Small marker chromosome identification in metaphase and interphase using centromeric multiplex fish (CM-FISH)

Multicolor karyotyping procedures, such as multiplex fluorescence in situ hybridization (M-FISH), spectral karyotyping, or color-changing karyotyping, can be used to detect chromosomal rearrangements and marker chromosomes in prenatal diagnosis, peripheral blood cultures, leukemia, and solid tumors, especially in cases where G-banding is not sufficient. A regular M-FISH analysis requires relatively large amounts of labeled DNA (microgram quantities), is not informative in interphase nuclei, hybridization can take up to 2 to 3 days, and unlabeled human chromosome-painting probes are not available commercially. Unique probes (plasmids, PAC), specific for centromeric or subtelomeric chromosomal regions, can replace the painting probes in M-FISH to address specific issues, such as the identification of marker chromosomes and aneuploidies. A set of plasmid probes carrying repetitive sequences specific for the alpha-satellite region of all human chromosomes were combined in a metaphase assay and an interphase assay, allowing identification of aneuploidies in one hybridization step, on a single cytogenetic slide. The fluorophore-dUTP and the labeled antibodies required to label and detect the DNA probes can be prepared in any laboratory. All DNA probes can be easily isolated and labeled using common molecular cytogenetic procedures. Because of the repetitive nature of the probes, hybridization time is short, usually less than 1 hour, and the analysis can be performed with nonspecialized image-processing software.     

Multiplex fluorescence in situ hybridization and cross species color banding of a case of chronic myeloid leukemia in blastic crisis with a complex Philadelphia translocation

Exciting new techniques in molecular cytogenetics--namely, spectral karyotyping, multiplex fluorescence in situ hybridization (M-FISH), and cross species color banding--have been recently developed. An increasing number of reports demonstrate the success of these procedures in providing additional cytogenetic information--identifying marker chromosomes and revealing the presence of previously undetected chromosomal changes. However, these procedures have their limitations, and their absolute sensitivity in the accurate identification of subtle chromosomal abnormalities remains to be established. M-FISH and color banding have been applied to a case of chronic myeloid leukemia with a complex Philadelphia translocation involving chromosomes 9, 17, and 22, which had initially been identified from G-banded chromosome analysis. The abnormalities were confirmed by chromosome "painting" and specific probes. Although M-FISH and color banding revealed no additional cryptic chromosomal changes, this study has clearly demonstrated the success of these multiple color FISH approaches in the accurate characterization of a complex rearrangement with subtle abnormalities.     

Tpp1/Acd maintains genomic stability through a complex role in telomere protection

Telomeres serve to protect the ends of chromosomes, and failure to maintain telomeres can lead to dramatic genomic instability. Human TPP1 was identified as a protein which interacts with components of a telomere cap complex, but does not directly bind to telomeric DNA. While biochemical interactions indicate a function in telomere biology, much remains to be learned regarding the roles of TPP1 in vivo. We previously reported the positional cloning of the gene responsible for the adrenocortical dysplasia (acd) mouse phenotype, which revealed a mutation in the mouse homologue encoding TPP1. We find that cells from homozygous acd mice harbor chromosomes fused at telomere sequences, demonstrating a role in telomere protection in vivo. Surprisingly, our studies also reveal fusions and radial structures lacking internal telomere sequences, which are not anticipated from a simple deficiency in telomere protection. Employing spectral karyotyping and telomere FISH in a combined approach, we have uncovered a striking pattern; fusions with telomeric sequences involve nonhomologous chromosomes while those lacking telomeric sequences involve homologues. Together, these studies show that Tpp1/Acd plays a vital role in telomere protection, but likely has additional functions yet to be defined.     

Towards unlimited colors for fluorescence in-situ hybridization (FISH)

We describe a FISH protocol that allows rehybridization of complex DNA probes up to four times to the same specimen. This strategy, which we termed ReFISH, opens a wide range of new applications to conventional band pass filter epifluorescence microscopy. These include M-FISH karyotyping and cross-species color banding that emulate multiplex probe sets labeled with up to 12 fluorochromes in sequential hybridizations to the same specimen. We designed a human 24-color karyotyping probe set in combination with a 29-color cross-species color banding probe set using gibbon painting probes. Applying the ReFISH principle, 53 painting probes on individual metaphases were discriminated. This allowed simultaneous screening for inter- and intrachromosomal rearrangements on normal human diploid cells, a HeLa derived cell line, and highly rearranged gibbon chromosomes. Furthermore, the present ReFISH experiments successfully combine 24-color FISH with laser scanning confocal microscopy to study the 3D organization of all 46 human chromosome territories in individual interphase cell nuclei.     

Cytogenetic and molecular biological characterization of an adult medulloblastoma

Medulloblastoma is a malignant invasive embryonal tumor, occurring in children mainly. It is rare in adults (<1% of adult brain tumors), and so comprehensive cytogenetic and molecular biological data on adult medulloblastomas are very limited. Conventional therapies provide disappointing long-term disease control, and new therapeutic options are being tested. We performed comprehensive cytogenetic analyses of an adult medulloblastoma, WHO grade IV, using trypsin-Giemsa staining (GTG-banding), multicolor fluorescence in situ hybridization (M-FISH), and locus-specific FISH, complemented by molecular karyotyping using high-density single nucleotide polymorphism (SNP) arrays. GTG-banding of 25 metaphases revealed 31 structural chromosomal aberrations, predominantly located on chromosomes 4q, 9q, 10q, 11p, and 20q, which were confirmed by M-FISH. Two novel, so far not described translocations were found: t(4;11)(q25;p15) and t(9;20)(p23;p12). GTG-banding, locus-specific FISH, and M-FISH detected numerical changes of chromosomes 8, 14, 18, 19, 20, 21, and 22. Molecular karyotyping by SNP array confirmed chromosomal changes -2p, -10q, -16q, and -Xq and revealed de novo partial uniparental disomy 1q and 9q. Applying an upcoming therapeutic approach, we found that primary medulloblastoma cells were resistant to TRAIL, a novel anticancer cytokine, but could be efficiently sensitized by cotreatment with the proteasome inhibitor bortezomib. Bortezomib-TRAIL cotreatment may serve as a powerful therapeutic option for medulloblastoma patients.     

Combined PI–DAPI staining (CPD) reveals NOR asymmetry and facilitates karyotyping of plant chromosomes

This paper presents a preparative and staining procedure for plant mitotic chromosomes that uses a combination of PI (propidium iodide) and DAPI (4′,6-diamidino-2-phenylindol) and which reveals a pattern of high-affinity regions for these fluorochromes. Nucleolar organiser regions (NORs), telomeres and centromeric regions exhibit high PI affinity (red), whereas other chromosomal regions exhibit high affinity for either PI (red) or DAPI (blue). NOR-bearing and other chromosomes are readily distinguished, facilitating karyotyping. The dual staining pattern was observed in all the plants tested. Aspects of NOR size, number and occurrence are discussed. A karyotype of rice metaphase chromosomes is presented, based on their fluorescent banding patterns. This revised version was published online in July 2006 with corrections to the Cover Date.     

Multicolor karyotyping and clinicopathological analysis of three intravascular lymphoma cases.

Intravascular lymphoma (IVL) is a rare neoplastic disease characterized by the presence of large malignant lymphoid cells in small vessels. It is often diagnosed at autopsy. Clinical manifestations are typically neurologic and dermatologic. Karyotypic abnormalities have been described in a small number of cases and have revealed complex alterations in the majority of cases. We have identified three cases of IVL with varied clinicopathological findings. Karyotypic analysis was undertaken by standard G-banding and supplemented by multi-colored karyotyping (M-FISH) to decipher the chromosomal content of marker chromosomes and undefined additions. M-FISH clarified the chromosomal abnormalities in two cases and unveiled cryptic translocations der(10)t(10;22), der(17)t(17;22), and balanced t(11;14). Comparison with previously published karyotypes revealed prominent involvement of chromosomes 1, 3, 6, 11, 14, and 18, similar to the pattern of clonal evolution in other B-cell lymphomas. The most frequent alterations seen were -6 or 6q- and +18 or dup(18q), with a minimally deleted region located at 6q21-q23 and a commonly amplified region located at 18q13-q23, respectively. Few differences between the classical and Asian variant of this disease were apparent at the karyotypic level. Cytogenetic analysis of additional cases supplemented by multicolor karyotyping may help identify the full spectrum of genetic alterations associated with IVL and assist in the delineation of the critical mutations associated with initiation and progression of this disease.     

Comprehensive cytogenetic characterization of an esthesioneuroblastoma

Esthesioneuroblastoma is a malignant neuroectodermal tumor originating from olfactory epithelial cells in the nasal vault. Due to the rarity of this tumor entity, cytogenetic data are very limited. Therefore, we performed comprehensive cytogenetic analyses of an esthesioneuroblastoma, Hyam's grade III-IV, using trypsin-Giemsa staining (GTG banding), multicolor fluorescence in situ hybridization (M-FISH), and locus-specific FISH complemented by molecular karyotyping using high-density single nucleotide polymorphism arrays. GTG banding of 25 metaphases revealed 54 structural intrachromosomal aberrations, predominantly located on 2q, 6q, 21q, and 22q, which were confirmed by FISH analysis. Interestingly, we found two novel, so far not described deletions, del(2)(q37) and del(21)(q22). Using GTG banding, locus-specific FISH, and M-FISH, we detected numeric changes of chromosomes 5, 17, 19, and 22, as well as trisomy 8 at low frequency. Applying SNP array karyotyping, we confirmed the chromosomal aberrations del(2)(q37.3), del(3)(q27.2), del(10)(q26.11), chromosomal imbalance on 17q, del(21)(q22), and revealed a number of so far unknown aberrations (gain of 2q14.3, 13q33.3, and 13q34). While the cytogenetically revealed low frequency mosaic del(6)(q22q24) was not visible using SNP array karyotyping, some of the smaller imbalances (SNP array data) could not have been detected by classic cytogenetic analysis. Therefore, our study supports the usefulness of applying complementary methods for cytogenetic analysis.     

Transformation of Sordaria macrospora to hygromycin B resistance: characterization of transformants by electrophoretic karyotyping and tetrad analysis

The ascomycete Sordaria macrospora was transformed using different plasmid molecules containing the bacterial hygromycin B resistance gene (hph) under the control of different expression signals. The highest transformation frequency was obtained with vector pMW1. On this plasmid molecule, expression of the hph gene is directed by the upstream region of the isopenicillin N synthetase gene (pcbC) from the deuteromycete Acremonium chrysogenum. Southern analysis suggests that the vector copies are integrated as tandem repeats into the S. macrospora chromosomes and that duplicated sequences are most probably not inactivated by methylation during meiosis. Furthermore, the hygromycin B resistance (hygR) is not correlated with the number of integrated vector molecules. Electrophoretic karyotyping was used to further characterize S. marcospora transformants. Five chromosomal bands were separated by pulsed-field gel electrophoresis (PFGE) representing seven chromosomes with a total genome size of 39.5 Mb. Hybridization analysis revealed ectopic integration of vector DNA into different chromosomes. In a few transformants, major rearrangements were detected. Transformants were sexually propagated to analyze the fate of the heterologous vector DNA. Although the hygR phenotype is stably maintained during mitosis, about a third of all lines tested showed loss of the resistance marker gene after meiosis. However, as was concluded from electrophoretic karyotyping, the resistant spores showed a Mendelian segregation of the integrated vector molecules in at least three consecutive generations. Our data indicate that heterologous marker genes can be used for transformation tagging, or the molecular mapping of chromosomal loci in S. macrospora     

Synaptonemal complex karyotyping: an appraisal based on a study ofCrepis capillaris

A synaptonemal complex (SC) karyotype forCrepis capillaris, based on SC measurements from 92 surface-spread pachytene nuclei, was compared with the mitotic karyotype of this species in order to evaluate the specific and general validity of SC karyotyping and to assess its potential for high resolution physical mapping. Although there are obvious similarities between the SC and mitotic karyotypes ofCrepis capillaris, detailed quantitative comparisons reveal that they differ in some respects, both with regard to the relative lengths of entire chromosomes and arm ratios. The arm ratio differences between SC and mitotic chromosomes are evident in both the A and C chromosomes and reflect the distribution of C-banding heterochromatin. Based on this comparison, heterochromatin appears to be underrepresented in SC length. However, the relative lengths of entire A and C chromosome SCs do not conform to this model and suggest that some other factor or factors are also influencing SC lengths differentially. It is concluded that the non-agreement of SC and mitotic karyotypes does not invalidate the use of SCs for karyotyping and physical mapping purposes provided that any differences are understood and characterized as far as possible.     

多重荧光原位杂交结合染色体涂抹技术检测骨髓增生异常综合征复杂核型异常

目的探讨多重荧光原位杂交(multiplex fluorescence in situ hybridization,M-FISH)及全染色体涂抹(whole chromosome painting,WCP)技术在骨髓增生异常综合征(myelodysplastic syndromes,MDS)复杂核型异常检测中的价值。方法对7例常规R显带具有复杂染色体异常的MDS患者应用M-FISH技术确定复杂染色体的重排及标记染色体的组成,识别微小易位。并进一步采用双色WCP技术验证M-FISH检测的结果。结果M-FISH不仅证实了R显带的结果,而且确定了R带核型分析没有确定的6种标记染色体、9种有不明来源的额外物质增加的染色体、5种衍生染色体的组成和来源及4种被忽略的微小易位。涉及17号染色体的异常及-5/5q-是MDS最为常见的两种染色体异常。WCP技术纠正了一些M-FISH漏检及误检的异常。结论M-FISH是明确复杂染色体异常的很有用的分子生物学工具,WCP是M-FISH技术的重要补充,R带核型分析结合分子细胞遗传学工具M-FISH和WCP可以更加准确地描述复杂染色体异常。     

Molecular cytogenetic characterization of the mouse cell line WMP2 by spectral karyotyping and multicolor banding applying murine probes

The Moloney murine leukemia virus-transformed suspension cell line WMP2 is derived from wild mice (Mus musculus) of the WMP/WMP strain. These mice carry nine pairs of metacentric Robertsonian translocation chromosomes. As the chromosomes of the wild-type mouse are all acrocentric, metaphase spreads of the WMP2 cells seam to be highly suited for physical gene mapping. Here we studied the WMP2 line using spectral karyotyping (SKY) combined with new established mouse specific multicolor banding (mcb) probes for the chromosomes X, 3, 4, 6 and 18. SKY revealed that the WMP2 cell line developed further four derivative chromosomes. After application of mcb five previously unrecognizable intrachromosomal rearrangements with 9 breakpoints were detected for the studied chromosomes.     

An XX/XY sex microchromosome system in a freshwater turtle, Chelodina longicollis (Testudines: Chelidae) with genetic sex determination

Heteromorphic sex chromosomes are rare in turtles, having been described in only four species. Like many turtle species, the Australian freshwater turtle Chelodina longicollis has genetic sex determination, but no distinguishable (heteromorphic) sex chromosomes were identified in a previous karyotyping study. We used comparative genomic hybridization (CGH) to show that C. longicollis has an XX/XY system of chromosomal sex determination, involving a pair of microchromosomes. C-banding and reverse fluorescent staining also distinguished microchromosomes with different banding patterns in males and females in ∼70% cells examined. GTG-banding did not reveal any heteromorphic chromosomes, and no replication asynchrony on the X or Y microchromosomes was observed using replication banding. We conclude that there is a very small sequence difference between X and Y chromosomes in this species, a difference that is consistently detectable only by high-resolution molecular cytogenetic techniques, such as CGH. This is the first time a pair of microchromosomes has been identified as the sex chromosomes in a turtle species.     

An exceptional complex chromosomal rearrangement (CCR) with eight breakpoints involving four chromosomes (1;3;9;14) in an azoospermic male with normal phenotype

A 27-year-old man was referred for chromosome analysis due to infertility caused by azoospermia. Chromosome analysis by conventional karyotyping, multicolour FISH (M-FISH) and multicolour banding (MCB) analysis revealed an apparently balanced translocation between chromosomes 1, 3, 9 and 14 as well as an additional inverted insertion of 3q material with a total of eight breakpoints. Due to the diversity of theoretically unbalanced products of meiotic recombination in this exceptional complex chromosomal rearrangement a successful result of assisted reproduction seems unlikely.     

Analysis of marker or complex chromosomal rearrangements present in pre- and post-natal karyotypes utilizing a combination of G-banding,spectral karyotyping and fluorescence in situ hybridization

The significance of complex chromosomal rearrangements presents a diagnostic dilemma. In the past, the use of G-banding coupled with fluorescence in situ hybridization (FISH) has been the standard approach. The recent development of spectral karyotyping (SKY) and multicolor FISH (M-FISH) has resulted in an increased accuracy of identification of marker or other complex chromosomal rearrangements. However, owing to the additional cost and time associated with SKY or M-FISH, and the restricted availability of such imaging facilities in many centers, it is not feasible to perform these procedures routinely on every sample. In addition, the identification of an aberration by SKY or M-FISH will often require confirmation by FISH. A practical approach is needed to take advantage of the complementary strengths of each method. In our center we utilize an algorithm that dictates the use of routine G-banding for the initial preliminary evaluation of a patient, followed by SKY characterization if marker chromosomes or complex translocations are detected by the G-banding analysis. According to this algorithm, FISH is used to verify the results once the origin of the abnormal chromosome has been determined by SKY. To demonstrate the effectiveness of this algorithm, we have analyzed both amniocyte and lymphocyte slides, using a combination of G-banding, SKY, and FISH. Our results confirm that an algorithm which selectively uses SKY or M-FISH will provide an efficient and improved method for pre- and post-natal chromosomal analysis.     

Genomic comparisons among parental and fusant strains of Candida shehatae and Pichia stipitis

DNA-DNA binding experiments on selected fusants of Candida shehatae and Pichia stipitis showed that the nucleus of these strains was composed predominantly of Pichia DNA. Electrophoretic karyotyping revealed that the fusants contained four chromosomes, similar to those found in the Pichia parental strain. In addition, the fusants showed only marginal increases in cell DNA content when compared with the parents. Karyogamy was confirmed, however, by the isolation of recombinant phenotypic segregants, induced by meiotic and mitotic segregation. The results suggest that the fusion led to integration of Candida genes, rather than whole chromosomes, with the entire genome of P. stipitis.     

Early Phase Karyotype Analysis of Chromosome Segregation After Formation of Mouse–Mouse Hybridomas with Chromosome Painting Probes

FISH analysis with chromosome painting probes allows, better than karyotyping after Giemsa banding, the study of chromosome segregation after hybridoma formation. FISH is particularly useful for intraspecies hybrids and allows visualization of small chromosome fragments. Cell hybrids were constructed between P3 × 63Ag8.653 mouse myeloma cells and lymphocytes from BALB/c mice by PEG fusion and by selection in hypoxanthine–azaserine medium. Three hybridomas (A4, D8, F10) were selected and, after cloning, the cells were cultivated in vitro over a period of 28 days. During this time in culture, air-dried metaphase spreads were prepared by standard methods. For FISH chromosome painting, digoxigenin- and biotin-labeled mouse chromosome painting probes and rhodamine–antidigoxigenin antibodies and fluorescein–avidin were used for dual color detection. Total chromosome numbers and the numbers of mouse chromosomes 1, X, 6 and 12 were estimated as function of days in culture. Mean chromosome numbers of 78 (D8), 82 (F10) and 150 (A4) were observed. The major rearrangements of chromosome numbers occured in the first 28 days in culture and did not change significantly between day 28 and day 56. Mouse chromosome #12, which had the largest chromosome fragments in the parent myeloma, remained stable while the number of X chromosomes, which were significantly fragmented already in the parent myeloma, decreased by approximately 50%.     

Spontaneous chromosomal aberrations in oogenesis of laboratory rats

Of 861 oocytes with chromosomes suitable for karyotyping and accurate counting, 797 (92.7%) had the normal number of chromosomes, 64 (7.5%) had aneuploidy, four (0.4%) hyperploidy, and in the remaining 60 there was a deficiency of chromosomes (hypoploidy). Hypoploidy was often caused by artefacts. The percentage of spontaneous aneuploidy in rat oogenesis is evidently about 0.8, much lower than the percentage of spontaneous aneuploidy in mouse oogenesis.     

Preparation of chromosomes from plant leaf meristems for karyotype analysis and in situ hybridization

A reliable method for preparing metaphase chromosomes from plant leaf tissues is described. The chromosomes are suitable for karyotype analysis and gene mapping by fluorescence in situ hybridisation (FISH). The method is based on enzymatic digestion of young leaf tissues (shoot-tips) after which the resulting protoplasts are treated hypotonically before being dropped onto microscopic slides. Compared to root-tip chromosomes, leaf chromosomes tend to be longer, or less condensed, and hence more karyotypically differentiated. Metaphase index in young leaf tissues is also very high. Metaphase spread consists of evenly and well-distributed chromosomes and this allows accurate counting. The plant used to demonstrate this method is birch (Betula L.), a group of tree species that has extremely small chromosomes. Root-tip chromosomes of these plants are difficult to obtain, as cutting does not produce roots readily. Seedling chromosomes do not represent the same genomic constitution as their mother trees due to introgressive hybridisation. Furthermore, sample collection in the field is convenient and actively growing leaf buds are available throughout the growing season. FISH experiments with these leaf chromosomes also give good results comparable to those obtained with root-tip chromosomes or even better as mapping on long or extended chromosomes has high resolution in general. Mapping of the 16S–28S ribosomal genes on birch leaf chromosomes has been shown to differentiate between birch species and therefore can accurately confirm their interspecific hybrids.