Silver staining in clinical cytogenetics

Silver staining of human chromosomes at prometaphase or metaphase identifies variants in the stalk (nucleolar organizing) regions of acrocentric chromosomes (Nos. 13, 14, 15, 21, 22). Variants are defined by size, number, and morphology of silver staining areas. They are heritable polymorphisms and have not been associated with clinical abnormalities. However, these variants are useful in clinical cytogenetics, specifically in studies attempting to determine whether genetic material has been gained or lost in chromosomal rearrangements, the origin of chromosomal aberrations, the origin of cells in tissue culture, the chromosomal location of single genes, clonal origin of tumors, the zygosity of twins, and paternity. Some chromosomal aberrations require silver staining for their definition. Because loss of the stalk regions per se is apparently not deleterious, demonstration that chromosomal breaks occurred within this region without concomitant loss or gain of genetic material essential for normal human development provides basis for a good prognosis for the individual with the chromosomal rearrangement resulting from such breakage. The principle underlying most of the other applications is to determine whether variants being compared are identical or dissimilar, and to make inferences from these results (e.g., variants in monozygotic twins should all be identical, whereas in dizygotic twins they are as similar as in any pair of sibs). Silver staining is a valuable technique for special questions in clinical analysis.     

Abundance of protein-bound sulfhydryl and bisulfide groups at chromosomal nucleolus organizing regions

Silver stainability of the chromosomal nucleolus organizing regions that contain the structural genes for ribosomal RNA can be abolished by proteolytic and oxidative treatments. Histone extraction has no effect. This indicates that reducing groups of non-histone chromosomal proteins are responsible for silver staining. Treatment with fluorescent sulfhydryl and disulfide specific reagents followed by silver staining demonstrates coincidence of silver dots and brightly fluorescent spots at the short arms of human acrocentric chromosomes where ribosomal RNA-genes are located. After treatment with cupric sulfite reagent in the presence of urea fluorescence and silver staining was no longer possible. Silver staining has been reported to be associated with ribosomal RNA-gene activity. Acrocentric chromosomes that are negative in silver staining also lack the brightly fluorescent spots. Therefore, we conclude that an abundance of protein-bound sulfhydryl and disulfide groups occur at nucleolar organizing regions with active genes. Differentially fluorescing spots could not be observed after staining with fluorescamine. So, either the sulfhydryl reagents used in this study are much more sensitive than fluorescamine to study protein distributions in cytological preparations, or our observations point to a local accumulation of some specific protein(s) rich in sulfhydryls. The presence of many sulfhydryl and disulfide groups at the nucleolus organizing regions seems suggestive of a great flexibility of protein(s) by transition of sulfhydryl groups to disulfide bridges and vice versa at these highly active regions of the genome.     

Identification of nucleolus organizer regions (NORs) in normal and neoplastic human cells by the silver-staining technique.

Silver nitrate has been used to demonstrate the chromosomal location of ribosomal cistrons in nine tissue-culture lines derived from human tumors of various pathological origins. Control individuals have a particular modal number (range 7--10) of D- and G-group chromosomes stained with silver. In the controls, 96.2% of the D- and G-group chromosomes that have a stalk show silver staining, while no relationship can be seen in acrocentric chromosomes without stalks. The tumor cells, whose modal chromosome numbers range from 42 to 68, possess variable numbers of acrocentrics (11--18). The number of chromosomes stained with silver, however, remained at control levels (range, 6--9). These data indicate that, in humans, silver staining may not identify all NORs that contain structural ribosomal genes.     

Chromosomal variants with normal phenotype in Man

The origin of human cytogenetics was very intimately associated with medicine, and therefore there was a primary interest in pathogenic effects of chromosomal aberrations only. However, chromosomal aberrations and variants exist which do not change the phenotype of the carrier. Similar aberrations and variants played a prominent role during the evolution of Man (centric fusions, inversions and possibly also translocations; variants in heterochromatic components of chromosomes). The principles of chromosomal evolution are still at work in Man; however the probability of a new and different human karyotype coming into existence, is negligible.New methods in cytogenetics (fluorescence, banding methods) which were used in human cytogenetics for the first time about two years ago, now allow analysis of chromosomes in very fine detail; they started a new era in cytogenetics. It is, therefore, a suitable time to summarize the results of the past era regarding chromosomal variants in Man, which were detected by classical staining methods in the first 15 years of human cytogenetics. The future review based on new methods, will be, of course, more extensive than this one, but it will be available only after years of chromosomal research.This review will be divided in the following way: (1) source of information on variants with normal phenotype, (2) variants with normal phenotype, (3) survival of variants in the population, (4) homozygous variants, (5) evolutionary consequences of chromosomal variants.     

Interrogation of genomes by molecular copy-number counting (MCC)

Human cancers and some congenital traits are characterized by cytogenetic aberrations including translocations, amplifications, duplications or deletions that can involve gain or loss of genetic material. We have developed a simple method to precisely delineate such regions with known or cryptic genomic alterations. Molecular copy-number counting (MCC) uses PCR to interrogate miniscule amounts of genomic DNA and allows progressive delineation of DNA content to within a few hundred base pairs of a genomic alteration. As an example, we have located the junctions of a recurrent nonreciprocal translocation between chromosomes 3 and 5 in human renal cell carcinoma, facilitating cloning of the breakpoint without recourse to genomic libraries. The analysis also revealed additional cryptic chromosomal changes close to the translocation junction. MCC is a fast and flexible method for characterizing a wide range of chromosomal aberrations.     

Conservation of nucleolar structure in polytene tissues of Ceratitis capitata (Diptera: Tephritidae)

Nucleolar structure was studied in mitotic and three polytene tissues of the Mediterranean fruit fly, Ceratitis capitata using in situ hybridization with a tritium-labelled rDNA probe and silver staining. In mitotic metaphase chromosomes nucleolar organiser regions were localised in the short arms of both sex chromosomes. In polytene nuclei of trichogen cells, salivary glands and fat body rDNA was detected within nucleoli. Nucleoli in these tissues have a similar structure with rDNA labelling concentrated in a central core. Silver staining resulted in very heavy staining of polytene nucleoli and interphase nucleoli in diploid cells. Silver staining of nucleolar organisers in metaphase chromosomes is weak or absent although the X chromosome has numerous dark silver bands in other locations. The results suggest that nucleolar structure is conserved in polytene tissues contrasting with the variability of autosomal banding patterns and sex chromosome structure. They also indicate that silver staining is not necessarily specific for nucleolar regions.     

Cytogenetic analysis of Epicauta atomaria (Meloidae) and Palembus dermestoides (Tenebrionidae) with Xyp sex determination system using standard staining, C-bands, NOR and synaptonemal complex microspreading techniques

The mitotic and meiotic chromosomes of the beetles Epicauta atomaria (Meloidae) and Palembus dermestoides (Tenebrionidae) were analysed using standard staining, C-banding and silver impregnation techniques. We determine the diploid and haploid chromosome numbers, the sex determination system and describe the chromosomal morphology, the C-banding pattern and the chromosome(s) bearing NORs (nucleolar organizer regions). Both species shown 2n = 20 chromosomes, the chromosomal meioformula 9 + Xyp, and regular chromosome segregation during anaphases I and II. The chromosomes of E. atomaria are basically metacentric or submetacentric and P. dermestoides chromosomes are submetacentric or subtelocentric. In both beetles the constitutive heterochromatin is located in the pericentromeric region in all autosomes and in the Xp chromosome; additional C-bands were observed in telomeric region of the short arm in some autosomes in P. dermestoides. The yp chromosome did not show typical C-bands in these species. As for the synaptonemal complex, the nucleolar material is associated to the 7th bivalent in E. atomaria and 3rd and 7th bivalents in P. dermestoides. Strong silver impregnated material was observed in association with Xyp in light and electron microscopy preparations in these species and this material was interpreted to be related to nucleolar material.     

A Method for Combined C-Banding and Silver Staining

A reliable technique for combined C-banding and silver staining of metaphase chromosomes which uses trypsinization is described. Slides are first immersed in dilute HCl to remove residual cytoplasm from around the chromosomes. They are then treated with saturated barium hydroxide and incubated overnight in saline sodium citrate (0.30 M NaCl, 0.03 M sodium citrate, adjusted to pH 7.0 with HCl). Following the C-banding pretreatment, a two-step method of silver staining which employs a protective colloidal developer is used to stain the nucleolar organizer regions (NORs) of the chromosomes. Silver staining is followed by trypsinization to remove extraneous silver precipitate from the chromosome arms which permits the C-bands to be stained with Giemsa. The method works equally well with fresh and aged mitotic chromosome preparations and gives consistent staining of both heterochromatin and active NORs in metaphases across the slide.     

A method for combined C-banding and silver staining

A reliable technique for combined C-banding and silver staining of metaphase chromosomes which uses trypsinization is described. Slides are first immersed in dilute HCl to remove residual cytoplasm from around the chromosomes. They are then treated with saturated barium hydroxide and incubated overnight in saline sodium citrate (0.30 M NaCl, 0.03 M sodium citrate, adjusted to pH 7.0 with HCl). Following the C-banding pretreatment, a two-step method of silver staining which employs a protective colloidal developer is used to stain the nucleolar organizer regions (NORs) of the chromosomes. Silver staining is followed by trypsinization to remove extraneous silver precipitate from the chromosome arms which permits the C-bands to be stained with Giemsa. The method works equally well with fresh and aged mitotic chromosome preparations and gives consistent staining of both heterochromatin and active NORs in metaphases across the slide.     

Rapid induction of large chromosomal deletions by a Cre/inverted loxP system in mouse ES Cell hybrids

Loss of heterozygosity by whole or partial loss of chromosomal regions is crucial to genetic disorders, cancers and diseases. It is difficult to analyze the mechanisms of pathogenesis caused by large-scale chromosomal abnormalities due to the extreme rarity of this mutagenesis. Using a Cre/inverted loxP system, we have generated a chromosome elimination cassette (CEC) that induces a selective loss of embryonic-stem-cell-derived chromosomes in undifferentiated embryonic stem cell-somatic cell hybrids. Here, due to the increased expression of Cre, rapid formation of Cre recombination products and immediate loss of CEC-tagged chromosomes were detected by fluorescence in situ hybridization. Cre also initiated intrachromosomal recombination between identical short sequences outside loxP, leading to large chromosomal deletions of CEC-tagged regions. The Cre-mediated antiparallel synapses likely act as a scaffold to bring the identical short sequences into close proximity for recombination. This CEC technology might allow better understanding of the modulator sequences responsible for the tangled structure formation and its solution mechanism, inducing mitotic recombination leading to chromosomal deletions.     

Silver Staining for Nucleolar Organizing Regions of Vertebrate Chromosomes

Refinements to a simple, one-step silver staining technique for nucleolar organizing regions are described. These include fixation of silver stained material with sodium thiosulfate and standardization of silver development conditions for different groups of vertebrates. The central advantages to the method are that it is rapid, reliable, simple, and inexpensive. Additional benefits include (i) consistent and uniform silver staining of nucleolar organizing regions, (ii) few reduced silver deposits elsewhere on the chromosomes or on the slides, (iii) generally unaltered chromosome morphology after silver treatment, and (iv) relative permanence of Permounted preparations. The method works equally well on chromosomes made from cell cultures and from solid tissues of live specimens.     

Silver staining for nucleolar organizing regions of vertebrate chromosomes

Refinements to a simple, one-step silver staining technique for nucleolar organizing regions are described. These include fixation of silver stained material with sodium thiosulfate and standardization of silver development conditions for different groups of vertebrates. The central advantages to the method are that it is rapid, reliable, simple, and inexpensive. Additional benefits include (i) consistent and uniform silver staining of nucleolar organizing regions, (ii) few reduced silver deposits elsewhere on the chromosomes or on the slides, (iii) generally unaltered chromosome morphology after silver treatment, and (iv) relative permanence of Permounted preparations. The method works equally well on chromosomes made from cell cultures and from solid tissues of live specimens.     

Intercalary heterochromatin in polytene chromosomes of <Emphasis Type="Italic">Drosophila melanogaster</Emphasis>

Intercalary heterochromatin consists of extended chromosomal domains which are interspersed throughout the euchromatin and contain silent genetic material. These domains comprise either clusters of functionally unrelated genes or tandem gene duplications and possibly stretches of noncoding sequences. Strong repression of genetic activity means that intercalary heterochromatin displays properties that are normally attributable to classic pericentric heterochromatin: high compaction, late replication and underreplication in polytene chromosomes, and the presence of heterochromatin-specific proteins. Late replication and underreplication occurs when the suppressor of underreplication protein is present in intercalary heterochromatic regions. Intercalary heterochromatin underreplication in polytene chromosomes results in free double-stranded ends of DNA molecules; ligation of these free ends is the most likely mechanism for ectopic pairing between intercalary heterochromatic and pericentric heterochromatic regions. No support has been found for the view that the frequency of chromosome aberrations is elevated in intercalary heterochromatin.     

Analysis of banding patterns and mosaic configurations in a case of ring chromosome 15

Summary Cytogenetic studies on lymphocytes from a 14-year-old mentally retarded girl with somatic anomalies suggestive of a chromosomal abnormality revealed a ring chromosome 15. The long arm of the defective chromosome is broken at band q24 or q25. The silver staining technique for nucleolus organizer regions showed that the ring had lost the achromatic stalk and the satellite. The chromosomal mosaicism resulting from the structural instability of the ring chromosome was analyzed and compared with 6 cases reported in the literature. It is proposed that the clinical manifestations in the different patients with ring chromosome 15 result from both the deficiency in the long arm and the mosaic configurations.     

Nature and distribution of constitutive heterochromatin and NOR location in the grasshopper Phaeoparia megacephala (Romaleidae: Orthoptera)

The constitutive heterochromatin (CH) of Phaeoparia megacephala was studied using C-banding and fluorochrome staining (CMA3, DAPI and acridine orange). The nucleolar organizer regions (NOR) were identified with silver staining. The chromosome complement of this species was 2n = 23, XO in males, and 2n = 24, XX in females. The CH was pericentromeric in all chromosomes. L1, L2, L3 and X chromosomes showed large blocks of CH, while the medium and small chromosomes had small blocks. The staining procedure with acridine orange revealed the same pattern. All the pericentromeric regions showed small blocks of CMA3-positive constitutive heterochromatin (GC-rich regions), while only part of the large C-band positive chromosome segments (L1, L2, L3 and X) were CMA3 positive. This character demonstrates an uncommon heterogeneity of constitutive heterochromatin in P. megacephala. The fluorochrome DAPI did not reveal DAPI-positive regions (AT-rich regions). Silver staining revealed only one pair of medium chromosomes with NOR.     

Subtelomeric chromosomal rearrangements detected in patients with idiopathic mental retardation and dysmorphic features

Subtelomeric chromosomal rearrangements detected in patients with idiopathic mental retardation and dysmorphic features: Cryptic aberrations involving the subtelomeric regions of chromosomes are thought to be responsible for idiopathic mental retardation (MR) and multiple congenital anomalies, although the exact incidence of these aberrations is still unclear. With the advent of chromosome-specific telomeric Fluorescence In Situ Hybridization (FISH) probes, it is now possible to identify submicroscopic rearrangements of distal ends of the chromosomes that can not be detected by conventional cytogenetic methods. In this study, cryptic subtelomeric chromosomal aberrations were detected in two of ten patients with idiopathic MR and dysmorphic features by using FISH probes of subtelomeric regions of all chromosome arms. A cryptic unbalanced de novo translocation was detected between the subtelomeric regions of the chromosome 10p and 18p in a patient with severe mental retardation, sensorineuronal deafness and several dysmorphic features. In the other patient, with mild mental retardation and dysmorphic features, a de novo subtelomeric deletion of chromosome 2q was found. In conclusion, in both familial and sporadic cases with idiopathic MR and dysmorphic features, the detection of chromosomal aberrations including subtelomeric rearrangements is of great importance in offering genetic counseling and prenatal diagnosis.     

A case of prenatal detection of a de novo unbalanced complex chromosomal rearrangement involving four chromosomes

Complex chromosomal rearrangements are rarely observed prenatally. Genetic counceling of CCR carriers is complicated, especially in cases of de novo origin of the rearrangement. Here we present a new case of a de novo CCR involving four chromosomes observed in amniotic fluid cells of the fetus at 17 weeks of gestation. The rearrangement was characterized as an apparently balanced four-way trans-location t(1;11;7;13)(~p21;~q13.5;~q32;~q22)dn by conventional cytogenetic studies. However, array-based comparative genomic hybridization revealed 5 submicroscopic heterozygous interstitial deletions on chromosome 1, 11, 7, 13 with a total loss of 21.1 Mb of genetic material in regions close to those, designated as breakpoints by conventional cytogenetic analysis. The described case clearly illustrates that high-resolution molecular genetic analysis should be combined with conventional cytogenetic techniques to exclude subtle chromosomal abnormalities in CCR cases detected prenatally.