An efficient technique for obtaining sequences flanking inserted retroviruses

SiteFinding-PCR: a simple and efficient PCR method for chromosome walking

In this paper, we present a novel PCR method, termed SiteFinding-PCR, for gene or chromosome walking. The PCR was primed by a SiteFinder at a low temperature, and then the target molecules were amplified exponentially with gene-specific and SiteFinder primers, and screened out by another gene-specific primer and a vector primer. However, non-target molecules could not be amplified exponentially owing to the suppression effect of stem–loop structure and could not be screened out. This simple method proved to be efficient, reliable, inexpensive and time-saving, and may be suitable for the molecules for which gene-specific primers are available. More importantly, large DNA fragments can be obtained easily using this method. To demonstrate the feasibility and efficiency of SiteFinding-PCR, we employed this method to do chromosome walking and obtained 16 positive results from 17 samples.

T-linker-specific ligation PCR (T-linker PCR): an advanced PCR technique for chromosome walking or for isolation of tagged DNA ends

Dozens of PCR-based methods are available for chromosome walking from a known sequence to an unknown region. These methods are of three types: inverse PCR, ligation-mediated PCR and randomly primed PCR. However, none of them has been generally applied for this purpose, because they are either difficult or inefficient. Here we describe a simple and efficient PCR strategy--T-linker-specific ligation PCR (T-linker PCR) for gene or chromosome walking. The strategy amplifies the template molecules in three steps. First, genomic DNA is digested with 3' overhang enzymes. Secondly, primed by a specific primer, a strand of the target molecule is replicated by Taq DNA polymerase and a single A tail is generated on the 3' unknown end of the target molecule, and then a 3' overhang-T linker (named T-linker) is specifically ligated onto the target. Thirdly, the target is amplified by two rounds of nested PCR with specific primers and T-linker primers. T-linker PCR significantly improves the existing PCR methods for walking because it uses specific T/A ligation instead of arbitrary ligation or random annealing. To show the feasibility and efficiency of T-linker PCR, we have exploited this method to identify vector DNA or T-DNA insertions in transgenic plants.

Genetic heterogeneity in acute myeloid leukemia: maximizing information flow from MuLV mutagenesis studies

The study of myeloid leukemia induced by slow transforming murine leukemia viruses (MuLV) in the laboratory mouse has led to discovery of many important genes with critical roles in regulating the growth, death, lineage determination and development of hematopoietic precursor cells. This review provides an overview of the susceptible strains and virus isolates that cause acute myeloid leukemia (AML) in mice. In addition, newer methodologies, involving the use of the polymerase chain reaction, that have been used to identify cancer genes mutated by proviral insertion in mouse models, will be discussed. As cancer is a multi-gene disease, a system in which pairs of oncogenic mutations are classified as redundant, neutral or synergistic is described. The potential to combine MuLV mutagenesis with recent advances in mouse transgenesis in order to model specific forms of myeloid leukemia or genetic pathways common in human AML will be discussed. Finally, a general strategy for maximizing these genetically rich models to foster a better understanding of AML physiology and developing therapies is proposed.

Long range-inverse PCR (LR-IPCR): extending the useful range of inverse PCR

The inverse PCR technique (IPCR) has proven to be very useful for the amplification of uncharacterized stretches of DNA upstream or downstream of regions that have already been cloned and sequenced. In practice, however, chromosome walking using standard IPCR is often a slow, repetitive process because only small DNA fragments are effectively amplified. The development of long and accurate PCR methodology has greatly expanded the range of DNA fragment sizes that is amenable to amplification by conventional PCR. We reasoned that combining long range PCR with IPCR would also extend the useful range of the IPCR technique. In this paper we demonstrate the utility of the hybrid, long range-inverse PCR (LR-IPCR) technique by generating clones containing long stretches of DNA flanking endogenous chicken proviral elements.