Interspersed repetitive sequence (IRS)-PCR amplification of pulsed-field gel fractionated DNA to derive markers from the incontinentia pigmenti 1 (IP1) locus

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.

MATS: a rapid and efficient method for the development of microsatellite markers from YACs

In this report, we describe the successful application of a rapid and efficient procedure, based on subtractive hybridization and PCR amplification, for generating microsatellite-based markers directly from yeast artificial chromosomes (YACs). This strategy, termed MATS (marker addition through subtraction), exploits the fact that the only difference between a yeast host strain harboring a YAC and the host strain alone is the artificial chromosome. Given the low complexity of the yeast genome and relatively large target size presented by a YAC, only a single round of subtraction is required before amplification of the target sequences (YAC) and cloning into a plasmid vector for further analysis. Several key steps have been designed to achieve optimal subtraction and to obtain preferential amplification and recovery of the target sequences. Methods for efficient construction of small insert libraries and rapid, nonradioactive screening have also been integrated into the protocol. Using a 750-kb YAC as a target, we identified a minimum of 14 unique microsatellite containing clones, leading to the development of 12 polymorphic STSs (sequence-tagged sites). These new markers will facilitate the genetic localization of targeted locus and allow the accurate ordering by STS content mapping of a cloned contig spanning the interval. In addition to the utility of this approach in positional cloning, this strategy may provide an approach for filling gaps in the emerging genetic maps.

Partitioned pulsed-field gel electrophoresis-PCR (PPF-PCR): a new method for pulsed-field mapping for STS and microsatellites

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