Håkan Telenius

Chromosome 2-specific DNA clones from flow-sorted chromosomes of tomato

We obtained DNA clones specific to tomato chromosome 2 from a small number of chromosomes collected by flow sorting. Suspensions of metaphase chromosomes were prepared from 3-month-old tomato cell cultures of Lycopersicon pennellii. Isolated chromosomes stained with chromomycin A3 and Hoechst 33258 were analyzed on an EPICS 753 flow cytometer using a UV laser to excite Hoechst fluorescence and a 458 nm laser to excite chromomycin A3 fluorescence. Chromosomes from well-resolved peaks on a bivariate flow karyotype were sorted directly onto membrane filters for spot-blot analysis. The filters were processed and hybridized with chromosome-specific repetitive DNA probes. In this way tomato chromosome 1 and chromosome 2 were assigned to peaks in the bivariate flow karyotypes. One thousand copies of the putative chromosome 2 were flow-sorted directly into microfuge tubes. DNA specific to chromosome 2 was amplified by a polymerase chain reaction (PCR) technique using universal 22mer degenerate oligonucleotide primers (DOP) sequences. DOP-PCR yields a smear of fragments of various sizes from 250 to 1600 bp. Amplified products were cloned into the Bluescript plasmid vector. Approximately 11 of the clones contained sequences with highly repetitive elements, and 85% contained only low-copy-number sequences. Eleven clones containing low-copy-number sequences that detect restriction fragment length polymorphisms were placed on the molecular linkage map of tomato. All showed linkage to chromosome 2.

Complete characterization of a large marker chromosome by reverse and forward chromosome painting.

Marker chromosome are small supernumerary chromosomes that are sometimes associated with developmental abnormalities. Hence, the genes involved in such cases provide an interesting approach to understanding developmental abnormalities in man. As a first step towards isolating such sequences, marker chromosomes need complete characterization. By combining chromosome isolation by flow sorting and the “degenerate oligonucleotide primed — polymerase chain reaction”, we have constructed a DNA library specific for a marker chromosome found in a child with severe developmental abnormalities. We used fluorescent in situ hybridization of the library onto normal metaphase spreads (“reverse chromosome painting“) and were thus able to determine that the marker consists of the centromeric part of chromosome 7, the telomeric region of the long arm of chromosome 5 and the telomeric region of the short arm of the X-chromosome. Subsequently, we hybridized normal chromosome-specific libraries of the relevant chromosomes onto metaphases containing the marker chromosome (“forward chromosome painting”) and could in this manner establish the precise location of the different chromosome regions on the marker chromosome itself. This is a general approach suitable for outlining marker chromosomes in detail, and will aid the identification of the genes involved.

Stability of a functional murine satellite DNA-based artificial chromosome across mammalian species.

A 60-Mb murine chromosome consisting of murine pericentric satellite DNA and two bands of integrated marker and reporter genes has been generated de novo in a rodent/human hybrid cell line (mM2C1). This prototype mammalian artificial chromosome platform carries a normal centromere, and the expression of its β-galactosidase reporter gene has remained stable under selection for over 25 months. The novel chromosome was transferred by a modified microcell fusion method to mouse [L-M(TK−)], bovine (P46) and human (EJ30) cell lines. In all cases, the chromosome remained structurally and functionally intact under selection for periods exceeding 3 months from the time of transfer into the new host. In addition, the chromosome was retained in three first- generation tumours when L-M(TK−) cells containing the chromosome were xenografted in severe combined immunodeficiency mice. These data support that a murine satellite DNA-based artificial chromosome can be used as a functional mammalian artificial chromosome and can be maintained in vivo and in cells of heterologous species in vitro.

Complementary physical and genetic techniques map the vinculin (VCL) gene on chromosome 10q

Vinculin is a cytoskeletal protein component of adherens type cell junctions. The gene had been mapped to 10q11.2-qter. We have used a combination of physical and genetic mapping techniques to refine this localization. Hybridization of the vinculin cDNA probe, HV1, to a human-rodent somatic hybrid panel initially suggested a position of either 10q11.2 or 10q22.1-10q23. Genetic recombination mapping in three-generation families with multiple endocrine neoplasia type 2 (MEN2) indicated a position distal to D10S22 (10q21.1) in 10q22.1-10q23. This was confirmed by hybridization of the vinculin cDNA to flow-sorted translocation derivative chromosomes containing the q21-qter portion of chromosome 10. We conclude that the vinculin locus maps in 10q22.1-q23, distal to D10S22.

Minisatellite DNA Profiles: Rapid Sample Identification in Linkage Analysis

Locus-specific minisatellite probes detect multiple alleles with heterozygosities of greater than 90% when hybridised to HinfI and AluI restriction digests of human DNA. We have hybridised 4 of these probes to a panel of DNAs digested with 6 of the restriction enzymes which commonly reveal di-allelic polymorphisms in the human genome. All 6 enzymes detected multiple resolvable alleles with at least 1 of the 4 minisatellite probes tested, thus providing a rapid and efficient means to check family relationships and paternity on filters already being used for linkage analysis.