Regional localization on the human X of DNA segments cloned from flow sorted chromosomes.

Fluorescence activated sorting of chromosomes from 49,XXXXY human lymphoblasts has been used to obtain DNA enriched for the human X. This DNA was cloned in lambda phage Charon 21A to obtain a library of approximately 60,000 pfu. Phage inserts free of human highly repeated DNA sequences are localized to different regions of the human X by two independent hybridization analyses. The first utilized comparative hybridization to rodent-human hybrid cell DNA samples containing all or known portions of the human X, while the second was based on hybridization dosage to DNA samples from human cell lines differing in the number of X chromosomes or X chromosome segments. Of five unique sequence inserts tested, three were X chromosome specific and were localized to regions Xpter leads to Xcen, Xql leads to Xq22 and Xq24 leads to Xqter, respectively. The library presented here represents a highly enriched source of human X chromosome-specific DNA sequences.     

Moderately repeated DNA sequences specific for the short arm of the human Y chromosome are present in XX males and reduced in copy number in an XY female.

Four DNA sequences specific for the Y chromosome were isolated from a recombinant phage library constructed from flow sorted human Y chromosomes. Two of these sequences were moderately repeated and assigned to the short arm of the Y chromosome by in situ hybridization. Both sequences were detected in five out of six [corrected] 46,XX males and were reduced in copy number in one out of two 46,XY gonadal dysgenesis patients tested. The findings suggest close proximity of these Y-specific moderately repeated DNA sequences to a testis determining locus.     

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 genomic sequences from the human Y chromosome after purification by dual beam flow sorting

Summary Human Y chromosomes were purified by dual beam flow sorting from a human x Chinese hamster cell line retaining the Y as the only free human chromosome. DNA was extracted from the Y fraction and cloned into gtWES.B vector arms. More than 100 recombinant clones carrying human inserts have been characterised by Benton-Davis plaque screening and Southern blotting or in situ hybridisation. Several repetitive sequences were found to be predominantly located on the Y, whereas the majority also cross-hybridised with autosomal DNA. One repetitive clone gave a specific hybridisation signal with the X and the Y chromosome but not with autosomes. Preliminary evidence indicates that many clones contain single copy as well as repetitive sequences. However, no Y-specific single copy sequence has yet been identified.     

Y chromosomal DNA of Drosophila hydei

Six recombinant DNA clones are described, which are derived from the Y chromosome of Drosophila hydei. They reveal characteristic features of Y chromosomal DNA sequences. Three of the cloned inserts are Y-specific and are members of the same family of repeated sequences associated with the lampbrush loop-forming fertility gene "nooses" in the short arm of the Y chromosome. The other three cloned sequences are members of three different families of repeated sequences, but display a small amount of homology to one another and to the family of the nooses sequences. These three cloned sequences are found preferentially in the Y chromosome, but also in other chromosomal positions. The Y chromosomal copies are located in the short arm of the Y chromosome. The other copies are found in autosomal kinetochore-associated heterochromatin or, for one of the cloned sequences, in one band of the giant chromosome 4, in addition to the kinetochore heterochromatin.     

Construction of a human X-chromosome-enriched phage library which facilitates analysis of specific loci

A human X-chromosome-enriched MboI-partial-digest recombinant library in phage lambda Charon30 has been constructed. Twelve out of the thirteen X-chromosome DNA sequences that were tested were present in the library. Most regions were covered in overlapping phage inserts; mean insert size was 13.7 kb. One phage from the library allowed detection of a 225-bp insertion of DNA into a region near the Duchenne muscular dystrophy (DMD) locus. Another recombinant phage represents an expansion of a region which exhibits extensive and varying homology with other human chromosomes, including the Y, as well as with rodent DNA. The present library should have widespread use for examining DNA sequences on the human X chromosome.     

Isolation of mouse x-chromosome specific DNA from an x-enriched lambda phage library derived from flow sorted chromosomes

A lambda phage library enriched in X(7) chromosomal material has been constructed from flow sorted chromosomes isolated from mice carrying the Cattanach translocation T(X;7)1Ct. The flow sorted fraction that was cloned contained 40% X(7) chromosomes, so that the resulting lambda phage library should be more than 10-fold enriched for X chromosomal DNA. Approximately 100,000 lambda phage clones were obtained; of these, at least 80% were recombinant. Three quarters of recombinants were positive for mouse repetitive DNA as detected either by phage plaque filter hybridization or by Southern blotting. Recombinant DNA inserts were prepared from some of the remaining nonrepetitive phage fraction. The X-chromosome specificity of cloned DNA inserts was tested by hybridization to DNA from mouse-hamster somatic cell hybrids that had retained all or most of the mouse X as the only mouse chromosome and by comparison of the extent of hybridization to DNA from male and female mice. Out of nine cloned unique sequence segments successfully examined thus far, two were presumably derived from the X. Possession of phage library highly enriched for mouse X DNA should facilitate molecular studies of the control of X chromosome gene expression.     

Deletion mapping of the testis determining locus with DNA probes in 46,XX males and in 46,XY and 46,X,dic(Y) females.

Eleven Y-specific DNA probes hybridizing with DNA from one or more 46,XX males were isolated from a recombinant phage DNA library constructed from flow sorted human Y chromosomes. Two probes hybridized with DNA from nine out of eleven, i.e. greater than 80% of these 46,XX males. The relative frequency of hybridization of the probes in the 46,XX males and in a 46,X,dic(Y) female, together with in situ hybridization data, allowed mapping of the probes on Yp in relation to a putative testis determining locus. Several of those probes were also absent in a 46,XY female, further refining a model for ordering the probes on Yp. The DNA of one XX male hybridized both with probes from Yp and probes from proximal Yq (excluding the pericentral region). This suggests that complex translocations may occur into the DNA of 46,XX males that involve not only parts of Yp but also parts of Yq.     

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.     

Three cases of 45,X/46,XYnf mosaicism

Summary Three patients with 45,X/46,XYnf mosaicism were investigated by Southern hybridization using both X- and Y-specific DNa probes. Our patients seem to be hemizygous for the X chromosomal loci tested. Single-copy and low-copy repeated Y chromosomal sequences assigned to the short arm, centromere, and euchromatin of the long arm have been detected in our patients, suggesting the Y chromosomal origin of the marker chromosome both in male and female cases studied. Densitometry of autoradiographs revealed a double dose of Yp-specific fragments of the DXYS1 locus. None of the patients tested showed either the 3.4- or the 2.1-kb Hae III malespecific repeated DNa sequences. It seems likely that the Ynf is a pseudodicentric chromosome with duplication of Yp and euchromatic Yq sequences, the Yq heterochromatin being lost. Our findings indicate structural heterogeneity of the marker chromosome and in addition provide further information on the relative position of DNa sequences detectected by DNA probes 50f2, M1A, and pDP105.     

Organization and chromosomal specificity of autosomal homologs of human Y chromosome repeated DNA

The human Y chromosome contains a group of repeated DNA elements, identified as 3.4-kilobase pair (kb) fragments in Hae III digests of male genomic DNA, which contain both Y-specific and non-Y-specific sequences. We have used these 3.4-kb Hae III Y fragments to explore the organizational properties and chromosomal distribution of the autosomal homologs of the non-Y-specific (NYS) 3.4-kb Hae III Y elements. Three distinct organizations, termed domains, have been identified and shown to have major concentrations on separate chromosomes. We have established that domain K is located on chromosome 15 and domain D on chromosome 16 and suggested that domain R is on chromosome 1. Our findings suggest that each domain is composed of a tandemly arrayed cluster of a regularly repeating unit containing two sets of repeated sequences: one that is homologous to the NYS 3.4-kb Hae III Y sequences and one that does not cross-react with the 3.4-kb Hae III Y repeats. Thus, these autosomal repeated DNA domains, like their Y chromosome counterparts, consist of a complex mixture of repeated DNA elements interspersed among each other in ways that lead to defined periodicities. Although each of the three identified autosomal domains cross-reacts with 3.4-kb Hae III Y fragments purified from genomic DNA, the length periodicities and sequence content of the autosomal domains are chromosome specific. The organizational properties and chromosomal distribution of these NYS 3.4-kb Hae III homologs seem inconsistent with stochastic mechanisms of sequence diffusion between chromosomes.     

Isolation and characterization of two repetitive DNA fragments located near the centromere of the mouse X chromosome

Two repetitive DNA fragments located on the mouse X chromosome are described. The fragments were isolated from a lambda phage library enriched in X-chromosomal sequences by flow sorting. Both fragments, which are repeated 20 to 50 times in the genome, were mapped to the mouse X chromosome by Southern blot hybridization to DNA from hybrid cells retaining the mouse X chromosome, by dosage analysis, and by in situ hybridization to mouse chromosomes. In mouse strain C57BL/10BK, one fragment appeared to be located only on the X chromosome, while the other fragment had homologous sequences on chromosome 11 in addition to the X chromosome. The latter fragment showed DNA variants between mouse strains, which are potentially useful for mapping. Both fragments cross-hybridized to another mouse species: Mus caroli. In this species, each fragment appeared to be located on the X chromosome, indicating that some X-chromosome repetitive sequences are partially conserved. In addition, one fragment cross-hybridized to human DNA.     

Molecular cloning and mapping of 10 new probes on the human Y chromosome

We have developed a novel positive cloning vector whose use precludes the cloning of any fragments less than 0.8 kb as well as 3.4-kb EcoRI fragments of DYZ1, the largest repeating-DNA family on the long arm of the human Y chromosome. Using this vector, we subcloned inserts of a Y-chromosome-specific phage library constructed from EcoRI-digested flow-sorted Y-chromosome DNA. Ten novel Y-specific fragments were obtained. Their localization on the Y chromosome was determined by deletion mapping using clinical samples with structurally abnormal Y chromosomes. The long arm of the Y chromosome was divided into 12 segments by the novel probes in combination with established probes. The amelogenin-like sequence, mapped on the long arm in Human Gene Mapping 10, has been mapped on the short arm.     

Evolution of four human Y chromosomal unique sequences

Four cloned unique sequences from the human Y chromosome, two of which are found only on the Y chromosome and two of which are on both the X and Y chromosomes, were hybridized to restriction enzyme-treated DNA samples of a male and a female chimpanzee (Pan troglodytes), gorilla (Gorilla gorilla), and pig-tailed macaque (Macaca nemestrina); and a male orangutan (Pongo pygmaeus) and gibbon (Hylobates lar). One of the human Y-specific probes hybridized only to male DNA among the humans and great apes, and thus its Y linkage and sequence similarities are conserved. The other human Y-specific clone hybridized to male and female DNA from the humans, great apes, and gibbon, indicating its presence on the X chromosome or autosomes. Two human sequences present on both the X and Y chromosomes also demonstrated conservation as indicated by hybridization to genomic DNAs of distantly related species and by partial conservation of restriction enzyme sites. Although conservation of Y linkage can only be demonstrated for one of these four sequences, these results suggest that Y-chromosomal unique sequence genes do not diverge markedly more rapidly than unique sequences located on other chromosomes. However, this sequence conservation may in part be due to evolution while part of other chromosomes.     

A 45,X male with a Yp/18 translocation

Summary A patient described as a 45,X male (Forabosco et al. 1977) was examined for the presence of Y-specific DNA by using various probes detecting restriction fragments from different regions of the Y chromosome. Positive hybridization signals were obtained for Yp fragments only. In situ hybridization with two different probes, pDP31 and the pseudoautosomal probe 113F, led to a clear assignment of the Yp sequences to the short arm of one chromosome 18. Cytogenetically, the presence of all of Yp including the Y centromere on 18p could be demonstrated replacing a segment of similar size of 18p. Thus, the Y/18 translocation chromosome is dicentric structurally, but it was shown to be monocentric functionally with the no. 18 centromere active. Gene dosage studies with the probe B74 defining a sequence at 18p11.3 demonstrated a single dose of this sequence in the patient. In agreement with these observations, the patient shows clinical signs of the 18p-syndrome. It is concluded that in XO males in general, the X is of maternal origin while the maleness is due to a de novo Y/autosome translocation derived from the father. Depending on the nature of the autosomal deficiency caused by the Y/autosome translocation, the patient may have congenital malformations.     

Evolution of human cytoplasmic actin gene sequences: chromosome mapping and structural characterizations of three cytoplasmic actin-like pseudogenes including one on the Y chromosome

Eight recombinant phage clones containing cytoplasmic actin-like gene sequences have been isolated from a human genomic library for structural characterization. Kpn I family repeat sequences flank six of these actin genes isolated, and Alu family repeats are scattered throughout the DNA inserts of all eight phage clones. Three of these genes are γ actin-like, and the other five are β actin-like. The complete nucleotide sequence analysis of one β and one γ actin-like genes and their flanking regions demonstrates that they both are processed pseudogenes. Using unique DNA sequences flanking these two pseudogenes as hybridization probes for human-mouse somatic cell hybrid DNAs, we have mapped the two actin pseudogenes on human chromosomes 8 and 3, respectively. We have also determined the DNA sequence of a human Y chromosome-linked, processed actin pseudogene. The different values of sequence divergence of these processed pseudogenes and their functional counterparts allow us to estimate the time of generation of the pseudogenes. The results suggest that the cDNA insertion events generating the human cytoplasmic actin-like pseudogenes have occurred at significantly different times during the evolution of primates, after their separation from other mammalian species.     

Rapid methods to visualize Y-specific repeated DNA sequences in cytological preparations

We described rapid methods to detect Y-specific repeated DNA sequences in cytological preparations using in situ hybridization. A human Y chromosome specific DNA probe with an insert equivalent to that in pHY2.1 was labelled with [alpha-32P]dCTP or photobiotin, and hybridized to chromosome preparations. Signals were visualized specifically on Y chromosomes after 1 day's autoradiography or a couple of hours treatment with streptavidin alkaline phosphatase/BCIP/NBT. These methods are useful for molecular confirmation of Y-autosomal translocations.     

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.     

Isolation, characterization, and physical localization of 33 human X-chromosome RFLP markers

In a search for highly polymorphic X-specific loci, the X-chromosome DOE Ch35 phage library (LAOXNL01) was screened with three oligonucleotides representative of minisatellite consensus sequences. A total of 170 clones containing human inserts were isolated by hybridization to the oligonucleotide sequences; each was tested for polymorphism on five random female DNAs with six restriction enzymes. Among the 53 clones demonstrating a polymorphic pattern, 47 were of distinct origin. Twelve of the polymorphisms (23%) were determined to be autosomal. Polymorphisms for the remaining 35 clones were characterized, These polymorphisms represent 33 new X-chromosome RFLP loci, since two pairs of clones detected partially overlapping patterns. A pattern of similar length variation with multiple enzymes ("VNTR-type") was demonstrated in 6 (50%) of the 12 non-X-polymorphic clones. However, only 3 (9%) of the 33 X polymorphic loci showed VNTR-like patterns, suggesting a decreased amount of VNTR polymorphism on the X chromosome. The 33 polymorphic X loci were physically localized with a set of rodent x human somatic cell hybrid DNAs representing nine different X-chromosome breakpoints.