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Notes: Summary. First-trimester chorionic villus sampling (CVS) was performed in a series of 1250 pregnancies. The direct method of karyotyping was successful in 1205 (96.4%). Abnormal laboratory findings resulted in 60 terminations of pregnancy (4.8%). In addition, six unexpected balanced chromosome rearrangements were detected. False-positive cytogenetic findings occurred in 2.3%, comprising 22 with mosaicism confined to the trophoblast, and a further six non-mosaic false-positive discrepancies were detected, four after termination of pregnancy. The outcome of the first 1000 pregnancies is known in all but one. There were no false-negative findings. Of 947 pregnancies meant to be continued, 34 (3.6%) ended in pregnancy loss before 28 weeks gestation. However, obstetricians with an experience of over 150 procedures had a pregnancy loss of 1.3%.

Notes: Summary Quantitative aspects of DNA losses during fixation and pararosaniline(SO2)-Feulgen staining of microscopic preparations were studied. The preparation of a new cytochemical model, consisting of DNA-protein layers (with thicknesses between 0.1 and 5.0 μm) on microscopic glass slides is described and potentialities and limitations of this model are discussed. Polyacrylamide films into which high molecular weight calf thymus DNA or chicken erythrocyte nuclei had been constrained served as another model. As biological objects chicken erythrocyte nuclei and rat liver nuclei either in suspension or on microscopical glass slides were used. The experimental results indicate a loss of about 5% of the DNA due to the fixation procedure applied. Hydrolysis in 5 N HCl at room temperature, staining with the pararosaniline-Schiff medium and rinsing with sulfurous acid induced losses of DNA too, varying in amount depending on the type of preparation used. About 10% of the original DNA content is lost in total from chicken erythrocyte nuclei and rat liver nuclei dried on microscopical glass slides, from chicken erythrocyte nuclei constrained in polyacrylamide films, and from DNA-protein layers on microscopic glass slides. For nuclei fixed and stained in suspension the total losses amount to about 40%. The differences in losses between various types of preparations are discussed. Biochemically, the content of DNA originally present per chicken eythrocyte nucleus was determined to be 2.52 pg, a value, which is in good accordance with reliable biochemical data published already. It is shown that calibration of cytochemical staining intensities into biochemical units or absolute amounts of material by use of a model system, is only reliable when it is known or to be expected that both the loss of material due to fixation and staining, and the stoichiometric relation between material present and dye molecules is identical. The same holds for the application of internal biological reference systems.

Notes: Summary A new hypothesis is proposed on the involvement of nucleosomes in Giemsa banding of chromosomes. Giemsa staining as well as the concomitant swelling can be explained as an insertion of the triple charged hydrophobic dye complex between the negatively-charged supercoiled helical DNA and the denatured histone cores of the nucleosomes still present in the fixed chromosomes. New cytochemical data and recent results from biochemical literature on nucleosomes are presented in support of this hypothesis. Chromosomes are stained by the Giemsa procedure in a purple (magenta) colour. Giemsa staining of DNA and histone (isolated or in a simple mixture) in model experiments results in different colours, indicating that a higher order configuration of these chromosomal components lies at the basis of the Giemsa method. Cytophotometry of Giemsa dye absorbance of chromosomes shows that the banding in the case of saline pretreatment is due to a relative absence of the complex in the faintly coloured bands (interbands). Pretreatment with trypsin results in an increase in Giemsa dye uptake in the stained bands. Cytophotometric measurements of free phosphate groups before and after pretreatment with saline, reveal a blocking of about half of the free phosphate groups indicating that a substantial number of free amino groups is still present in the fixed chromosomes. Glutaraldehyde treatment inhibited Giemsa-banding irreversibly while the formaldehyde-induced disappearance of the bands could be restored by a washing procedure. These results correlate with those of biochemical nucleosome studies using the same aldehydes. Based on these findings and on the known properties of nucleosomes, a mechanism is proposed that explains the collapse of the chromosome structure when fixed chromosomes are transferred to aqueous buffer solutions. During homogeneous Giemsa staining reswelling of the unpretreated chromosome is explained by insertion of the hydrophobic Giemsa complex between the hydrophobic nucleosome cores and the superhelix DNA. Selective Giemsa staining of the AT-enriched bands after saline pretreatment is thought to be due to the, biochemically well-documented, higher affinity of arginine-rich proteins present in the core histones for GC-enriched DNA, which prevents the insertion of the Giemsa complex in the interbands. Production of Giemsa bands by trypsin pretreatment can be related to the action of this enzyme on the H1 histones and subsequent charge rearrangements. This and other cytochemical and biochemical evidence leads to a coherent hypothesis that relates the swelling properties, the purple homogeneous Giemsa staining, as well as the selective band staining after pretreatment of the chromosomes primarily to differences in base composition of the supercoiled DNA helices present in bands and interbands. Such base sequence differences are known to lead to differences in internal tension in supercoiled DNA helices as present in the nucleosomes as well as to differences in binding strength to the polar parts of histones. The proposed hypothesis eliminates the necessity to postulate a role for, up to now elusive, band-specific non-histone proteins in Giemsa banding.

Notes: Summary The properties of aminoalkylsilane-treated glass slides for the preparation of metaphase spreads and their staining quality have been studied and compared with those of slides which had only been cleaned in ethanol/ether. The parameters investigated were: (1) the average area of metaphases from cultures of blood from both healthy donors and haematology patients; (2) the influence of the positively charged ‘coating’ on the quality of quinacrine- and Giemsa-banding patterns; (3) non-specific background staining for these banding methods; (4) the number of metaphases as compared to the number of interphase cell nuclei per area of preparation; and (5) the Feulgen-staining intensities of chromosomes and chicken erythrocyte nuclei. The quality of metaphase preparations and the differential staining of chromosomes is better on aminoalkysilane-treated glass slides than that of preparations on routinely cleaned normal microscope slides. In the preparations on aminoalkylsilance-treated slides, the distribution of the cells over the glass surface is more homogeneous; and no influence could be detected on the relative frequency of metaphases as compared to the number of non-divided cell nuclei; the average area per metaphase is increased by about 10% and consequently the number of overlapping chromosomes is decreased. Preparations on aminoalkylsilane-treated glass, after Q-, G- and DAPI-banding procedures, always showed less binding of the staining compounds to the glass slide (a cleaner background) than those on routinely cleaned microscope glass slides. The Feulgen-pararosaniline staining intensities of human metaphase chromosomes and chicken erythrocyte nuclei are the same on aminoalkylsilane-treated slides and on routinely cleaned glass slides. Furthermore, the reproducibility and constancy of quinacrine banding was improved by development of an equilibrium staining method which does not require a washing procedure. The medium, containing 0.002% quinacrine, allows optimal staining results to be obtained for microphotography purposes within 30 min of staining (for visual inspection at least 90 min is required) and is used as the embedding medium. In combination with aminoalkylsilane-treated glass slides, this procedure leads to a clean background and reproducible banding patterns of excellent quality, the results being better and more constant than those of methods described before.