High-resolution fluorescence in situ hybridization of RBM- and TSPY-related cosmids on released Y chromatin in humans and pygmy chimpanzees

Evolutionary breakpoint analysis on Y chromosomes of higher primates provides insight into human Y evolution

Comparative FISH mapping of PAC clones covering almost 3 Mb of the human AZFa region in Yq11.21 to metaphases of human and great apes unravels breakpoints that were involved in species-specific Y chromosome evolution. An astonishing clustering of evolutionary breakpoints was detected in the very proximal region on the long arm of the human Y chromosome in Yq11.21. These breakpoints were involved in deletions, one specific for the human and another for the orang-utan Y chromosome, in a duplicative translocation/transposition specific for bonobo and chimpanzee Y chromosomes and in a pericentric inversion specific for the gorilla Y chromosome. In addition, our comparative results allow the deduction of a model for the human Y chromosome evolution.

A fiber-FISH contig spanning the non-recombining region of the human Y chromosome

Using fluorescence in-situ hybridization on interphase chromatin fibers (fiber-FISH), we have constructed an overlapping fiber-FISH contig spanning the non-recombining region of the human Y chromosome (NRY). We first established a standard FISH-signal pattern for a distinct panel of DNA clones on prometaphase Y chromosomes in six healthy fertile men. Clones in the panel were selected from all R-bands as well as deletion intervals 1 through 7 plus PAR1 and PAR2 of the human Y chromosome. We next used signals of these marker clones to build a fiber-FISH contig for the multicopy gene families, CDY, DAZ, RBMY, TSPY and XKRY, along the NRY. Our fiber-FISH contig of human NRY may help to close the four gaps that still exist in the current physical map of the human Y chromosome. Furthermore, it provides a more complete picture with respect to the positions and arrangements of the multicopy gene families along the human NRY.

A review of fluorescence in situ hybridization (FISH): current status and future prospects

Fluorescence in situ hybridization (FISH) is a powerful technique for detecting DNA or RNA sequences in cells, tissues and tumors. This molecular cytogenetic technique enables the localization of specific DNA sequences within interphase chromatin and metaphase chromosomes and the identification of both structural and numerical chromosome changes. FISH is quickly becoming one of the most extensively used cytochemical staining techniques owing to its sensitivity and versatility, and with the improvement of current technology and cost effectiveness, its use will surely continue to expand. Here we review the wide variety of current applications and future prospects of FISH technology.

A long-range restriction map of deletion interval 6 of the human Y chromosome: a region frequently deleted in azoospermic males

Deletion interval 6 (DI6) of the human Y chromosome, located at the distal end of the long arm euchromatic region, is required for normal spermatogenesis. About 10% of males with idiopathic azoospermia or oligospermia have microdeletions in this region. Six gene families, including RBMY (RNA binding motif, Y chromosome), DAZ (deleted in azoospermia), and four recently isolated genes, have been mapped to this interval. Genes from all of these families show testis-specific expression and are thus candidates for azoospermic factor (AZF). DI6 is also rich in Y-specific repetitive sequences, which may be responsible for its frequent deletion. To understand the sequence organization of this region, a 5-Mb restriction map was constructed based on YAC clones and was partially verified on genomic DNA. The locations of five gene family members, as well as numerous STSs, were determined. The map shows several inverted and direct repeats several hundred kilobases in size. The restriction map of DI6 will facilitate future mapping of deletion breakpoints in infertile males and elucidation of mechanisms behind frequent deletions.

High resolution free chromatin/DNA fiber fluorescent in situ hybridization

High resolution chromatin/DNA fiber fluorescent in situ hybridisation (FISH) is a powerful system for physical mapping and genome research. With direct visualisation of molecular probes along released chromatin or DNA fiber, fiber FISH has become the method of choice to order genes or DNA markers within chromosomal regions of interest. Combined with DNA-protein in situ codetection fiber FISH shall play a more important role for analysis of genome function. In this paper the concept and technical developments of fiber FISH are reviewed with the emphasis of comparison on the various protocols. Future challenges are also discussed along with the highlights of the successful applications achieved by fiber FISH methodology.

Structure and organization of the RBMY genes on the human Y chromosome: transposition and amplification of an ancestral autosomal hnRNPG gene

The RBMY (RNA-binding motif, Y chromosome) gene family encodes a germ-cell-specific nuclear protein implicated in spermatogenesis. It consists of approximately 30 genes and pseudogenes, found on both arms of the Y chromosome. RBMY shares high homology with an autosomal hnRNPG gene that contains an RNA-binding motif and one of the four SRGY repeats found in RBMY. One proposal is that RBMY represents an ancestral hnRNPG gene, transposed to the Y chromosome and then amplified. We characterized seven RBMY genes in interval 6 of the Y chromosome long arm. Four have the normal structure with 12 exons spanning 15 kb, whereas one lacks the first 3 exons, therefore representing a pseudogene. The remaining two genes belong to a different subfamily, resembling the autosomal hnRNPG gene with only one SRGY repeat. We also found that most RBMY genes in interval 6 are arranged in tandem. The structure and organization of the Y-linked RBMY genes support the transposition-amplification hypothesis.

Simian Y chromosomes: species-specific rearrangements of DAZ, RBM, and TSPY versus contiguity of PAR and SRY

The three human male specific expressed gene families DAZ, RBM, and TSPY are known to be repetitively clustered in the Y-specific region of the human Y Chromosome (Chr). RBM and TSPY are Y-specifically conserved in simians, whereas DAZ cannot be detected on the Y chromosomes of New World monkeys. The proximity of SRY to the pseudoautosomal region (PAR) is highly conserved and thus most effectively stabilizes the pseudoautosomal boundary on the Y (PABY) in simians. In contrast, the non-recombining part of the Y Chrs, including DAZ, RBM, and TSPY, was exposed to species-specific amplifications, diversifications, and rearrangements. Evolutionary fast fixation of any of these variations was possible as long as they did not interfere with male fertility.

Multiple functional copies of the RBM gene family, a spermatogenesis candidate on the human Y chromosome

The RBM (RNA-binding motif) gene family on the human Y chromosome encodes proteins with an RNA-binding domain. Its exclusive expression in germ cells and its partial deletion in some azoospermic or severely oligospermic males provide evidence of a role for RBM genes in spermatogenesis. There are approximately 30 RBM genes, found on both arms of the Y chromosome. Two RBM cDNA clones with slightly different sequences have been reported. To investigate the number of functional genes, we studied RBM expression by use of RT-PCR of RBM transcripts and by characterizing numerous RBM cDNA clones. A total of 27 RT-PCR and 19 cDNA clones were sequenced. Whereas the RT-PCR clones pointed to the existence of at least six RBM subfamilies (RBMI to RBMVI), the cDNA clones indicated that only RBMI is actively transcribed and encodes functional proteins. A total of six RBMI genes were identified, which produce four polypeptides due to some silent base substitutions. The transcripts of each gene are alternatively spliced to generate protein isoforms with three or four SRGY boxes, thus greatly increasing the complexity of the products of the RBM gene family. We also provide evidence suggesting that a 5-bp deletion in a previously reported RBM cDNA clone represents a processing irregularity.

High-resolution fluorescence in situ hybridization of human Y-linked genes on released chromatin

Genes within the differential region of the human Y chromosome do not recombine, and therefore the determination of their location depends on physical mapping. Yeast artificial chromosome (YAC) contigs spanning the euchromatic region of the human Y have become a powerful tool for the generation of an overlapping clone map. With this approach, however, complete physical mapping is difficult in Y euchromatic regions that are rich in repetitive sequences. We have, therefore, made use of the fluorescence in situ hybridization technique as an alternative strategy for physically mapping the PRKY and AMELY genes as well as the TSPY, RBM and DAZ gene families to human Y chromosomes in prometaphase and to extended Y chromatin in interphase. From our results, the following order of gene sequences in interval 3 of the short arm of the human Y chromosome is suggested: TSPY major with few RBM sequences interspersed-PRKY-AMELY-TSPY minor with few RBM sequences interspersed-cen. On the long arm, RBM sequences appear to be distributed over wide regions of intervals 5 and 6 with few TSPY sequences interspersed. Distal to an RBM signal cluster, a large cluster of DAZ signals is located with only a few DAZ and RBM signals overlapping in between the two clusters.