Sperm typing allows accurate measurement of the recombination fraction between D3S2 and D3S3 on the short arm of human chromosome 3

Playing hide and seek with mammalian meiotic crossover hotspots

Crossovers (COs) are essential for meiosis and contribute to genome diversity by promoting the reassociation of alleles, and thus improve the efficiency of selection. COs are not randomly distributed but are found at specific regions, or CO hotspots. Recent results have revealed the historical recombination rates and the distribution of hotspots across the human genome. Surprisingly, CO hotspots are highly dynamic, as shown by differences in activity between individuals, populations and closely related species. We propose a role for DNA methylation in preventing the formation of COs, a regulation that might explain, in part, the correlation between recombination rates and GC content in mammals.

Allelic recombination and de novo deletions in sperm in the human beta-globin gene region

Meiotic recombination is of fundamental importance in creating haplotype diversity in the human genome and has the potential to cause genomic rearrangements by ectopic recombination between repeat sequences and through other changes triggered by recombination-initiating events. However, the relationship between allelic recombination and genome instability in the human germline remains unclear. We have therefore analysed recombination and DNA instability in the delta-, beta-globin gene region and its associated recombination hotspot. Sperm typing has for the first time accurately defined the hotspot and shown it to be the most active autosomal crossover hotspot yet described, although unusually inactive in non-exchange gene conversion. The hotspot just extends into a homology block shared by the delta- and beta-globin genes, within which ectopic exchanges can generate Hb Lepore deletions. We developed a physical selection method for recovering and validating extremely rare de novo deletions in human DNA and used it to characterize the dynamics of these Hb Lepore deletions in sperm as well as other deletions not arising from ectopic exchanges between homologous DNA sequences. Surprisingly, both classes of deletion showed breakpoints that avoided the beta-globin hotspot, establishing that it possesses remarkable fidelity and does not play a significant role in triggering these DNA rearrangements. This study also provides the first direct analysis of de novo deletion in the human germline and points to a possible deletion-controlling element in the beta-globin gene separate from the crossover hotspot.

Loss of heterozygosity in squamous cell carcinomas of the head and neck defines a tumor suppressor gene region on 11q13

Tumor suppressor genes APC, RB1, and DCC, as well as genes localized to 3p and 11q, have been implicated in the development of a number of human tumors. To determine whether allelic deletions occur at these loci in squamous cell carcinomas (SSCs) of the head and neck, 25 primary, 1 metastatic, and 3 recurrent tumors, along with the corresponding constitutional tissues, were analyzed by using a battery of polymorphic DNA markers. For two primary tumors, we also analyzed subsequent metastatic tumors of the lung. Polymerase chain reaction-based restriction fragment length polymorphism studies demonstrated loss of heterozygosity for the APC gene in 2 of 12 (17%), the RB1 gene in 5 of 22 (23%), and the DCC gene in 5 of 13 (38%) informative cases. Alleles on chromosomes 3p, 11q13, and 18q21.1 were lost in 7 of 20 (35%), 9 of 23 (39%), and 4 of 17 (24%) informative cases, respectively. A breakpoint was identified within the chromosomal region 3p13-21.2 in a SCC of the tongue. Breakpoints within 11q13 were identified in 2 additional tumors. Thus, allelic deletions of DCC, 3p, and 11q13 appear to be common in head and neck cancers, suggesting that these genes play a critical and complex role in the development of these tumors. Furthermore, the present study provides definitive evidence for a tumor suppressor gene at chromosome band 11q13 and localizes this gene to the INT2-D11S533 interval for future cloning and sequencing.

RhD genotype determination by single sperm cell analysis

OBJECTIVE

An Rh-negative woman with preexisting anti-D antibodies may affect some or all subsequent fetuses, depending on the genotype of her Rh-positive partner. Currently, a reliable technique for an absolute determination of RhD genotype is not available. This study was initiated to develop an accurate method for RhD genotyping in men.

STUDY DESIGN

RhD genotype was determined by deoxyribonucleic acid amplification of a D-specific sequence in single sperm cell samples. Micromanipulation techniques were used for sampling of single sperm cells, which were further amplified by multiplex nested polymerase chain reaction at the RhD locus. A RhD sequence amplification product was expected in all of the successfully amplified samples from Rh-positive homozygotes, in some of the samples from heterozygotes, and in none of the samples form Rh-negative subjects.

RESULTS

RhD genotype was accurately determined in 10 of 10 donors. A total of 132 single sperm cells were analyzed (8 to 17 samples per donor), of which 96 were successfully amplified as assessed by an internal control. As expected, the specific region of the RhD gene was amplified in all, some, and none of the signal-positive sperm samples from Rh-positive homozygotes, heterozygotes, and Rh-negative subjects, respectively, allowing accurate determination of the genotype.

CONCLUSION

An accurate diagnosis of the RhD genotype can be attained from single sperm cell analysis by means of polymerase chain reaction and may have major clinical applications in the management of Rh isoimmunization.

High resolution localization of recombination hot spots using sperm typing

We have applied sperm DNA typing to determine the distribution of crossover events within a one megabase region of the short arm of human chromosome 4 near the locus for Huntington disease. A total of 29 recombinants were detected among 602 sperm typed after whole genome amplification. These recombinants were typed for seven polymorphic markers. The 280 kilobase D4S10-D4S126 interval was found to undergo recombination at a 6-9-fold greater rate per unit of physical distance than the adjacent 720 kb D4S126-D4S127 interval. Sperm typing has the potential to dissect mammalian recombination hot spots to the point where DNA sequence analysis may reveal the molecular basis for hyperrecombination.

Homozygous deletion, rearrangement and hypermethylation implicate chromosome region 3p14.3-3p21.3 in sporadic breast-cancer development

DNAs from 19 malignant human breast tumors and 2 benign fibroadenomas were analyzed for heterozygosity at 5 polymorphic loci on the short arm of chromosome 3. One homozygous deletion and one rearrangement were identified using probe D3S2 which maps to 3p14.3-3p21.1. This probe also detected novel hybridizing fragments of 2.0 kb and/or 3.4 kb in 6/18 (33%) of the malignant tumor samples that hybridized with the D3S2 probe following digestion with the 5'-methylcytosine-insensitive enzyme MspI. Comparisons of HpaII and MspI digestion showed that all but one of the tumor DNAs analyzed were hypermethylated. The two fibroadenoma DNAs were not as highly methylated and had hybridizing fragments of 3.4 kb after HpaII digestion. These malignant breast-tumor DNAs exhibit 3 mechanisms by which a tumor-suppressor gene hypothesized to reside at 3p14-3p21 could be inactivated: homozygous deletion, rearrangement and hypermethylation, and strongly implicate this 3p chromosome region in breast-tumor development.

Gene mapping of the mammalian genome: the CEPH and Genethon initiative

Over the past four years, the CEPH (Jean Dausset Foundation) has expanded its linkage mapping effort to include physical mapping and, in 1990, co-founded the Genethon to ensure that a combined physical and genetic map of the entire human genome would be achieved. The Genethon has applied methods developed at CEPH on an industrial scale to accomplish the colossal task of constructing an integrated map. It is the role of such an integrated map to accelerate the search for the genes responsible for inherited diseases, and the results of the past 12 months encourage our optimism that this goal will be realized rapidly. These discoveries are providing not only an approach to the diagnosis of genetically based disease but also some of the first breakthroughs in the area of gene therapy.

Order of bovine DRB3, DYA, and PRL determined by sperm typing

The order and recombination fractions (theta) between the bovine major histocompatibility complex DRB3, DYA, and prolactin (PRL) genes were determined by typing of 254 sperm from a triply heterozygous bull. A recently developed method, primer extension preamplification (PEP), was used to amplify the bovine sperm genome prior to amplification of specific loci by the polymerase chain reaction (PCR). At least 28 copies of the DRB3, PRL, or DYA gene were obtained from 50 cycles of PEP. For sperm typing, alleles of each locus were discriminated by restriction endonuclease cleavage of PCR products and polyacrylamide gel electrophoresis of the restriction fragments. The most likely gene order is PRL-DRB3-DYA, with theta = 0.025 (+/- 0.012) and theta = 0.150 (+/- 0.024), respectively. The odds are 128:1 in favor of this order in comparison with the second most likely order DRB3-PRL-DYA. Our results demonstrate the power of sperm typing in concert with PEP for multilocus gene mapping.

Using the polymerase chain reaction to estimate mutation frequencies and rates in human cells

The Polymerase Chain Reaction (PCR) has had a significant impact on molecular studies of human mutagenesis, mainly in the acceleration of molecular characterisation of mutant genes in cells isolated by a phenotypic selection. PCR can also be used to study genetic alterations in cells which have not undergone phenotypic selection. By modifying the standard PCR parameters, the presence of mutations can be assayed in single human cells, creating the potential to determine mutation rates in gametes on a cell-by-cell basis (Section I). Alternatively, PCR can be used to selectively amplify a mutant gene in a pool of normal genomes and thus determine a mutation frequency (Section II). Current applications of these two approaches are summarised and critically reviewed.

Whole genome amplification from a single cell: implications for genetic analysis

We have developed an in vitro method for amplifying a large fraction of the DNA sequences present in a single haploid cell by repeated primer extensions using a mixture of 15-base random oligonucleotides. We studied 12 genetic loci and estimate that the probability of amplifying any sequence in the genome to a minimum of 30 copies is not less than 0.78 (95% confidence). Whole genome amplification beginning with a single cell, or other samples with very small amounts of DNA, has significant implications for multipoint mapping by sperm or oocyte typing and possibly for genetic disease diagnosis, forensics, and the analysis of ancient DNA samples.

Close linkage between bovine prolactin and BoLA-DRB3 genes: genetic mapping in cattle by single sperm typing

The major histocompatibility complex and prolactin (PRL) genes are syntenic in humans and cattle but the genetic distance between these loci has not been determined for either species. In this study, the sperm typing technique was used to measure the recombination frequency between the bovine lymphocyte antigen (BoLA)-DRB3 and PRL loci. A total of 300 sperm were typed from one doubly heterozygous bull for segregation of DRB3 and PRL alleles. Sperm typing was performed using the polymerase chain reaction (PCR) and restriction enzyme cleavage of the PCR products, followed by resolution of the restriction fragments in polyacrylamide gels. Digestion with the restriction endonuclease RsaI allowed the unambiguous discrimination of alleles for both loci. The maximum likelihood estimation of the recombination fraction theta = 0.04, with a 95% confidence interval of 0.01 to 0.07. Close linkage between PRL and DRB3 has important implications for marker-assisted selection in animal breeding since PRL has been shown to be closely linked to a locus that affects milk yield, and BoLA loci influence susceptibility to a number of infectious diseases. Our results demonstrate the general applicability of the sperm typing procedure for gene mapping in species other than humans and provide an example of how parallel efforts to map the genomes of agriculturally important species of animals can have a positive impact on the development of a primary human linkage map.