Organizational variation of DYZ1 repeat sequences on the human Y chromosome and its diagnostic potentials

The long arm of the human Y chromosome is flecked with various fractions of repetitive DNA. DYZ1 is one such fraction, which is organized tandemly as an array of a 3.4-kb repeat ranging from 2000-4000 copies in normal males. We have studied the organizational variation of the DYZ1 fraction on the human Y chromosome using DNA samples from CEPH family members and the random population employing the RFLP approach, fluorescence in situ hybridization (FISH), and conducted a similarity search with GenBank sequences. Typing of genomic DNA using DYZ1 as a probe showed an allele length and copy number variations even between two male siblings. Hybridization of DNA from monochromosome hybrids with this probe showed its presence on chromosome 15 in addition to the Y chromosome. Fluorescence in situ hybridization of metaphase chromosomes from an apparently normal male showed DYZ1 sequences in the proximal region of chromosome 11 in addition to the long arm of the Y chromosome. Typing of sets of semen and blood DNA samples from the same human individuals showed discernible allelic variation between the two samples, indicating tissue-specific programmed sequence modulation. DYZ1 seems to be the first probe having the unique potential to discriminate unequivocally the difference between the DNA originating from semen and blood samples, and may be exploited in forensic cases. This probe may also be used as a diagnostic tool to ascertain Y chromosome mosaicism in patients (e.g., Turner), its aberrant status in somatic cells, and possible sequence modulation/rearrangement in the germline samples. Additionally, this can be used to uncover sequence polymorphism in the human population.     

AZFc somatic microdeletions and copy number polymorphism of the DAZ genes in human males exposed to natural background radiation

Ionizing radiations are known to induce tumors, chromosomal lesions and minisatellite length variations, yet no correlation has been demonstrated between radiation exposure and indels or copy number polymorphism (CNP) of the genes. We studied the impact of natural background radiation (NBR) on the human Y chromosome owing to its haploid status and clonal inheritance. We analyzed the AZFc region using the DNA from blood and semen of 100 males living near the coastal peninsula in Kerala (India), exposed to NBR along with other 50 normal fertile males. STS mapping of AZFc region showed random microdeletions without conclusive gr/gr or b1/b3 phenotypes. Using a highly specific novel Taqman assay based on sY587 sequence, we detected four copies of the DAZ genes in normal males and 4–16 in those exposed to NBR. Amongst NBR exposed males with multiples copies of the DAZ genes, 75% showed varying FISH signals for DAZ genes with cosmid 18E8 whereas 30% showed mosaicism in terms of presence/absence of the signals in 6–8% cells and unexpected number of signals in 9–12% interphase nuclei. Startlingly, all germline samples studied were found to be free from AZFc microdeletions and CNP of the DAZ genes. Since the DAZ genes are heavily implicated with the germ cell development, the cells with DAZ deletion/duplication are unlikely to survive. Alternatively, an innate mechanism may be operative to protect the germline from the effects of NBR.     

Novel mutations in the 3' region of the polycystic kidney disease 1 (PKD1) gene

Mutation screening in 90 unrelated ADPKD1 patients was carried out on some of the exons in the single copy area (37, 38, 39, 44, 45) using genomic PCR and SSCP. Four novel mutations were found: a 15 bp in-frame deletion in exon 39 [nt11449 (del 15)], a 2 bp deletion in exon 44 [nt12252 (del 2)], a G insertion in exon 44 [nt12290 (Ins G)], and a GTT in-frame deletion in exon 45 [nt12601 (del 3)].     

Fetal nucleated cells in maternal peripheral blood: frequency and relationship to gestational age

To determine the frequency of fetal nucleated cells in maternal peripheral blood during different stages of pregnancy, 50 primigravidas were investigated by determining the frequency of cells with the Y chromosome using fluorescence in situ hybridization (FISH) of Y-specific repetitive sequences of the DYZ1 family. Polymerase chain reaction (PCR) amplifying the same part of the DYZ1 used as the probe in FISH and a single-copy Y-specific fragment was also carried out for genomic DNA from the same samples. Cells with the hybridization signal were detected by FISH at and after 15 weeks of pregnancy in all pregnant women who gave birth to boys. The ratio of cells with the signal to those without the signal ranged from 1 in 144,000 to 1 in 4,000 with a tendency to increase as the pregnancy advanced. The frequency of fetal cells estimated by the PCR experiments was significantly and positively correlated with that found by FISH. The present study suggests that fetal nucleated cells increase in maternal peripheral blood with advancing gestation, from less than 1 in 100,000 nucleated cells in the first trimester to around 1 in 10,000 at term. These frequencies were much lower than those reported by cytological methods.     

Genomic heterogeneity and instability in colorectal cancer: spectral karyotyping, glutathione transferase-Ml and ras

Genomic instability in cancer is frequently described as being either chromosomal instability or microsatellite instability, although when events within chromosomes are monitored, extensive intrachromosomal instability is also found. Spectral karyotyping was used to visualize how extensively genomic instability gives rise to intratumor genomic heterogeneity in sporadic colorectal carcinomas. Two factors were then examined which might relate to intrachromosomal instability in colorectal cancers: the presence of the glutathione transferase-Ml gene to detoxify potential carcinogens, and the presence of activated ras which has been associated with chromosomal instability when first expressed. Intrachromosomal genomic instability was previously determined by inter-(simple sequence repeat) PCR (inter-SSR PCR) and by fractional allelic loss rate for 348 markers. GSTM1 status was determined for each of 49 tumors through use of specific PCR, and 28 of the tumors showed the GSTM1 null genotype. A significant association was found between GSTMl-null status and elevated inter-(simple sequence repeat) PCR instability. In contrast, no association was found with fractional allelic loss rate. The first exons of the K-ras and H-ras oncogenes were sequenced in 72 colorectal cancers; 19 of the tumors had a mutation in codon 12 of the K-ras gene (24.5%), but no H-ras mutations were found. A weak correlation (p=0.10) was observed between mutant K-ras and inter-(simple sequence repeat) PCR genomic instability, and no association existed with fractional allelic loss rate.     

Structural instability of human tandemly repeated DNA sequences cloned in yeast artificial chromosome vectors.

The suitability of yeast artificial chromosome vectors (YACs) for cloning human Y chromosome tandemly repeated DNA sequences has been investigated. Clones containing DYZ3 or DYZ5 sequences were found in libraries at about the frequency anticipated on the basis of their abundance in the genome, but clones containing DYZ1 sequences were under-represented and the three clones examined contained junctions between DYZ1 and DYZ2. One DYZ3 clone was quite stable and had a long-range structure corresponding to genomic DNA. All other clones had long-range structures which either did not correspond to genomic DNA, or were too unstable to allow a simple comparison. The effects of the transformation process and host genotype on YAC structural stability were investigated. Gross structural rearrangements were often associated with re-transformation of yeast by a YAC. rad1-deficient yeast strains showed levels of instability similar to wild-type for all YAC clones tested. In rad52-deficient strains, DYZ5 containing YACs were as unstable as in the wild-type host, but DYZ1/DYZ2 or DYZ3 containing YACs were more stable. Thus the use of rad52 hosts for future library construction is recommended, but some sequences will still be unstable.     

A human Y-chromosome specific repeated DNA family (DYZ1) consists of a tandem array of pentanucleotides.

We have determined the complete nucleotide sequence of a 3564 bp EcoRI fragment which represents a major component of the human Y-chromosome specific repeated DNA family (DYZ1). Sequencing result showed a tandem array of pentanucleotides after five nucleotides were inserted or deleted at four positions. 229 out of the 713 pentanucleotides were TTCCA, and 297 were its single-base substituents. Southern hybridization analyses of male genomic DNAs showed that several endonuclease cleavage sites were located at intervals of 3.56kb in the DYZ1 locus. This indicates that the DYZ1 repeated DNA family evolved and expanded by unequal crossovers which occurred at distances of 3.56kb. As there is a uniformly distributed array of pentanucleotides on this locus, it is not a sequence homology that determines the distance of unequal crossovers. A higher order of chromatin structure may be involved in the determination of distance in unequal crossovers.     

Origin and molecular structure of a midget chromosome in a common wheat carrying rye cytoplasm

The origin and molecular structure of the midget chromosome that is retained in a common wheat with rye cytoplasm, were studied by using fluorescent in situ hybridization (FISH). FISH with biotinylated rye genomic DNA as a probe clearly showed that the midget chromosome had originated from certain part(s) of rye chromosome(s). The midget chromosome did not possess sequences similar to wheat rDNA nor to a rye telomeric sequence with a 350 bp repeat unit. However, another repetitive sequence (120 bp family) of rye was found to occur at one end of the midget chromosome. The telomeric repeat sequences from Arabidopsis thaliana cross-hybridized to both ends of the midget chromosome as well as to wheat chromosomes. From the results obtained in this and previous studies, it is assumed that the midget chromosome originated from part of a rye chromosome, most likely the centromeric region of chromosome 1R, and that the telomeric sequences were synthesized de novo.by R. Appels     

Detection of mitochondrial DNA deletion by a modified PCR method in a 60Co radiation-exposed patient

A new PCR based method was developed to detect deleted mitochondrial DNA (mtDNA). Peripheral blood cell DNA was obtained from a victim who was accidently exposed to a 60Co radiation source in 1990. Using the DNA as template, first PCR was performed to generate multiple products including true deletions and artifacts. The full length product was recovered and used as template of secondary PCR. The suspicious deletion product of mtDNA could be confirmed only if it was yielded by first PCR. Using either original primers or their nested primers, the suspicious deletion product was amplified and authenticated as a true deletion product. The template was recovered and determined to be a deletion by sequencing directly. The results show that a new mtDNA deletion, which spans 889 bp from nt 11688 to nt 12576, was detected in the peripheral blood cells of the victim. It indicates that this new PCR-based method was more efficient at detecting small populations of mtDNA deletion than other routine methods. MtDNA deletion was found in the victim, suggesting the relationship between the deletion and phenotypes of the disease.     

Evidence of abundant constitutive alkali-labile sites in human 5 bp classical satellite DNA loci by DBD-FISH

Human blood leukocytes within an agarose matrix were deproteinized and exposed to an alkaline denaturation that generates single-stranded DNA (ssDNA) starting from the ends of spontaneous basal DNA breaks and alkali-labile sites. Since the amount of ssDNA produced within a specific sequence area may be detected by hybridization with a specific probe, we quantified this in situ in different satellite DNA loci (DBD-FISH: DNA Breakage Detection FISH). The DBD-FISH signal, corrected for the respective FISH signals in metaphase, was remarkably strong in the 5bp classical satellite DNA domains analyzed (D1Z1, D9Z3, DYZ1), intermediate in the classical satellite 1 DNA sequences, and low in the alphoid satellite regions (D1Z5, DXZ1, all centromeres). This result is evidence of a high density of constitutive alkali-labile sites, probably abasic sites, within the 5bp satellite DNA sequences in human blood leukocytes. The presence and relative abundance of alkali-labile sites could explain the high frequency of spontaneous breakage and rearrangements in pericentromeric heterochromatin of chromosomes 1, 9, and 16, but not in Yqh, when this chromatin is undercondensed through spontaneous or induced demethylation, i.e. ICF syndrome or 5-azacytidine treatment.     

Mutational landscape of the human Y chromosome-linked genes and loci in patients with hypogonadism

Sex chromosome-related anomalies engender plethora of conditions leading to male infertility. Hypogonadotropic hypogonadism (HH) is a rare but well-known cause of male infertility. Present study was conducted to ascertain possible consensus on the alterations of the Y-linked genes and loci in males representing hypogonadism (H), which in turn culminate in reproductive dysfunction. A total of nineteen 46, XY males, clinically diagnosed with H (11 representative HH adults and eight prepubertal boys suspected of having HH) were included in the study. Sequence-tagged site screening, SRY gene sequencing, fluorescence in situ hybridization mapping (FISH), copy number and relative expression studies by real-time PCR were conducted to uncover the altered status of the Y chromosome in the patients. The result showed random microdeletions within the AZFa (73%)/b (78%) and c(26%) regions. Sequencing of the SRY gene showed nucleotide variations within and outside of the HMG box in four males (21%). FISH uncovered mosaicism for SRY, AMELY, DAZ genes and DYZ1 arrays, structural rearrangement for AMELY (31%) and duplication of DAZ (57%) genes. Copy number variation for seven Y-linked genes (2–8 rounds of duplication), DYZ1 arrays (495–6201copies) and differential expression of SRY, UTY and VCY in the patients’ blood were observed. Present work demonstrates the organizational vulnerability of several Y-linked genes in H males. These results are envisaged to be useful during routine diagnosis of H patients.     

Stability of an inverted repeat in a human fibrosarcoma cell.

Deletions and rearrangements of DNA sequences within the genome of human cells result in mutations associated with human disease. We have developed a selection system involving a neo gene containing a DNA sequence inserted into the NcoI site that can be used to quantitatively assay deletion of this sequence from the chromosome. The spontaneous deletion from the neo gene of a 122 bp inverted repeat occurred at a rate of 2.1 x 10(-8) to <3.1 x 10(-9) revertants/cell/generation in three different cell lines. Deletion of the 122 bp inverted repeat occurred between 6 bp flanking direct repeats. Spontaneous deletion of a 122 bp non-palindromic DNA sequence flanked by direct repeats was not observed, indicating a rate of deletion of <3.1 x 10(-9) revertants/cell/generation. This result demonstrates that a 122 bp inverted repeat can exhibit a low level of instability in some locations in the chromosome of a human cell line.     

Construction of a swine YAC library allowing an efficient recovery of unique and centromeric repeated sequences

A swine DNA genomic library was constructed in yeast artificial chromosome (YAC) using the pYAC4 vector and the AB1380 strain. The DNA prepared from two Large White males was partially digested with EcoRI and size selected after both digestion and ligation. The YAC library contained 33792 arrayed clones with an average size of 280 kb as estimated by analysis of 2% of the clones, thus representing a threefold coverage of the swine haploid genome. The library was organized in pools to facilitate the PCR screening. The complexity of the library was tested both for unique and centromeric repeated sequences. In all, 20 out of 22 primer sets allowed the characterization of one to six clones containing specific unique sequences. These sequences are known to be on Chromosomes (Chrs) 1, 2, 5, 6, 7, 8, 13, 14, 15, 17, and X. Eight additional clones carrying centromeric repeat units were also isolated with a single primer set. The sequencing of 37 distinct repeat units of about 340 bp subcloned from these eight YACs revealed high sequence diversity indicating the existence of numerous centromeric repeat unit subfamilies in swine. Furthermore, the analysis of the restriction patterns with selected enzymes suggested a higher order organization of the repeat units. According to preliminary FISH experiments on a small number of randomly chosen YACs and YACs carrying specific sequences, the chimerism appeared to be low. In addition, primed in situ labeling experiments favored the idea that the YACs with centromeric repeat sequences were derived from a subset of metacentric and submetacentric chromosomes. Received: 14 July 1996 / Accepted: 24 October 1996     

Computational analysis and refinement of sequence structure on chromosome 22q11.2 region: application to the development of quantitative real-time PCR assay for clinical diagnosis

The low-copy repeat (LCR) is a new class of repetitive DNA element and has been implicated in many human disorders, including DiGeorge/velocardiofacial syndrome (DGS/VCFS). It is now recognized that nonallelic homologous recombination (NAHR) through LCRs flanking the chromosome 22q11.2 region leads to genome rearrangements and results in the DGS/VCFS. To refine the structure and content of chromosome 22q11.2 LCRs, we applied computational analysis to dissect region-specific LCRs using publicly available sequences. Nine distinct duplicons between 1.6 and 65 kb long and sharing >95% sequence identity were identified. The presence of these sequence motifs supports the NAHR mechanism. Further sequence analysis suggested that the previously defined 3-Mb deletion may actually comprise two deletion intervals of similar size close to each other and thus indistinguishable when using fluorescence in situ hybridization (FISH) analysis. The differentially deleted regions contain several hypothetical proteins and UniGene clusters and may partially explain the clinical heterogeneity observed in DGS/VCFS patients with the 3-Mb common deletion. To implement further sequence information in molecular medicine, we designed a real-time quantitative PCR assay and validated the method in 122 patients with suspected DGS/VCFS. The assay detected 28 patients with chromosome 22q11.2 deletion later confirmed using FISH. Our results indicated that the developed assay is reliable as well as time and cost effective for clinical diagnosis of chromosome 22q11.2 deletion. They also suggest that this methodology can be applied to develop a molecular approach for clinical detection and diagnosis of other genomic disorders.     

Heterozygosity of Knob-Associated Tandem Repeats and Knob Instability in Mitotic Chromosomes of Zea （Zea mays L. and Z. diploperennis Iltis Doebley）

Knobs are blocks of heterochromatin present on chromosomes of maize （Zea mays L.） and its relatives that have effects on the frequency of genetic recombination, as well as on chromosome behavior. Knob heterozygosity and instability in six maize inbred lines and one Z. diploperennis Iltis Doebley line were investigated using the fluorescence in situ hybridization （FISH） technique with knob-associated tandem repeats （180 bp and 350 bp （TR- 1）） as probes. Signals of seven heterozygous knobs containing 180- bp repeats and of one heterozygous knob containing TR- 1 were captured in chromosomes of all materials tested according to the results of FISH, which demonstrates that the 180-bp repeat is the main contributor to knob heterozygosity compared with the TR- 1 element. In addition, one target cell with two TR- 1 signals on one homolog of chromosome 2L, which was different from the normal cells in the maize inbred line GB57, was observed, suggesting knob duplication and an instability phenomenon in the maize genome.     

Heterozygosity of Knob-Associated Tandem Repeats and Knob Instability in Mitotic Chromosomes of Zea (Zea mays L. and Z. diploperennis Iltis Doebley)

Knobs are blocks of heterochromatin present on chromosomes of maize (Zea mays L.) and its relatives that have effects on the frequency of genetic recombination, as well as on chromosome behavior.Knob heterozygosity and instability in six maize inbred lines and one Z. diploperennis Iltis Doebley line were investigated using the fluorescence in situ hybridization (FISH) technique with knob-associated tandem repeats (180 bp and 350 bp (TR-1)) as probes. Signals of seven heterozygous knobs containing 180-bp repeats and of one heterozygous knob containing TR- 1 were captured in chromosomes of all materials tested according to the results of FISH, which demonstrates that the 180-bp repeat is the main contributor to knob heterozygosity compared with the TR-1 element. In addition, one target cell with two TR-1 signals on one homolog of chromosome 2L, which was different from the normal cells in the maize inbred line GB57,was observed, suggesting knob duplication and an instability phenomenon in the maize genome.     

Genome-wide mutagenesis resulting from topoisomerase 1-processing of unrepaired ribonucleotides in DNA

Ribonucleotides are the most common non-canonical nucleotides incorporated into DNA during replication, and their processing leads to mutations and genome instability. Yeast mutation reporter systems demonstrate that 2–5 base pair deletions (Δ2–5bp) in repetitive DNA are a signature of unrepaired ribonucleotides, and that these events are initiated by topoisomerase 1 (Top1) cleavage. However, a detailed understanding of the frequency and locations of ribonucleotide-dependent mutational events across the genome has been lacking. Here we present the results of genome-wide mutational analysis of yeast strains deficient in Ribonucleotide Excision Repair (RER). We identified mutations that accumulated over thousands of generations in strains expressing either wild-type or variant replicase alleles (M644G Pol ε, L612M Pol δ, L868M Pol α) that confer increased ribonucleotide incorporation into DNA. Using a custom-designed mutation-calling pipeline called muver (for mutationes verificatae), we observe a number of surprising mutagenic features. This includes a 24-fold preferential elevation of AG and AC relative to AT dinucleotide deletions in the absence of RER, suggesting specificity for Top1-initiated deletion mutagenesis. Moreover, deletion rates in di- and trinucleotide repeat tracts increase exponentially with tract length. Consistent with biochemical and reporter gene mutational analysis, these deletions are no longer observed upon deletion of TOP1. Taken together, results from these analyses demonstrate the global impact of genomic ribonucleotide processing by Top1 on genome integrity.