Comparison of YACs containing mouse centromeric satellite sequences cloned in rad52 and RAD52 host strains

Investigation of Schizosaccharomyces pombe as a cloning host for human telomere and alphoid DNA

The fission yeast Schizosaccharomyces pombe (Sch. pombe) has been proposed as a possible cloning host for both mammalian artificial chromosomes (MACs) and mammalian genomic libraries, due to the large size of its chromosomes and its similarity to higher eukaryotic cells. Here, it was investigated for its ability to form telomeres from human telomere sequence and to stably maintain long stretches of alphoid DNA. Using linear constructs terminating in the telomere repeat, T2AG3, human telomere DNA was shown to efficiently seed telomere formation in Sch. pombe. Much of the human telomeric sequence was removed on addition of Sch. pombe telomeric sequence, a process similar to that described in S. cerevisiae. To investigate the stability of alphoid DNA in fission yeast, bacterial artificial chromosomes (BACs) containing 130 and 173 kb of alphoid DNA were retrofitted with the Sch. pombe ars1 element and ura4+ marker using Cre-lox recombination. These alphoid BACs were found to be highly unstable in Sch. pombe deleting down to less than 40 kb, whilst control BACs of 96 and 202 kb, containing non-repetitive DNA, were unrearranged. Alphoid DNA has been shown to be sufficient for human centromere function, and this marked instability excludes Sch. pombe as a useful cloning host for mammalian artificial chromosomes. In addition, regions containing repetitive DNA from mammalian genomes may not be truly represented in libraries constructed in Sch. pombe.

Fine physical and transcript mapping of a 1.8 Mb region spanning the locus for childhood acute lymphoblastic leukemia on chromosome 12p12. 3

Rearrangements of the short arm of chromosome 12 are frequently observed in hematological disorders. Previous studies of loss of heterozygosity identified a small genetic interval on chromosome 12p12.3 that is frequently deleted in childhood acute lymphoblastic leukemia (ALL). Two genes, ETV6/TEL and p27/KIP1, are located in this interval. Evidence has accumulated that an as-yet unidentified tumor suppressor gene is closely linked to these. To facilitate the identification of candidate genes, a long-range high-resolution restriction map of the ALL locus was constructed using a contig of YAC clones. Several marker loci, including 11 STS, three newly developed YAC end-based STS, six EST, and seven genes were unambiguously positioned in the new map. The map covers 1.8Mb and extends from the distal salivary proline-rich protein gene cluster to the proximal p27/KIP1 gene. The data confirmed the order tel-D12S358-p27/KIP1-cen and excluded p27/KIP1 as a candidate tumor suppressor gene. The critical region delimited by D12S89 and D12S358 is a 750kb CpG-island rich region that includes the 240kb TEL/ETV6 gene as well as CLAPS3 (clathrin-adaptor small chain 3). The new map provides a molecular framework for the identification of novel genes and transcriptional units in the ALL interval.

A Schizosaccharomyces pombe artificial chromosome large DNA cloning system

The feasibility of using the fission yeast, Schizosaccharomyces pombe , as a host for the propagation of cloned large fragments of human DNA has been investigated. Two acentric vector arms were utilized; these carry autonomously replicating sequences ( ars elements), selectable markers ( ura4(+) or LEU2 ) and 250 bp of S. pombe terminal telomeric repeats. All cloning was performed between the unique sites in both vector arms for the restriction endonuclease Not I. Initially the system was tested by converting six previously characterized cosmids from human chromosome 11p13 into a form that could be propagated in S.pombe as linear episomal elements of 50-60 kb in length. In all transformants analysed these cosmids were maintained intact. To test if larger fragments of human DNA could also be propagated total human DNA was digested with Not I and size fractionated by pulsed field gel electrophoresis (PFGE). Fractions of 100-1000 kb were ligated to Not I-digested vector arms and transformed into S.pombe protoplasts in the presence of lipofectin. Prototrophic ura+leu+transformants were obtained which upon examination by PFGE were found to contain additional linear chromosomes migrating at between 100 and 500 kb with a copy number of 5-10 copies/cell. Hybridization analyses revealed that these additional bands contained human DNA. Fluorescent in situ hybridization (FISH) analyses of several independent clones indicated that the inserts were derived from single loci within the human genome. These analyses clearly demonstrate that it is possible to clone large fragments of heterologous DNA in fission yeast using this S.p ombe artificial chromosome system which we have called SPARC. This vector-host system will complement the various other systems for cloning large DNA fragments.