portion of human pregnancy-specific beta 1 glycoprotein (SP1). Seventeen clones were identified, all of which carried insert fragments capable of hybridizing with the cDNA probe. Insert size of these clones varied from 15.0 to 19.8 kb. Partial restriction maps were constructed, which demonstrated the presence of at least seven groups of unique SP1 genomic clones and suggested the possibility of multiple genes coding for SP1. The multigene nature of SP1 was confirmed by hybridization of the SP1 cDNA probe to multiple bands on Southern blots of human genomic DNA. Further analysis with chromosomal DNA dot blot demonstrated the presence of homologous sequences on the X chromosome and autosomal chromosome 6. Thus, human SP1 is apparently coded for by more than one gene residing on the X and 6 chromosomes.     

Molecular characterization of the purity of seven human chromosome-specific DNA libraries

We have characterized at the molecular level seven chromosome-specific libraries constructed in phage lambda Charon 21A from flow-sorted human chromosomes. The purity of libraries prepared from chromosomes sorted from hamster X human cells was estimated by species-specific hybridization and ranged from 48% to 83% of clones containing human inserts. Among libraries of chromosomes from human cells, mass screenings were made for repetitive sequences and 20 clones from the #18 and #20 libraries were analyzed in detail. Ten to fifteen percent of all clones contain sequences which can be mapped; 80-100% of these derive from the intended chromosome of origin, demonstrating very high purity and a 35 X enrichment of chromosome-specific sequences over a total genomic library. The two libraries contain a high, though dissimilar, percent of repeat-containing clones; the #18 library has 55% repetitive clones and the #20 library 85%. This dissimilarity may be due to a difference in insert size distribution, since the #18 library has smaller inserts than the #20. This could be caused by variation in extent of digestion of insert DNA and/or differences in sequence organization between the two chromosomes. A method more sensitive than conventional plaque-lift screening was used to detect repetitive inserts; in this way nearly all repetitive clones could be eliminated before purification of their DNAs.     

Microdissection and Microcloning of Chromosome 5 in Gossypium arboreum

Construction of single chromosomal DNA libraries by chromosome micromanipulation is a useful tool for pursuing genomic studies. Thus far, micromanipulation in cotton has not been reported yet, which may be due to difficulty in preparing chromosomes of similar sizes. In this study, single chromosome micromanipulation was successfully achieved in cotton. A single chromosome 5 of Gossypium arboreum (cultivar Shixiya-1) carrying a large satellite at mitotic metaphase was isolated by microdissection using the Cell Cut Plus Laser micromanipulation system. The chromosomal DNA was digested by Sau 3A and ligated to Sau 3A linker adaptors. After two rounds of linker adaptor PCR (LA-PCR) amplification, DNA fragments ranging from 300 to 2,500?bp were acquired. Southern hybridization revealed that the PCR products had homology with genomic DNA of the cultivar Shixiya-1, indicating that DNA of chromosome 5 has been successfully amplified. The second round LA-PCR products and 45S rDNA and chromosome-specific BAC clones were used as probes for fluorescence in situ hybridization analysis on metaphase chromosome. The results confirmed that the LA-PCR products were derived from the isolated target chromosome. Hybridization signals of the second round LA-PCR products were mainly detected along the entire chromosome 5; in addition, weak signals were also observed on other chromosomes, indicating that there were some homologous nucleotide sequences in other chromosomes. The second round LA-PCR products were cloned to generate a chromosome-specific DNA library which contains approximately 173,000 clones. Evaluation based on 136 randomly selected clones showed that the size of the inserts varied from 500 to 1,800?bp with an average of 750?bp. The no-load rate was less than 1?%, the titer of the library was 1.2?×?10⁶ pfu mL^?1, and the rate of the single and low copy sequences was over 47?%. This library will facilitate specific probe screening, molecular mapping, gene cloning, and DNA sequencing for this chromosome.     

Assignment of the functional gene for human adrenodoxin to chromosome 11q13----qter and of adrenodoxin pseudogenes to chromosome 20cen----q13.1.

Adrenodoxin is a small iron/sulfur protein serving as an electron-transport intermediate for all mitochondrial forms of cytochrome P450. Southern blots of normal genomic DNA cleaved with six restriction endonucleases probed with full-length human adrenodoxin cDNA revealed complex patterns indicating the presence of multiple adrenodoxin genes. Southern blots of DNA from a panel of mouse/human somatic cell hybrids identified cross-hybridizing adrenodoxin DNA in two loci, chromosome 11q13----qter and chromosome 20cen----q13.1. Examination of adrenodoxin clones from a genomic DNA library in phage lambda revealed some clones bearing gene fragments interrupted by introns and other clones bearing processed pseudogenes. By probing the mouse/human hybrids with unique intronic DNA and by correlating restriction maps of the phage clones with that of uncloned genomic DNA, we show that the authentic transcribed adrenodoxin gene lies on chromosome 11, while pseudogenes lie on chromosome 20.