Toward the construction of integrated physical and genetic maps of the mouse genome using interspersed repetitive sequence PCR (IRS-PCR) genomics

Advanced integrated mouse YAC map including BAC framework

Functional characterization of the mouse genome requires the availability of a comprehensive physical map to obtain molecular access to chromosomal regions of interest. Positional cloning remains a crucial way of linking phenotype with particular genes. A key step and frequent stumbling block in positional cloning is making a contig of a genetically defined candidate region. The most efficient first step is isolating YAC (Yeast Artificial Chromosome) clones. A robust, detailed YAC contig map is thus an important tool. Employing Interspersed Repetitive Sequence (IRS)-PCR genomics, we have generated an advanced second-generation YAC contig map of the mouse genome that doubles both the depth of clones and the density of markers available. In addition to the primarily YAC-based map, we located 1942 BAC (Bacterial Artificial Chromosome) clones. This allows us to present for the first time a dense framework of BACs spanning the genome of the mouse, which, for instance, can serve as a nucleus for genomic sequencing. Four large-insert mouse YAC libraries from three different strains are included in our data, and our analysis incorporates the data of Hunter et al. and Nusbaum et al. There is a total of 20,205 markers on the final map, 12,033 from our own data, and a total of 56,093 YACs, of which 44,401 are positive for more than one marker.

A set of canine interrepeat sequence PCR markers for high-throughput genotyping

One hundred and sixteen interspersed repetitive DNA sequence (IRS)-PCR markers have been developed and characterized from Canis familiaris for high-throughput filter-based genotyping. We present a detailed analysis of markers produced by amplification using primers directed to the conserved regions of the C. familiaris short interspersed nuclear element (Can-SINE). The majority of IRS-PCR markers developed were moderately to highly polymorphic with mean heterozygosity (HET) and polymorphism information content (PIC) values of approximately 0.6. The HET value for 22.3% of the markers exceeded 0.7. We also demonstrate that sequence variation of Can-SINEs between breeds is significant and also represents a rich source of polymorphisms. Mapping of 73 of the markers to the existing integrated linkage-radiation hybrid map enriches the map as well as establishes the utility of the markers. The significance and utility of this new class of IRS-PCR Can-SINE-based markers for high-throughput genotyping is discussed. This method can also be extended to other species that are currently map-poor but have a sufficiently high density of SINEs to allow IRS-PCR.

High-throughput scanning of the rat genome using interspersed repetitive sequence-PCR markers

We report the establishment of a hybridization-based marker system for the rat genome based on the PCR amplification of interspersed repetitive sequences (IRS). Overall, 351 IRS markers were mapped within the rat genome. The IRS marker panel consists of 210 nonpolymorphic and 141 polymorphic markers that were screened for presence/absence polymorphism patterns in 38 different rat strains and substrains that are commonly used in biomedical research. The IRS marker panel was demonstrated to be useful for rapid genome screening in experimental rat crosses and high-throughput characterization of large-insert genomic library clones. Information on corresponding YAC clones is made available for this IRS marker set distributed over the whole rat genome. The two existing rat radiation hybrid maps were integrated by placing the IRS markers in both maps. The genetic and physical mapping data presented provide substantial information for ongoing positional cloning projects in the rat.

PCR-detected genome polymorphism in malignant cell growth

In this chapter, we analyze the problem of genetic polymorphism in tumorigenesis, which determines basic capacities of tumors. The study of genome polymorphism with modified PCR methods allows the detection of various forms of polymorphism in tumor cells. This method has made it possible to determine association of DNA polymorphism with conditions of oncogenes, antioncogenes, and genes of apoptosis and with their allelic states. A special type of nonspecific DNA polymorphism that resulted from an increase in the mutation number in the cancer cell genome was discovered. This phenomenon was called the microsatellite mutator phenotype. Because the type of DNA polymorphism correlates with various biological capacities of malignant tumors and has an important prognostic significance, the analysis of DNA polymorphism in benign and malignant tumors of different histogenesis will play an important role both in theoretical studies of cancer and in oncological practice. A modified B1-PCR was used to study the genome polymorphism in the mouse tumor cells. The gain of the band 470 bp and the loss of the band 600 bp were revealed in the hepatoma cell line MH-22a as compared with liver cells of C3HA mice. The differentiation of teratocarcinoma EC F9 cells to endoderm-like cells was not accompanied by any changes in the B1-AF DNA fingerprint.

Interspersed repetitive sequence (IRS)-PCR for typing of whole genome radiation hybrid panels

The typing of a radiation hybrid (RH) panel is generally achieved using a unique primer pair for each marker. We here describe a complementing approach utilizing IRS-PCR. Advantages of this technology include the use of a single universal primer to specify any locus, the rapid typing of RH lines by hybridization, and the conservative use of hybrid DNA. The technology allows the mapping of a clone without the requirement for STS generation. To test the technique, we have mapped 48 BAC clones derived from mouse chromosome 12 which we mostly identified using complex probes. As mammalian genomes are repeat-rich, the technology can easily be adapted to species other than mouse.

A STS content physical and transcription map across the ky, kyphoscoliosis, nonrecombinant region

The ky mouse mutant exhibits a degenerative muscle disease resulting in chronic deformation of the spinal column. Following a previous report describing the mapping of the ky locus to a small region of mouse chromosome 9 (Skynner et al., 1995, Genomics 25, 207-213), we have now undertaken a positional cloning approach to identify candidate genes for ky. A YAC/BAC contig encompassing the ky locus was constructed comprising 48 YAC clones and 48 newly generated STSs. The results from the combined physical and genetic analyses showed that only two overlapping BAC clones, which together do not exceed 260 kb, span the ky nonrecombinant region. A combination of gene hunting methods on the critical BACs has led to the identification of seven coding fragments, which have been tested for expression. The expression analysis and the position of the coding fragments on the contig suggest their grouping in at least four transcription units. One of these transcription units is expressed exclusively in skeletal muscle, making it a suitable candidate for this muscle defect in the ky mouse.

Physical mapping of the mouse genome

This review is intended to provide an overview of techniques and a source of reagents for physical mapping of the mouse genome. It focuses on those applications, methods, or resources unique to the mouse and on the generation of comparative physical maps. The reference list is not comprehensive; rather, recent reviews on each topic and selected representative examples are given.

IRS-PCR-based genetic mapping of the huntingtin interacting protein gene (HIP1) on mouse chromosome 5

Huntington's disease (HD) is a devastating central nervous system disorder. Even though the gene responsible has been positionally cloned recently, its etiology has remained largely unclear. To investigate potential disease mechanisms, we conducted a search for binding partners of the HD-protein huntingtin. With the yeast two-hybrid system, one such interacting factor, the huntingtin interacting protein-1 (HIP-1), was identified (Wanker et al. 1997; Kalchman et al. 1997) and the human gene mapped to 7q11.2. In this paper we demonstrate the localization of the HIP1 mouse homologue (Hip1) into a previously identified region of human-mouse synteny on distal mouse Chromosome (Chr) 5, both employing an IRS-PCR-based mapping strategy and traditional fluorescent in situ hybridization (FISH) mapping.

Application of interspersed repetitive sequence polymerase chain reaction for construction of yeast artificial chromosome contigs

Construction of physical maps across candidate regions is one of the rate-limiting steps of positional cloning projects. To date, most physical maps have been constructed by polymerase chain reaction (PCR)-based sequence-tagged site (STS) content mapping. While effective, this technique has a number of disadvantages including problems with yeast artificial chromosome (YAC) chimerism, the time and effort required to generate new STSs from YAC ends, the cost of primer synthesis for large contiging projects, and the time, effort, and expense necessary for screening each STS in the two-tiered hierarchical YAC library screening format. An alternative strategy, interspersed repetitive sequence (IRS) PCR genomics, alleviates many of these constraints. Clonal overlap is detected by hybridization of individual IRS-PCR products to IRS-PCR product pools of the three-dimensional coordinate pools of YAC libraries in dot-blot format. Entire libraries can be screened in a single step, and multiple libraries can be screened simultaneously. Cloning YAC fragments, sequencing, and primer generation are eliminated, increasing the efficiency of contig construction and reducing the expense. In addition, the genomic location of the individual IRS-PCR products can also be simultaneously determined by screening either interspecific backcrosses or radiation hybrid panels, in dot-blot format, confirming contig extension in the region of interest.

A deletion in the bovine myostatin gene causes the double-muscled phenotype in cattle

An exceptional muscle development commonly referred to as 'double-muscled' (Fig. 1) has been seen in several cattle breeds and has attracted considerable attention from beef producers. Double-muscled animals are characterized by an increase in muscle mass of about 20%, due to general skeletal-muscle hyperplasia-that is, an increase in the number of muscle fibers rather than in their individual diameter. Although the hereditary nature of the double-muscled condition was recognized early on, the precise mode of inheritance has remained controversial; monogenic (domainant and recessive), oligogenic and polygenic models have been proposed. In the Belgian Blue cattle breed (BBCB), segregation analysis performed both in experimental crosses and in the outbred population suggested an autosomal recessive inheritance. This was confirmed when the muscular hypertrophy (mh) locus was mapped 3.1 cM from microsatellite TGLA44 on the centromeric end of bovine chromosome 2 (ref. 5). We used a positional candidate approach to demonstrate that a mutation in bovine MSTN, which encodes myostatin, a member of the TGF beta superfamily, is responsible for the double-muscled phenotype. We report an 11-bp deletion in the coding sequence for the bioactive carboxy-terminal domain of the protein causing the muscular hypertrophy observed in Belgian Blue cattle.

Aberrant splicing of a mouse disabled homolog, mdab1, in the scrambler mouse

Although accurate long-distance neuronal migration is a cardinal feature of cerebral cortical development, little is known about control of this migration. The scrambler (scm) mouse shows abnormal cortical lamination that is indistinguishable from reeler. Genetic and physical mapping of scm identified yeast artificial chromosomes containing an exon of mdab1, a homolog of Drosophila disabled, which encodes a phosphoprotein that binds nonreceptor tyrosine kinases. mdab1 transcripts showed abnormal splicing in scm homozygotes, with 1.5 kb of intracisternal A particle retrotransposon sequence inserted into the mdab1 coding region in antisense orientation, producing a mutated and truncated predicted protein. Therefore, mdab1 is most likely the scm gene, thus implicating nonreceptor tyrosine kinases in neuronal migration and lamination in developing cerebral cortex.