Diagnosis of four chromosome abnormalities of unknown origin by chromosome microdissection and subsequent reverse and forward painting

A molecular cytogenetic method consisting of chromosome microdissection and subsequent reverse/forward chromosome painting is a powerful tool to identify chromosome abnormalities of unknown origin. We present 4 cases of chromosome structural abnormalities whose origins were ascertained by this method. In one MCA/MR patient with an add(5q)chromosome, fluorescence in situ hybridization (FISH), using probes generated from a microdissected additional segment of the add(5q) chromosome and then from a distal region of normal chromosome 5, confirmed that the patient had a tandem duplication for a 5q35-qter segment. Similarly, we ascertained that an additional segment of an add(3p) chromosome in another MCA/MR patient had been derived from a 7q32-qter segment. In a woman with a history of successive spontaneous abortions and with a minute marker chromosome, painting using microdissected probes from the whole marker chromosome revealed that it was i(15)(p10) or psu dic(15;15)(q11;q11). Likewise, a marker observed in a fetus was a ring chromosome derived from the paracentromeric region of chromosome 19. We emphasize the value of the microdissection-based chromosome painting method in the identification of unknown chromosomes, especially for marker chromosomes. The method may contribute to a collection of data among patients with similar or identical chromosome abnormalities, which may lead to a better clinical syndrome delineation. © 1996 Wiley-Liss, Inc.     

Generation of Chromosome Painting Probes from Single Chromosomes by Laser Microdissection and Linker-Adaptor PCR

Fluorescence in situ hybridization (FISH) plays an essential role in research and clinical diagnostics. The versatility and resolution of FISH depends critically on the probe set used. Here, we describe an improved approach for the generation of specific DNA probes from single copies of chromosomes. Single chromosomes or single chromosomal regions were microdissected by laser pressure catapulting and amplified using linker-adaptor PCR. The probes were labeled and tested in various scenarios including multicolor-FISH experiments employing up to seven different fluorochromes. FISH confirmed the specific and even staining of the respective chromosomal regions. Furthermore, the capability of these probes to detect even small translocations (<3 Mb) suggests that the dissected regions are completely represented in the generated painting probes.     

Chromosomal polymorphism and comparative painting analysis in the zebra finch

The zebra finch (Taeniopygia guttata) is often studied because of its interesting behaviour and neurobiology. Genetic information on this species has been lacking, making analysis of informative mutants difficult. Here we report on an improved cytological method for preparation of metaphase chromosomes suitable for fluorescent in situ hybridization of adult birds. We found that individual chicken chromosome paints usually hybridized to single zebra finch chromosomes, indicating only minor chromosomal rearrangements since the evolutionary divergence of these two species, and suggesting that the genomic location of chicken genes will predict the location of zebra finch orthologues. Chicken chromosome 1 appears to have split into two macrochromosomes in zebra finches, and chicken chromosome 4 paint hybridizes to a zebra finch macrochromosome and a microchromosome. This pattern was confirmed by mapping the androgen receptor (AR), which is located on chicken chromosome 4 but on a zebra finch microchromosome. We detected a telocentric/submetacentric polymorphism of chromosome 6 in our colony of zebra finches, and found that the polymorphism was inherited in a Mendelian pattern     

Highly comprehensive karyotype analysis by a combination of spectral karyotyping (SKY), microdissection, and reverse painting (SKY-MD)

A technique disclosing most information about chromosome modifications is the technique of choice for the analysis of chromosome alterations. The newly developed method for microdissection of fluorescence-labeled chromosomes (FISH-MD) can improve upon this expectation in combination with 24-color spectral karyotyping (SKY). The highly efficient way to detect chromosome modifications by SKY and the detailed specification of aberrant chromosomes by FISH-MD prompted us to use both techniques in a combined approach called SKY-MD. First, an overview of chromosomal aberrations is obtained by spectral karyotyping and subsequently the derivative chromosomes recognized are characterized in a highly specific manner by microdissection and reverse painting. A small quantity of isolated material dissected directly from a 24-color metaphase is sufficient to obtain very detailed information about the chromosome regions and the breakpoints involved in the derivative chromosomes. Therefore, the combination of spectral karyotyping and microdissection in one procedure, and reverse painting can characterize chromosomal aberrations with a degree of specificity hitherto unknown from individual karyotyping experiments. In this article we compare the efficiency of both the SKY technique and that of classical microdissection with the efficiency obtained by SKY-MD.     

Maternal balanced translocation leading to partial duplication of 4q and partial deletion of 1p in a son: Cytogenetic and FISH studies using band-specific painting probes generated by chromosome microdissection

A 9-month-old boy with pre- and post-natal growth retardation, microcephaly, plagiocephaly, and several minor anomalies had the initial karyotype: 46,XY,der(1)t(1;?)(p36.1;?). Further analysis showed that the der(1) was derived from an unfavorable segregation of a maternal complex chromosome rearrangement, i.e., 46,XX,der(1)t(1;?)(p36.1;?), der(4)t(4;?)(q?;?). Whole chromosome fluorescence in situ hybridization (FISH) and chromosome microdissection were used to clarify the maternal karyotype as: 46,XX,der(1)t(1;4)(4qter→4q33::1p36.13→1qter),der(4)t(1;4)inv(4)(4pter→ 4q31.3::1p36.33→1p36.13::4q33→4q31.3::1p36.33→1pter). Therefore, the karyotype of the boy actually was 46,XY,der(1)t(1;4)(p36.13;q33). Clinical comparison of the patient's clinical findings showed similarities to individuals with partial del(1p) and dup(4q). To our knowledge the above cytogenetic abnormalities have not been described previously. This case further demonstrates the advantages of chromosome microdissection and FISH in the identification of anomalous chromosome regions and breakpoints. Am. J. Med. Genet. 71:160–166, 1997. © 1997 Wiley-Liss, Inc.     

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.     

Microdissection and chromosome painting of X and B chromosomes in Locusta migratoria

Acquisition of knowledge of the nature and DNA content of B chromosomes has been triggered by a collection of molecular techniques, one of which, microdissection, has provided interesting results in a number of B chromosome systems. Here we provide the first data on the molecular composition of B chromosomes in Locusta migratoria, after microdissection of the B and X chromosomes, DNA amplification by one (B) or two (X) different methods, and chromosome painting. The results showed that B chromosomes share at least two types of repetitive DNA sequences with the A chromosomes, suggesting that Bs in this species most likely arose intraspecifically. One of these repetitive DNAs is located on the heterochromatic distal half of the B chromosome and in the pericentromeric regions of about half of the A chromosomes, including the X. The other type of repetitive DNA is located interspersedly over the non-centromeric euchromatic regions of all A chromosomes and in an interstitial part of the proximal euchromatic half of the B chromosome. Chromosome painting, however, did not provide results sufficiently reliable to determine, in this species, which A chromosome gave rise to the B; this might be done by detailed analysis of the microdissected DNA sequences     

Construction of chromosome-specific paints for meta- and submetacentric autosomes and the sex chromosomes in the horse and their use to detect homologous chromosomal segments in the donkey

A pilot study comparing horse and donkey karyotypes on a molecular basis was initiated using the chromosomal microdissection approach. All equine meta- and submetacentric chromosomes, viz. ECA1 to ECA13 and the X and Y chromosomes, were microdissected. The DNA was PCR amplified, non-radioactively labelled and used as probes on equine metaphase chromosomes to confirm their origin. Once tested, the paints were used as probes on donkey metaphase chromosomes to detect homologous chromosomal segments between the two species. The results not only detected conservation of whole chromosome and/or arm synteny between the two karyotypes, but also highlighted varying degrees of rearrangements. The findings also enable deduction of homology between parts of donkey and human karyotypes. In light of the molecular evidence, this study examines the accuracy of the available comparative cytogenetic data between horse and donkey. This revised version was published online in July 2006 with corrections to the Cover Date.     

Simultaneous detection of centromere-specific probes and chromosome painting libraries by a combination of primedin situ labelling and chromosome painting (PRINS-painting)

In situ techniques for the detection of specific chromosomes using centromeric probes and the decoration of entire chromosomes using chromosome painting are well established. However, in the deciphering of complex chromosomal aberrations it is valuable to be able to detect the centromere and the entire DNA of a specific chromosome in different colours simultaneously on the same metaphase. In this report we describe a combination of the primedin situ labelling (PRINS) technique and chromosome painting for simultaneous visualization of centromere-specific oligonucleotides and chromosome painting libraries. A key feature is that the denaturation step in the PRINS reaction is sufficient to keep the chromosomes denatured for chromosome painting. This means that PRINS and consecutive chromosome painting can be performed as a single procedure (PRINS-painting)     

Chromosome studies of European cyprinid fishes: interspecific homology of leuciscine cytotaxonomic marker—the largest subtelocentric chromosome pair as revealed by cross-species painting

Leuciscine cyprinids possess a nearly invariant diploid number (2n = 50) with an extremely uniform karyotype comprising of 8 pairs of metacentric, 13-15 pairs of submetacentric and 2-4 pairs of subtelocentric (st) to acrocentric (a) chromosomes. The largest pair is characteristically an st/a element-the 'leuciscine' cytotaxonomic marker. Previously, the interspecific homology of this chromosome pair could not be assessed owing to the inability to produce euchromatic or serial banding patterns. In the present study, we used laser-microdissection (15-20 copies of the marker chromosome) to construct a whole chromosome probe (WCP) from the marker chromosome of the roach Rutilus rutilus to ascertain the interspecific homology of marker chromosomes by cross-species in-situ hybridization. WCP was hybridized to chromosomes of widely distributed (Abramis brama, Alburnoides bipunctatus, Alburnus alburnus, Aspius aspius, Ballerus ballerus, B. sapa, Blicca bjoerkna, Chondrostoma nasus, Leucaspius delineatus, Leuciscus leuciscus, L. idus, R. rutilus, Scardinius erythrophthalmus, Squalius cephalus, and Vimba vimba) and Iberian endemic species (Achondrostoma oligolepis, Iberochondrostoma almacai, I. lusitanicum, Pseudochondrostoma duriense, S. alburnoides and S. pyrenaicus). Cross-species in-situ hybridization to chromosomes of Phoxinus phoxinus, a representative of leuciscine sister lineage, showed the same pattern as in all of the leuciscins. The probe consistently hybridized to the distal part of the short arm of the marker chromosome, indicating sequence homology.     

全染色体涂抹探针在女性罗伯逊易位携带者植入前遗传学诊断中的临床应用

目的应用全染色体涂抹探针（whole chromosome painting probe，WCP）对女性罗伯逊易位携带者进行卵母细胞第一极体的植入前遗传学诊断（preimplantation genetic diagnosis，PGD）。方法应用全染色体涂抹探针进行第一极体荧光原位杂交，对4例女方罗伯逊易位携带者进行了4个周期的PGD。患者染色体核型均为45，XX，der（13；14），（q10；q10）。所有周期取卵后6h内通过活检取出第一极体，采用WCP探针进行荧光原位杂交，受精后第3天选择染色体组成正常或平衡的胚胎进行宫腔内移植。结果4个周期共获卵61个，其中54个成熟可进行活检，活检成功率92．6％（50／54），固定成功率90．O％（45／50）。40个获得明确诊断，总体诊断率为74．1％（40／54）。卵胞浆内单精子注射后受精率64．8％（35／54），优质胚胎率为65．7％（23／35）。获得2例临床妊娠。其中1例于孕9周胚胎停止发育，绒毛染色体分析核型为45，X；另1例产前诊断证实核型为46，XX。2006年6月足月分娩一正常活女婴。结论全染色体涂抹探针可准确区分正常、平衡以及异常卵子，从而可有效应用于女性染色体易位携带者的PGD。     

Characterization of a de novo unbalanced translocation t(14q18q) using microdissection and fluorescence in situ hybridization

We report on a patient with a de novo translocation between the long arms of chromosomes 14 and 18. The translocation was studied using microdissection in combination with fluorescence in situ hybridization (micro-FISH). Five copies of the chromosomes involved in the translocation were isolated by microdissection and amplified by means of degenerate oligonucleotide primed-polymerase chain reaction (DOP-PCR). Reverse chromosome painting with the biotin-labeled PCR product showed that part of the q-arm of chromosome 18 had no signal. The deletion was characterized further by FISH with band-specific probes and it was concluded that the rearrangement was unbalanced: 46,XY,t(14;18)(14pter→4q22::18q21.1→18qter)(18pter→18q12.2::14q22→14qter). The patient, who presented with psychomotor retardation, mild obesity, pes equinovarus, strabismus, and facial anomalies, is compared with previously reported patients with an interstitial deletion of band 18q12. Am. J. Med. Genet. 75:409-413, 1998. © 1998 Wiley-Liss, Inc.     

Reverse painting highlights the origin of chromosome aberrations

Reverse chromosome painting, as the opposite of forward chromosome painting, means that an abnormal chromosome of interest is recovered by flow sorting or by chromosome microdissection, amplified and labelled by DOP-PCR and hybridized onto normal metaphases of optimal quality. This provides rapid and unequivocal information about the chromosomal origin on the aberrant chromosome in one hybridization. Not only will the specific chromosome(s) involved be identified, but also the subchromosomal origin, including the breakpoints. The method has been used for over 10 years and has proven to be very useful for resolving complex chromosome rearrangements in a variety of different applications, both as a research tool and for clinical purposes in pre- and postnatal diagnosis.     

The genome phylogeny of domestic cat, red panda and five mustelid species revealed by comparative chromosome painting and G-banding

Genome-wide homology maps among stone marten (Martes foina, 2n = 38), domestic cat (Felis catus, 2n = 38), American mink (Mustela vison, 2n = 30), yellow-throated marten (Martes flavigula, 2n = 40), Old World badger (Meles meles, 2n = 44), ferret badger (Melogale moschata, 2n = 38) and red panda (Ailurus fulgens, 2n = 36) have been established by cross-species chromosome painting with a complete set of stone marten probes. In total, 18 stone marten autosomal probes reveal 20, 19, 21, 18 and 21 pairs of homologous chromosomal segments in the respective genomes of American mink, yellow-throated marten, Old World badger, ferret badger and red panda. Reciprocal painting between stone marten and cat delineated 21 pairs of homologous segments shared in both stone marten and cat genomes. The chromosomal painting results indicate that most chromosomes of these species are highly conserved and show one-to-one correspondence with stone marten and cat chromosomes or chromosomal arms, and that only a few interchromosomal rearrangements (Robertsonian fusions and fissions) have occurred during species radiation. By comparing the distribution patterns of conserved chromosomal segments in both these species and the putative ancestral carnivore karyotype, we have reconstructed the pathway of karyotype evolution of these species from the putative 2n = 42 ancestral carnivore karyotype. Our results support a close phylogenetic relationship between the red panda and mustelids. The homology data presented in these maps will allow us to transfer the cat gene mapping data to other unmapped carnivore species.     

Detection of deleted mitochondrial DNA in Kearns-Sayre syndrome using laser capture microdissection

A novel 4949-base pair mitochondrial DNA (mtDNA) deletion was detected in various tissues in a postmortem study of a patient with Kearns-Sayre syndrome (KSS). Deleted mtDNA levels were higher in skeletal muscle and brain and lower in kidney, working myocardium, and endocrine tissues (thyroid, parathyroids, pancreas, and adrenal glands). The distribution of the deletion in skeletal muscle and conducting myocardium was analyzed by means of laser capture microdissection (LCM). In skeletal muscle, the abundance of deleted mtDNA was slightly higher in cytochrome c oxidase (COX)-negative fibers (70%) than in COX-positive fibers (64%), whereas in the conducting myocardium it was lower in the atrioventricular node (9%) than in the sinus node and bundle of His (30% and 32%, respectively). In this study, LCM proved to be a reliable technique for a more accurate assessment of genotype/phenotype correlation when investigating mtDNA-related disorders.     

Polymerase chain reaction-based suppression of repetitive sequences in whole chromosome painting probes for FISH

We have developed a method to suppress the PCR amplification of repetitive sequences in whole chromosome painting probes by adding Cot-1 DNA to the amplification mixture. The repetitive sequences in the Cot-1 DNA bind to their homologous sequences in the probe library, prevent the binding of primers, and interfere with extension of the probe sequences, greatly decreasing PCR efficiency selectively across these blocked regions. A second labelling reaction is then done and this product is resuspended in FISH hybridization mixture without further addition of blocking DNA. The hybridization produces little if any non-specific binding on any other chromosomes. We have been able to successfully use this procedure with both human and rat chromosome probes. This technique should be applicable in producing probes for CGH, M-FISH and SKY, as well as reducing the presence of repetitive DNA in genomic libraries     

A fluid cover medium provides superior morphology and preserves RNA integrity in tissue sections for laser microdissection and pressure catapulting

Laser microdissection and pressure catapulting has become a powerful tool to obtain homogeneous cell populations from tissue samples in nearly all fields of biomedical research. The isolated cells can be subsequently used for the analysis of proteins, DNA or RNA. However, the method requires physical access to the tissue surface and the sections therefore need to be air-dried and uncovered. The consequence is poor morphology, which severely reduces the potential of the technique, especially in non-homogeneous tissues or tissues with infiltrating immune cells. To overcome this limitation, a fluid cover medium was developed and the effects on frozen and paraffin wax-embedded tissue morphology were evaluated. The cover medium improved the morphology such that it was almost comparable to sections overlaid with glass coverslips. Moreover, the laser microdissection procedure was facilitated, since the medium allowed larger areas of tissues to be laser pressure-catapulted. Neither the isolation of proteins nor the extraction of genomic DNA was adversely affected by the use of the fluid cover medium. No significant differences in RNA quantity and integrity were detected by TaqMan real-time PCR for GAPDH, and microchip electrophoresis, between covered and uncovered tissue sections. In conclusion, this method provides considerably improved morphology for laser microdissection and pressure catapulting techniques without affecting RNA-dependent downstream applications. This not only facilitates established procedures, but will also extend the application to tissues that require superior morphological resolution.     

Studies of stress in farm animals

Major changes have taken place in animal production over the last three decades. Housing conditions have changed dramatically over this period, and there has been a striking increase in production. Agricultural animals try to cope with these highly demanding conditions (stressors) using behavioural and physiological stress responses aiming to restore homeostasis. When these responses are not successful or when they are thwarted, typical behavioural and physiological symptoms of chronic stress occur. In this situation, the welfare of the animal is clearly at stake. Moreover, chronic stress may seriously affect the efficiency of animal production and the quality of the product. Ultimately, detailed knowledge of stress responses in agricultural animals will allow the formulation of housing and management requirements, including handling by humans, which will benefit welfare and health of farm animals as well as production efficiency. This paper briefly addresses some important issues regarding the study of stress and welfare in farm animals, and discusses some recently developed experimental methods as well as relevant results obtained in our laboratory. Originally presented at ECCP 97.