Gabriele Senger

High resolution multicolor-banding: a new technique for refined FISH analysis of human chromosomes

A new multicolor-banding technique has been developed which allows the differentiation of chromosome region specific areas at the band level. This technique is based on the use of differently labeled overlapping microdissection libraries. The changing fluorescence intensity ratios along the chromosomes are used to assign different pseudo-colors to specific chromosome regions. The multicolor banding of human chromosome 5 is presented as an example.

Two simple procedures for releasing chromatin from routinely fixed cells for fluorescence in situ hybridization.

We describe two methods for releasing chromatin from routinely harvested and fixed cells. Using fluorescence in situ hybridization with combinations of probes from the HLA class II region, we show that good signals can be obtained on free chromatin fibers enabling determination of relationships between closely adjacent or overlapping probes.

Microdissection of banded human chromosomes

SummaryPhysical dissection of metaphase chromosomes is the most straightforward approach for the isolation of DNA sequences from specific chromosome regions. However, conventional microdissection techniques are too crude and inefficient for analysis of the human genome. Here we describe a technique for the precise dissection of single bands from GTG-banded chromosomes. Cells from normal amniotic fluid cell cultures are harvested by the pipette method. Microdissection is performed on an inverted microscope (magnification 1250 x) with the help of extended siliconized glass needles and an electronically controlled micromanipulator. Enzymatic amplification of the dissected DNA allows the construction of band-specific DNA libraries from as few as 20 dissected chromosome fragments.

Homologous sequences at human chromosome 9 bands p12 and q13-21.1 are involved in different patterns of pericentric rearrangements

A thorough study of the heterochromatin organisation in the pericentromeric region and the proximal long (q) and short (p) arms of human chromsome 9 (HSA 9) revealed homology between 9p12 and 9q13-21.1, two regions that are usually not distinguishable by molecular cytogenetic techniques. Furthermore, the chromosomal regions 9p12 and 9q13-21.1 showed some level of homology with the short arms of the human acrocentric chromosomes. We studied five normal controls and 51 clinical cases: 48 with chromosome 9 heteromorphisms, one with an exceptionally large inversion and two with an additional derivative chromosome 9. Using fluorescence in situ hybridisation (FISH) with three differentially labelled chromosome 9-specific probes we were able to distinguish 12 heteromorphic patterns in addition to the most frequent pattern (defined as normal). In addition, we studied one inversion 9 case with the recently described multicolour banding (MCB) technique. Our results, and previously published findings, suggest several hotspots for recombination in the pericentromeric heterochromatin of HSA 9. They also demonstrate that constitutional inversions affecting the pericentromeric region of chromosome 9 carry breakpoints located preferentially in 9p12 or 9q13-21.1 and less frequently in 9q12.

Microdissection of the Prader-Willi syndrome chromosome region and identification of potential gene sequences

The Prader-Willi syndrome chromosome region on the long arm of human chromosome 15 was microdissected and microcloned from 20 GTG-banded metaphase chromosomes, and 5000 recombinant clones were obtained. Of these clones, 39% identify single-copy human DNA sequences, most of which map to the dissected chromosome region and are evolutionarily conserved in other species. Three of eleven clones studied in detail are deleted in several patients with Prader-Willi syndrome. The microclones will be useful for the physical characterization of the Prader-Willi syndrome chromosome region and the identification of the affected genes in this disease.

Construction and characterization of band-specific DNA libraries

SummaryA universally primed polymerase chain reaction was developed to amplify DNA dissected from GTG-banded human chromosomes. The amplification products are cloned into plasmid vectors, which allow the rapid characterization of recombinant clones. Starting from 20–40 chromosome fragments, several thousand independent clones detecting single-copy sequences can be obtained. Although these libraries comprise only a few percent of the dissected DNA, they provide narrowly spaced anchor clones for the molecular characterization of chromosome bands and the identification of gene sequences. Here we describe the construction and characterization of DNA libraries for the Langer-Giedion syndrome chromosome region (LGCR, 8q23–24.1), Wilms tumor chromosome region 1 (WT1, 11p13), Prader-Willi syndrome/Angelman syndrome chromosome region (PWCR/ANCR, 15q11.2–12), meningioma chromosome region (MGCR, 22q12–13), and fragile X chromosome region (FRAXA, Xq27.3).

Interstitial deletion of chromosome 6q: Precise definition of the breakpoints by microdissection, DNA amplification, and reverse painting

Routine chromosomal analysis using GTG-banding alone showed a mosaic terminal deletion of 6q in a 14-week-old boy with developmental retardation, facial anomalies, agenesis of corpus callosum, cleft palate, hypotonia, short neck and pterygium colli, and minor anomalies of hands and feet. Discrepancies between the clinical findings on our patient and those described in the literature on patients having terminal deletions led to a more precise analysis of the karyotype. Reverse painting was performed on normal G-banded metaphases for exact determination of the breakpoints and on metaphases of the patient for evaluation of mosaicism. A DNA library that was obtained by microdissection of three deleted chromosomes 6 was used as a painting probe. Subsequent DNA amplification was performed with the help of topoisomerase-pretreated degenerate oligonucleotide primers. Unexpectedly, the hybridization pattern on normal metaphase chromosomes revealed an interstitial deletion with breakpoints at 6825.1 and 6827 instead of a terminal deletion. Hybridization on metaphases of the patient showed one deleted chromosome 6 in all metaphases analyzed at a higher resolution rather than mosaicism as previously assumed karyotype, 46,XYdel(6)(g25.1→g27)]. We assume that in the single cases of 6q− described in the literature the deletions are misclassified. This might be due to difficulties in distinguishing between interstitial and terminal deletions at 6q and in precisely defining chromosomal breakpoints after GTG-banding alone.

Fine mapping of the human MHC class II region within chromosome band 6p21 and evaluation of probe ordering using interphase fluorescence in situ hybridization

Eight previously well-characterized and mapped probes derived from the human major histocompatibility complex (MHC) class II region were used to investigate the advantages and limitations of fluorescence in situ hybridization (FISH) techniques for fine mapping. The class II region of the MHC was localized within subband 6p21.31 by in situ hybridization on metaphase chromosomes that were banded by immunofluorescence staining with an antibody against 5-bromodeoxyuridine (BrdU). Ordering of probes that were separated by up to 900 kb was achieved by simultaneous hybridization of two or three probes on interphase nuclei. Three-color FISH proved to be an excellent method for ordering of probes within distances of 200-1,000 kb. Under certain conditions, closer probes could be ordered by comparing measured distances between their hybridization signals in interphase nuclei. A linear correlation between measured interphase distances and kilobase distances was observed up to 500 kb. With increasing distances, the measurements become more inaccurate due to chromatin folding.

An easy and reliable procedure of microdissection technique for the analysis of chromosomal breakpoints and marker chromosomes.

Microdissection in combination with reverse painting fluorescence in-situ hybridization (FISH) is a very effective method to identify breakpoints and rearrangements of derived chromosomes and reveal the chromosomal origin of marker chromosomes. We describe an innovation that allows a convenient, fast and safe isolation of microdissected fragments as currently available protocols. The microdissected chromosomes are harvested in a collection drop located in a movable micropipette adjusted to a second micromanipulator under microscopic observation. We used this technique to analyze several cytogenetic aberrations. In order to evaluate the efficiency of our microdissection procedure, we compared the results obtained with microdissection probes made from only one fragment with those obtained with more than six microdissected fragments. In all cases, the single- fragment microdissections were sufficient to provide probes.

New markers for the neurofibromatosis-2 region generated by microdissection of chromosome 22 ☆

To identify new DNA markers around the neurofibromatosis-2 gene on human chromosome 22, the critical region (22q12-q13.1) was microdissected and microcloned from GTG-banded metaphase chromosomes. Eighteen thousand recombinant clones were obtained. Twenty-seven of 55 clones tested (50%) detected single-copy DNA sequences. Nine of nine clones analyzed in detail were found to map to chromosome 22. Interestingly one clone (EAN04) is part of the leukemia inhibitory factor gene which has previously been mapped to 22q11.2-q13.1. Four clones (EAN01, EAN47, EAN57, and EAN68) detect DNA polymorphisms. These probes were used to compare constitutional and tumor genotypes of 41 patients with acoustic neurinoma. Loss of constitutional heterozygosity was identified in 17 of 31 informative cases (55%). From our data we conclude that the microdissection library is a valuable resource for physical and genetic mapping studies in neurofibromatosis-2.