mBAND: a high resolution multicolor banding technique for the detection of complex intrachromosomal aberrations

Precise breakpoint definition of chromosomal rearrangements using conventional banding techniques often fails, especially when more than two breakpoints are involved. The classic banding procedure results in a pattern of alternating light and dark bands. Hence, in banded chromosomes a specific chromosomal band is rather identified by the surrounding banding pattern than by its own specific morphology. In chromosomal rearrangements the original pattern is altered and therefore the unequivocal determination of breakpoints is not obvious. The multicolor banding technique (mBAND, see Chudoba et al., 1999) is able to identify breakpoints unambiguously, even in highly complex chromosomal aberrations. The mBAND technique is presented and illustrated in a case of intrachromosomal rearrangement with seven breakpoints all having occurred on one chromosome 16, emphasizing the unique analyzing power of mBAND as compared to conventional banding techniques.

Molecular cytogenetic detection of paternal chromosome fragments in allogynogenetic gibel carp, Carassius auratus gibelio Bloch

In gynogenesis, sperm from related species activates egg and embryonic development, but normally does not contribute genetically to the offspring. In gibel carp, Carassius auratus gibelio Bloch, however, gynogenetic offspring often show some phenotypes apparently derived from the heterologous sperm donor. This paternal effect of allogynogenesis is outstanding in an artificial clone F produced by cold treatment of clone E eggs after insemination with blunt-nose black bream (Megaloabrama amblycephala Yin) sperm. Karyotype analysis revealed 5-15 supernumerary microchromosomes in different individuals of clone F in addition to 156 normal chromosomes inherited from the maternal clone E. A painting probe was prepared from the microdissected microchromosomes, and used to investigate the origin of these microchromosomes. Strong positive signals were detected on each microchromosomes of clone F and on 4 pairs of chromosomes in blunt-nose black bream, whereas no signals were detected on the chromosomes of clone E. This result indicates that some paternal chromosome fragments of blunt-nose black bream have been incorporated into the artificial clone F. Therefore, the manipulation of allogynogenesis may provide a unique method to transfer DNA between diverse species for fish breeding.

Multicolor spectral karyotyping of rat chromosomes

Rat and mouse have become important animal models to study various human diseases such as cancer. Cytogenetic analysis of the respective karyotypes is frequently required to investigate the causative genetic defects and especially neoplastic cells often show complex chromosome aberrations and many different marker chromosomes. However, structural homogeneity of the chromosomes in these species as well as less pronounced differences in banding patterns make it difficult to assign genetic abnormalities to certain chromosomes by conventional banding techniques. Here we report for the first time the successful application of multicolor spectral karyotyping (SKY) to rat chromosomes, which allows unequivocal identification of all rat chromosomes with the exception of chromosomes 13 and 14 in different colors, thus enabling the elucidation of even complex rearrangements in the rat karyotype. Flow-sorted chromosome specific painting probes for all 22 rat chromosomes (20 autosomes, X, and Y) were combinatorially labeled by a set of five different fluorochromes and hybridized in situ to metaphase spreads of a healthy rat, to diakineses from testicular material, and to cells from a rat FAO hepatoma cell line. Measuring the complete spectrum at each image point by using the SpectraCube((R)) spectral imaging system and respective computer software allowed identification of the individual rat chromosomes by their specific emission spectra. Classification algorithms in the analysis software can then display the rat chromosomes in specific pseudo-colors and automatically order them in a karyotype table. After its successful application to human and mouse chromosomes, spectral karyotyping of rat chromosomes now also allows cytogenetic screening of the complete rat genome by a single hybridization.

Current status of fluorescent in-situ hybridisation

Several modifications have taken place in fluorescent in-situ hybridisation (FISH) techniques, including comparative genomic hybridisation, primed in-situ labelling, interphase FISH, multicolour FISH and in combination with peptide nucleic acid technology. FISH can also be combined with microarrays. Selected innovative technologies are described. The most clinically important applications are in cytogenetics and oncology.

Karyotypic relationships of horses and zebras: results of cross-species chromosome painting

Complete sets of chromosome-specific painting probes, derived from flow-sorted chromosomes of human (HSA), Equus caballus (ECA) and Equus burchelli (EBU) were used to delineate conserved chromosomal segments between human and Equus burchelli, and among four equid species, E. przewalskii (EPR), E. caballus, E. burchelli and E. zebra hartmannae (EZH) by cross-species chromosome painting. Genome-wide comparative maps between these species have been established. Twenty-two human autosomal probes revealed 48 conserved segments in E. burchelli. The adjacent segment combinations HSA3/21, 7/16p, 16q/19q, 14/15, 12/22 and 4/8, presumed ancestral syntenies for all eutherian mammals, were also found conserved in E. burchelli. The comparative maps of equids allow for the unequivocal characterization of chromosomal rearrangements that differentiate the karyotypes of these equid species. The karyotypes of E. przewalskii and E. caballus differ by one Robertsonian translocation (ECA5 = EPR23 + EPR24); numerous Robertsonian translocations and tandem fusions and several inversions account for the karyotypic differences between the horses and zebras. Our results shed new light on the karyotypic evolution of Equidae.

[Cytogenetic and molecular genetic studies on a variant of t(15;17), ins(17;15)(q21;q14q22), in an acute promyelocytic leukemia patient]

OBJECTIVE

To report a rare variant of t(15;17), ins(17;15)(q21;q14q22) in an acute promyelocytic leukemia (APL) patient and the results of cytogenetic and molecular genetic studies.

METHODS

Chromosomes were prepared after 24 hours culture of bone marrow cells and peripheral blood cells. R-banding technique was used to analyze karyotypes. Chromosome painting analysis was performed using whole chromosome paints for chromosomes 15 and 17. PML-RAR alpha and RAR alpha-PML fusion transcripts were detected by reverse transcription-polymerase chain reaction (RT-PCR).

RESULTS

Karyotypic analysis using both specimens from bone marrow and peripheral blood leukemic cells revealed 15q- and 17q+. Chromosome painting analysis confirmed that the karyotypic abnormality was ins(17;15). PML-RAR alpha fusion transcript (S type) was detected by RT-PCR, while RAR alpha-PML fusion transcript was not detected.

CONCLUSION

Chromosome painting and RT-PCR are reliable methods for characterization of the insertion involving chromosomes 15 and 17 in APL patients.

Refined genome-wide comparative map of the domestic horse, donkey and human based on cross-species chromosome painting: insight into the occasional fertility of mules

We have made a complete set of painting probes for the domestic horse by degenerate oligonucleotide-primed PCR amplification of flow-sorted horse chromosomes. The horse probes, together with a full set of those available for human, were hybridized onto metaphase chromosomes of human, horse and mule. Based on the hybridization results, we have generated genome-wide comparative chromosome maps involving the domestic horse, donkey and human. These maps define the overall distribution and boundaries of evolutionarily conserved chromosomal segments in the three genomes. Our results shed further light on the karyotypic relationships among these species and, in particular, the chromosomal rearrangements that underlie hybrid sterility and the occasional fertility of mules.

Chromosome evolution in bears: reconstructing phylogenetic relationships by cross-species chromosome painting

Genome-wide homology maps among dog (Canis familiaris, CFA, 2n = 78), African lion (Panthera leo, PLE, 2n = 38), clouded leopard (Neofelis nebulosa, NNE, 2n = 38) and Malayan sun bear (Helartos malayanus, HMA, 2n = 74) have been established by chromosome painting using a complete set of dog probes. In total, chromosome-specific painting probes from the 38 dog autosomes reveal 69, 69 and 73 conserved segments in African lion, clouded leopard and Malayan sun bear, respectively. The chromosomal painting results show that the African lion and clouded leopard have an identical karyotype which, in turn, is similar to that previously published for the cat (Felis catus, FCA 2n = 38). The findings confirm and extend other studies that show felids to be karyotypically conserved. In contrast, ursids, including the Malayan sun bear, have a relatively highly rearranged karyotype in comparison with other carnivores. The 2n = 74 karyotype of the Malayan sun bear, which is believed to closely resemble the ancestral karyotype of the Ursidae, could have evolved from the 2n = 42 putative ancestral carnivore karyotype by an inversion and 16 centric fissions. Independent fusions of the acrocentric ancestral chromosomes have generated the unique karyotypes of the giant panda and the spectacled bear.

A chromosome painting test of the basal Eutherian karyotype

We studied the chromosomes of an Afrotherian species, the short-eared elephant shrew Macroscelides proboscideus with traditional banding techniques and mapped the homology to human chromosomes by in-situ hybridization of human chromosome paints. Here we present for the first time the karyotype of this species, including banding patterns. The chromosome painting allowed us to test various hypotheses of the ancestral Eutherian karyotype, the validity of the radical taxonomic assemblage known as Afrotheria and the phylogenetic position of the elephant shrew within the Afrotheria. Current hypotheses concerning the Eutherian ancestral karyotype include diploid numbers ranging from 2n = 44 to 50 while molecular studies have proposed a new superordinal grouping of extant Eutherians. In particular, the Afrotheria is hotly debated, as it appears to be an odd mixture of species from Ungulata, Tubulidentata, Macroscelidea and Lipotyphla, which have no apparent morphological traits to unite them. The hybridization pattern delimited a total of 37 segments in the elephant shrew genome and revealed 21 different associations of human chromosome segments. Associations 1/19 and 5/21 link all Afrotheria so far studied and support the Afrotheria assemblage. Associations 2/8, 3/20, and 10/17 strongly link aardvarks and elephant shrews after the divergence of the line leading to elephants. The most likely ancestral Eutherian karyotype would be 2n = 48 chromosomes. However, the lack of comparative chromosome painting data between Eutherians and an appropriate outgroup is a severe limitation on attempts to delineate the ancestral genome of Eutherians. Current attempts lack legitimacy until this situation is corrected.

Multicolor chromosome painting in diagnostic and research applications

For many years whole chromosome painting probes have been the work-horses in a large variety of clinical and research molecular cytogenetic applications. In recent years painting probes have been complemented by an increasing number of further region-specific probes, which allow the specific staining of centromeres, subtelomeres or other regions within the genome. This development of new probe sets was greatly facilitated by the Human Genome Project from which well-characterized probes for any region within the genome have emerged. Furthermore, the evolution of different multicolor fluorescence in situ hybridization (FISH) technologies now allows the cohybridization of multiple DNA-probes of different colors. These developments have paved the way for FISH-based automated karyotyping or the simultaneous analysis of multiple defined regions within the genome. Using appropriate instrumentation and image processing, the analysis can be performed two-dimensionally on metaphase spreads or three-dimensionally in intact interphase nuclei. Here we summarize some of the most recent developments and discuss the application of painting probes in different scenarios.

Characterization of psu dic(6;5)(p21.3;q13) with reverse chromosome painting in a patient with secondary myelodysplastic syndrome following treatment for multiple myeloma

We report a case of a psu dic(6;5)(p21.3;q13) in a patient with secondary myelodysplastic syndrome (sMDS) following treatment for multiple myeloma. The abnormal chromosome was isolated by flow karyotyping and initially identified by reverse chromosome painting. The findings were then confirmed by forward painting. The value of flow karyotyping as a diagnostic technique in hematologic malignancies is discussed.

Chromosome paints from single copies of chromosomes

We have used OmniPlex library technology to construct chromosome painting probes from single copies of flow sorted chromosomes. We show that this whole genome amplification technology is particularly efficient at amplifying single copies of chromosomes for the production of paints and that single aberrant chromosomes can be analysed in this way using reverse chromosome painting. The efficient generation of painting probes from single copies of sorted chromosomes has the advantage that the probe must be specific for the chromosome sorted and will not suffer from contamination from other chromosomes particularly in situations where flow karyotype peaks are poorly resolved. These initial results suggest that OmniPlex whole genome amplification will be equally effective in other cytogenetic applications where only small amounts of DNA are available, i.e. from single cells or from small pieces of microdissected tissue.

Sequential multiple probe fluorescence in-situ hybridization analysis of human oocytes and polar bodies by combining centromeric labelling and whole chromosome painting

The incidence of chromosomal aneuploidy was analysed in 104 unfertilized human oocytes and 56 first polar bodies using a double-label fluorescence in-situ hybridization (FISH) procedure. Combinations of centromeric (or locus-specific) DNA probes and whole chromosome painting probes for chromosomes 9, 13, 16, 18, 21 and X were applied on oocyte preparations, in a sequential FISH protocol. This combined approach allowed a precise in-situ identification of both chromosomes and free chromatids, and consequently a reliable analysis of chromosomal segregation errors. Of the 104 analysed oocytes, 84 (80.7%) displayed a normal chromosome constitution. Three cases of chromosome non-disjunction (2.8%) were found, whereas seven oocytes (6.7%) presented extra single chromatids. In addition, 12 oocytes (11.5%) showed balanced pre-division of one pair of sister chromatids. Although this phenomenon was not classified as aneuploidy, it could lead to aneuploidy at anaphase II. Abnormalities were observed in all the targetted chromosomes. The present data confirm that both whole chromosome non-disjunction and premature chromatid separation constitute the two major mechanisms of aneuploidy in human female meiosis.

Molecular cytogenetic characterization of the KG-1 and KG-1a acute myeloid leukemia cell lines by use of spectral karyotyping and fluorescence in situ hybridization

The KG-1 cell line, established from bone marrow cells of a patient with erythroleukemia evolving to acute myelogenous leukemia, and its less differentiated variant, KG-1a, are widely used in research worldwide. However, to our knowledge, neither cell line was studied by use of molecular-cytogenetic techniques such as spectral karyotyping (SKY) and fluorescence in situ hybridization (FISH). Our G-banding, SKY, and FISH analyses revealed a complex karyotype with a pseudodiploid modal chromosome number in both the KG-1 and KG-1a cell lines. The lines shared several identical structural aberrations, including der(4)t(4;8), del(7q), der(8)t(8;12), idic(8)(p11), der(17)t(5;17), and der(20)t(12;20), but also differed with regard to other chromosome rearrangements. In contrast to KG-1, the KG-1a line lost one of the two copies of idic(8)(p11) present in KG-1 cells and gained a der(8;22)(q24;q13), an i(11)(q10), and a der(19)t(14;19)(q13;q13.4). Notably, we have shown that the KG-1 cells harbor a partial hexasomy of the long arm of chromosome 8, which may explain in part the previously reported significantly higher rate of formation of the AML1-ETO fusion gene in KG-1 cells subjected to high-dose gamma irradiation compared with the rates of formation of the BCR-ABL or the DEK-CAN fusion gene. Our detailed description of chromosome rearrangements in KG-1 and KG-1a will be useful for the cytogenetic authentication of the lines, and provide clues as to the regions of the genome that could be studied further to explain the differences in phenotypic properties between KG-1 and KG-1a cells.

A new chromosome banding technique, spectral color banding (SCAN), for full characterization of chromosomal abnormalities

We have developed spectral color banding (SCAN) as a new chromosome banding technique based on spectral analysis of differentially labeled chromosome band-specific painting probes. In this study, we succeeded in displaying a multicolor banding pattern for chromosome 3, which was almost identical to the pattern obtained with the corresponding G-banding. We applied this method to metaphase cells from different normal male donors with various levels of G-banding resolution, ranging from 250 to 850 bands per haploid set. The same multicolor banding pattern was observed in all samples regardless of the length of the chromosomes or the quality of the G-banding. We then used SCAN in a diffuse large B-cell lymphoma case for a complete analysis of the intrachromosomal change for chromosome 3, which could not be fully characterized by G-banding or even by spectral karyotyping (SKY). SCAN could detect the duplicated segment and identify the origin of the chromosome band on the basis of the specific spectral color of each band. This study demonstrates that SCAN is a useful tool for full characterization of chromosomal abnormalities not identified by SKY.

The use of laser microdissection for the preparation of chromosome-specific painting probes in farm animals

Laser microbeam microdissection and laser pressure catapulting procedure were used for the construction of chromosome-specific painting probes, arm-specific probes and probes for chromosomal subfragments. We report on a method for generation of fluorescence in-situ hybridization probes from laser dissected chromosomes of farm animals. So far, using the described method, a set of chromosome-specific painting probes has been obtained for all porcine chromosomes, 17 chromosomes of cattle and selected equine chromosomes. It is concluded that the laser technology appears to be a useful and powerful tool for the construction of chromosome-specifi c painting probes. Its main advantage is the fast non-contact collection of chromosomes.

Role of short telomeres in inducing preferential chromosomal aberrations in human ovarian surface epithelial cells: A combined telomere quantitative fluorescence in situ hybridization and whole-chromosome painting study

It is well established that specific cancers and immortalized cells have nonrandom chromosome aberrations. However, little is understood about the underlying mechanism that initiates these aberrations in human cells. To examine whether human chromosomes with the shortest telomeres initiate the preferential chromosomal aberrations before cellular immortalization, we simultaneously applied telomere quantitative fluorescence in situ hybridization and specific whole-chromosome painting on chromosomes 1, 5, 8, 17, 19, and 20 in human ovarian surface epithelial (HOSE 6-3) cells expressing human papilloma viral oncogenes (HPV16 E6E7). The HPV16 E6E7-expressing cells, with extended in vitro life span and telomerase-negative status, were previously identified as having nonrandom chromosomal imbalances and high frequencies of dicentrics. Our analyses showed that among six pairs of targeted chromosomes, chromosomes 8 and 20 showed critically short telomeres with an undetectable telomere signal in more than 50% of cells analyzed. These chromosomes with the critically short telomeres were preferentially involved in various types of chromosomal aberrations including dicentrics, translocations, breaks, insertions, and losses or gains of chromosomal elements. Our findings suggest that nonrandom chromosome aberrations in HOSE cells occurring before cellular immortalization could be caused by the telomere length heterogeneity.

Chromosomal aberrations of multiple myeloma in Chinese patients at diagnosis: a study by combined G-banding and multicolor spectral karyotyping

Cytogenetic investigation of multiple myeloma (MM) has been difficult by conventional methods and most of the data have been derived from western population where incidence of MM is much higher as compared to that of Asians. The current study represents the first report of chromosomal aberrations of multiple myeloma in Chinese. We investigated 25 consecutive Chinese patients with MM for chromosomal aberrations at diagnosis using G-banding and multicolor spectral karyotyping (SKY). Of the 21 patients successfully analyzed by G-banding, 11 patients revealed cytogenetic abnormalities showing complex numerical and structural aberrations, which were further characterized with SKY. An abnormal karyotype significantly associated with blastic MM was observed. Consistent with the western literature, structural rearrangements involving chromosomes 1, 6, 8, 19, numerical abnormalities of gains in chromosomes 9, 3, and 5, and losses in chromosomes 13 and 14 were observed. However, there were notably higher incidences of -22/22q- (4/11) and structural aberrations of chromosome X but a lower incidence of -X. The biological implications of these findings, if confirmed, deserve further evaluation.

The abnormalities of chromosome 8 in two hepatocellular carcinoma cell clones with the same genetic background and different metastatic potential

PURPOSE

Two hepatocellular carcinoma (HCC) cell clones named MHCC97-H and MHCC97-L with different metastatic potential have recently been established from the same parent cell line MHCC97 in our institute. The cytogenetic alterations of these two clones were investigated in this study to explore the possible clues to the mechanism involved in HCC metastasis.

METHODS

Their chromosomal aberrations were analyzed with comparative genomic hybridization (CGH), chromosome-specific painting, and two-color fluorescence in situ hybridization (FISH).

RESULTS

The aberrations were found in a total of 17 chromosomes, and six kinds of the aberrations including gains of 1q, 7q, 8q, 20, and the losses of 8p23, 21q were found both in the two cell clones and their parent cell line MHCC97. Using modified CGH, with the DNA of MHCC97-L as control to test the MHCC97-H clone, the loss of 8p23 and the gain of 1q31-32, 8q21.3-22, 13q22, 17q22 were highlighted, and the most significant finding was on chromosome 8. Dual color FISH combining a pericentromeric probe and a BAC probe mapping at 8q23.1 was then performed to verify this result, and the signal ratios of the BAC to centromere were 1.43 in MHCC97-H and 1.45 in MHCC97-L, confirming the over-representations at 8q in both cells. Another interesting finding in the dual-color metaphase FISH was the intrachromosomal translocation of 8q to 8p (looked like an isochromosome 8) and non-reciprocal translocation of part of 8q to 4q, which was further clarified and proved by the FISH with whole chromosome 8 painting probe.

CONCLUSIONS

The high copies amplification on 8q, the formation of isochromosome 8, non-reciprocal translocation of partial 8q to 4q, and loss of 8p occurred at the same time and are the characteristic chromosomal aberrations of the two cell clones. The chromosome 8p, especially 8p23, might harbor some novel genes related to the HCC metastasis.

Genomic deletions on other chromosomes involved in variant t(9;22) chronic myeloid leukemia cases

The Philadelphia (Ph) chromosome is the cytogenetic hallmark of chronic myeloid leukemia (CML) and is observed in more than 90% of CML cases. At diagnosis, in 5-10% of CML patients the Ph chromosome is derived from variant translocations other than the standard t(9;22). Deletions adjacent to the translocation junction on the derivative chromosome 9 were recently described by different groups. The deletions may identify a subgroup with a worse prognosis. The presence of similar deletions on the third derivative other than the 9 and 22 chromosomes in CML with variant translocation has never been investigated. We studied three cases of CML variants showing relatively large deletions on the third chromosome involved in the translocation. Known tumor-suppressor genes (TSGs) or genes involved in signal transduction and in the modulation of cell proliferation were found to be located inside these deleted regions. As an alternative to Knudson's two-hit model, the "haplo-insufficiency" hypothesis suggests that the deletion of a single allele of a TSG can play an important role in tumor progression. Our findings suggest that great attention should be paid to the molecular cytogenetic characterization of variant t(9;22) CML patients to unveil fully the biological heterogeneity of CML.

Fluorescence in situ hybridization (FISH) on human chromosomes using photoprobe biotin-labeled probes

Fluorescence in situ hybridization (FISH) on human chromosomes in meta- and interphase is a well-established technique in clinical and tumor cytogenetics and for studies of evolution and interphase architecture. Many different protocols for labeling the DNA probes used for FISH have been published. Here we describe for the first time the successful use of Photoprobe biotin-labeled DNA probes in FISH experiments. Yeast artificial chromosome (YAC) and whole chromosome painting (wcp) probes were tested.

Molecular cytogenetic detection of chromosomal breakpoints in T-cell receptor gene loci

Chromosomal aberrations with breakpoints in T-cell receptor (TCR) gene loci are recurrent in several T-cell malignancies. Although the importance of interphase cytogenetics has been extensively shown in B-cell lymphomas, hardly any molecular cytogenetic tools are available for recurrent changes in T-cell disorders. Thus, we have established fluorescence in situ hybridization (FISH)-based break-apart assays for the TCRA/D (14q11), TCRB (7q34) and TCRG (7p14) genes and the TCL cluster (14q32). The assays were validated in normal controls as well as in 43 T-cell malignancies with cytogenetically proven 14q11, 7q34-35 or 7p13-21 aberrations. Breakpoints in TCRA/D, TCRB and TCRG could be diagnosed by these assays in 32/33 T-cell neoplasms with chromosome 14q11, 3/6 with 7q34-35 and 1/7 with 7p13-21 alterations, respectively. Application of the new FISH assays to a series of 24 angioimmunoblastic and 12 cutaneous T-cell lymphomas confirmed the cytogenetic evidence of lack of breakpoints in the TCRA/D or TCRB locus. Simultaneous detection of TCRA/D or TCRB breaks was achieved in a multicolor approach, which was further combined with detection of the T-cell-specific CD3 antigen in a multicolor FICTION (Fluorescence Immunophenotyping and Interphase Cytogenetics as a Tool for the Investigation of Neoplasm) assay. These new FISH and FICTION assays provide sensitive, rapid and accurate tools for the diagnosis and biological characterization of T-cell malignancies.

Characterization of the recurrent translocation t(1;1)(p36.3;q21.1-2) in non-Hodgkin lymphoma by multicolor banding and fluorescence in situ hybridization analysis

Aberrations of chromosomal bands 1p36 and 1q11-q23 are among the most common chromosomal alterations in non-Hodgkin lymphoma (NHL). In this study, 16 cases of NHL showing recurrent unbalanced translocation t(1;1)(p36;q11-23) by G-band analysis were selected for further analysis. To delineate the exact breakpoints, multicolor band analysis for chromosome 1 (M-BAND1), and locus-specific fluorescence in situ hybridization (LS-FISH) using human genome designated BAC clones were performed. In all but one dicentric case, the breakpoint was determined to involve chromosomal bands 1p36.3 and 1q21.1-2. LS-FISH analysis for the TP73, MEL1, SKI, and CASP9 loci at 1p36, and the loci IRTA1, IRTA2, BCL9, AF1Q, JTB, and MUC1 at 1q21, verified the MBAND1 results and further delineated the breakpoints. In band 1p36, two hybridization patterns were observed, one involving deletions of MEL1, TP73, and SKI, but not CASP9, and the second involving a breakpoint telomeric to TP73. In region 1q21, four hybridization patterns were observed, the first involving duplication/translocation of all five genes; the second involving duplication/translocation of BCL9, AF1Q, JTB, and MUC1; the third involving duplication/translocation of AF1Q, JTB, and MUC1; and the fourth with a breakpoint telomeric to MUC1. Using an alpha-satellite probe for chromosome 1 (D1Z5), centromeric involvement in the unbalanced translocation t(1;1)(p36.3;q21.1-2) was excluded in all but the one dicentric case, that is, dic(1;1)(p36.3;q10). In conclusion, deletion of 1p36 and duplication of 1q21 through formation of an unbalanced translocation t(1;1)(p36.3;q21.1-2) is a non-random event in NHL, suggesting a deletion-duplication mechanism involved in lymphoma progression and justifying further systematic research.

Generation of chromosome paints: approach for increasing specificity and intensity of signals

Chromosome painting is a widely used technique, and the two principal means of generating probes for such experiments involve DNA isolation by chromosome flow sorting and by chromosome microdissection. Frequently, chromosome paints are bright and specific; however, on occasion, signals can be weak and nonspecific, particularly for microdissected probes. Reasons for this have been attributed to co-amplification of non-target DNA and the formation of primer concatamers during degenerate oligonucleotide primed (DOP)-PCR. Here we describe a technique of circumventing this problem by sequence enrichment. It involves co-hybridization of DOP-PCR biotinylated microdissected material and linkered genomic DNA. Biotinylated DNA fragments captured on streptavidin-coated paramagnetic beads are eluted and amplified by PCR using a single primer complementary to the linker arm.