INDUCED POLYPLOIDY AND SORTING OF DAMAGED DNA BY MICRONUCLEATION IN RADIORESISTANT RAT LIVER EPITHELIAL STEM-LIKE CELLS EXPOSED TO X-RAYS

OBJECTIVE

Rat liver stem-like epithelial cells (WB-F344) that under certain conditions may differentiate into hepa- tocyte and biliary lineages were subjected to acute X-irradiation with the aim to examine cell cycle peculiarities dur- ing the course of survival.

MATERIALS AND METHODS

Suspensions of WB-F344 cells that grew as a monolayer and reached sub-confluence were irradiated with 1, 5, and 10 Gy of X-rays (2 Gy/min). As an intact control, sham-irradiated cells were used. After irra- diation, cells were plated into 25-cm2 tissue culture flasks to culture them for over several days without reaching contact inhibition. On days 1, 2, 3, and 5 post-irradiation, cells were harvested and examined for nuclear morpholo- gy and DNA ploidy by stoichiometric toluidine blue reaction and image cytometry. On days 7 and 9 post-irradiation, only heavily irradiated (10 Gy) cells were examined. Also, 10 Gy-irradiated cells were chosen for immunofluorescence staining to monitor persistence of DNA lesions (γ-H2AX), cell proliferation (Ki-67), and self-renewal factors charac- teristic for stem cells (OCT4 and NANOG).

RESULTS

Radioresistance of WB-F344 cells was evidenced by the findings that they do not undergo rapid and mas- sive cell death that in fact was weakly manifested as apoptotic even in heavily irradiated cells. Instead, there was cell cycle progression delay accompanied by polyploidization (via Ki-67-positive mitotic slippage or via impaired cytokinesis) and micronucleation in a dose-dependent manner, although micronucleation to some extent went ahead of polyploidization. Polyploid cells amenable for recovering from DNA damage can mitotically depolyploidize. Many micronuclei contained γ-H2AX clusters, suggesting isolation of severely damaged DNA fragments. Both factors, OCT4 and NANOG, were expressed in the intact control, but became enhanced after irradiation.

CONCLUSIONS

Although the fact of micronucleation is indicative of genotoxic effect, WB-F344 cells can probably escape cell death via sorting of damaged DNA by micronuclei. Induction of polyploidy in these cells can be adaptive to promote cell survival and tissue regeneration with possible involvement of self-renewal mechanism.

PROBING BREAST CANCER THERAPEUTIC RESPONSES BY DNA CONTENT PROFILING

Background. Discrepancies in the interpretation of breast cancer therapeutic responses still exist mainly because of lack of standardized assessment criteria and methods. Objective. DNA content profiling of cells in the affected (cancerous) tissue before and after neoadjuvant chemotherapy (NAC) was applied to facilitate interpretation of therapeutic responses. Methods. Both diagnostic biopsy and operation materials representing the tissue of primary tumors surgically removed after NAC were subjected to DNA image cytometry. Polyploidy and aneuploidy in DNA histograms were evaluated with a prognostic Auer typing. Stemline DNA index (DI) values and percentages of cells that polyploidize (>4.5C) were also determined. Immunofluorescence staining was applied to evaluate proliferation (Ki-67), invasiveness (CD44), and self-renewal factors characteristic for stem cells (SOX2 and NANOG). Results. DNA content profiles of 12 breast cancer cases, of which 7 were triple-negative, revealed the features of tumor non-responsiveness to NAC in 7 cases, of which 5 were triple-negative. Among non-responsive cases there were 3 cases that showed enhanced polyploidization, suggesting the negative NAC effect. Near-triploid (DI=1.26-1.74) triple-negative cases were determined as most resistant to NAC. Cycling near-triploid cells may contribute to the excessive numbers of >4.5C cells. Polyploid cells were positive for Ki-67, CD44, SOX2, and NANOG. Conclusions. DNA content profiling data provide additional helpful information for interpreting therapeutic responses in NAC-treated breast cancers. Polyploid tumor cells possessing stem cell features can be induced by NAC. Because NAC effects in some cases may be unfavorable, the use of the further treatment strategy should be carefully considered.

Abstract P3-03-17: Can polyploid tumor cells possessing stem cell features be induced in resistant breast carcinomas?

Cancer stem cells are believed to be responsible for radio- and chemoresistance of malignant tumors. In vitro studies demonstrate that ionizing radiation is capable of reprogramming cancer cells from non-stem state into stem state [1, 2]. Moreover, the embryonic stemness cassette was found to be expressed in tumor cells (including breast cancer cells) after they were polyploidized as a result of genotoxic stress [2, 3], thus prompting us to suppose that the polyploid cells and their descendants released by depolyploidization can possess stem cell characteristics. The aim of the current work is to test whether polyploid cells having stem cell features can be also induced in vivo, namely in locally advanced breast carcinomas as a result of neoadjuvant chemotherapy (NAC), assuming that this process is not autonomous, but rather stipulated by the tumor microenvironment.

The study population consisted of 30 breast cancer patients of age ranged from 31 to 75 y. o. diagnosed in the Latvian Oncology Center of the Riga East University Hospital between 2013 and 2015. The tissue specimens were collected after the patients' informed consent was obtained in accordance with the Ethics regulations. The clinico-pathologic information about these patients, including Ki-67 index and the status of ER, PR and HER2 receptors, was obtained from the aforementioned clinics. The majority of patients (n = 28) had locally advanced breast cancer, predominantly Stage III disease. Both diagnostic biopsy and operation material, such as primary tumors surgically removed after NAC using standard doses of paclitaxel and doxorubicin, were subjected to DNA content analysis with image cytometry. Ploidy-related parameters, such as DNA index and the percentage of cells exceeding 4.5c (presumably proliferating and polyploid cells), were determined. Immunofluorescence staining was applied to evaluate expression of such markers/factors as proliferation (Ki-67), stemness (SOX2 and NANOG) and invasiveness (CD44).

At the time of diagnosis, 14 patients had primary tumors possessing near-triploid clones, and these cases in comparison with 16 other cases comprised of near-euploid clones had 4.5-fold increase of percentages of cells exceeding the ploidy of 4.5c (p < 0.05) and 1.3-fold increase of percentages of cells positive for Ki-67 (p > 0.05). Of 10 cases diagnosed as “triple-negative”, 6 were near-triploid. Among those cases that showed the resistance to NAC (grades 1 and 2 by Miller-Payne histopathologic scoring), 67% were near-triploid. Polyploidization, which in some resistant cases is gained by NAC, was likely to be attributed to near-triploid clones. Notably, polyploid cells were positive for Ki-67, SOX2, NANOG, and CD44. Thus, these non-quiescent polyploid cells can possess the invasiveness and self-renewal features that were also seen in descendants after depolyploidization. Perhaps, reversible polyploidy plays a definite role in gaining the resistance of tumor cells to chemo- and radiotherapy in vivo.

1. Ghisolfi L. et al. PLoS ONE 2012; 7: e43628.

2. Lagadec C. et al. Stem Cells 2012; 30: 833-44.

3. Salmina K. et al. Exp Cell Res 2010; 316: 2099-112.

Citation Format: Gerashchenko BI, Salmina K, Eglitis J, Erenpreisa J. Can polyploid tumor cells possessing stem cell features be induced in resistant breast carcinomas? [abstract]. In: Proceedings of the 2016 San Antonio Breast Cancer Symposium; 2016 Dec 6-10; San Antonio, TX. Philadelphia (PA): AACR; Cancer Res 2017;77(4 Suppl):Abstract nr P3-03-17.

Disentangling the aneuploidy and senescence paradoxes: a study of triploid breast cancers non-responsive to neoadjuvant therapy

Aneuploid cells should have a reduced proliferation rate due to difficulty in proceeding through mitosis. However, contrary to this, high aneuploidy is associated with aggressive tumour growth and poor survival prognosis, in particular in triploid breast cancer. A further paradox revolves around the observation that, while cell senescence should inhibit proliferation, the senescence marker p16INK4a correlates with poor treatment outcome in patients with a very aggressive triple-negative breast carcinoma (TNBC). In this study, we aim to pour light on the possible relationship of these conundrums with polyploidy of tumour cells. We performed detailed analysis of DNA histogram profiles in diagnostic core biopsies of 30 cases of operable breast cancer and found that near triploidy in TNBC and other forms correlated with weak or no response to neoadjuvant chemotherapy (NAC) as scored by Miller-Payne index. Polyploid cells in operation samples from tumours that were non-responsive to NAC treatment were Ki67 and CD44 positive. In addition, polyploid cells were positive for markers of embryonic stemness (OCT4, SOX2, NANOG) and senescence (p16INK4a). The relationship patterns between p16INK4a and NANOG were heterogeneous, with predominantly mutually exclusive expression but also synergistic and intermediate variants in the same samples. We conclude that the aneuploidy and senescence paradoxes can be explained by the mutual platform of polyploidy, conferring genomic and epigenetic instability as a survival advantage. Such cells are able to bypass aneuploidy restrictions of conventional mitosis and overcome the barrier of senescence by a shift to self-renewal, resulting in progression of cancer.

Characterization of breast cancer DNA content profiles as a prognostic tool

Worldwide, breast cancer in women remains to be the most common malignancy that in a considerable proportion shows the resistance to genotoxic treatments and poor outcome. Chromosomal instability manifested as aneuploidy represents an integral cha-racteristics of the malignant genotype not only because of the selection of mutated aneuploid sub-clones that stipulate the tumor progression, but also because of the reversible endopolyploidy of tumor cells that serves for the endless maintenance of therapy-resistant tumor stem cells. Therefore, cytometric determination of DNA content in tissue samples for detecting malignancy, monitoring responses to therapy, and prognosing disease outcome needs to be revived. Both flow and image cytometry are most frequently used for generation of DNA content profiles (histograms), interpretation of which, however, may have some caveats. This review presents the major characterization criteria and analysis tools for breast cancer DNA histograms.

MOS, aneuploidy and the ploidy cycle of cancer cells

After DNA or spindle damage, p53-defective tumor cells undergo a complex cycle of reversible polyploidy. How this process occurs and more importantly, why, has recently become the focus of several research groups, prompting this review in which we discuss two related phenomena that accompany the reversible polyploidy of tumor cells: the induction of meiosis genes such as MOS and the decrease in genomic instability observed during the reversion from polyploidy to para-diploidy. The reversible polyploidy likely provides the means through which the balance between increased chromosome instability (CIN), driving genetic variation and decreased CIN, necessary for perpetuating these malignant clones, is maintained. These concepts are integrated with recent findings that many meiotic and self-renewal genes become activated during reversible polyploidy and lead us to the hypothesis that tumor cell immortality may be achieved through germline-like transmission.

Sperm chromatin structure and male fertility: biological and clinical aspects

Sperm chromatin/DNA integrity is essential for the accurate transmission of paternal genetic information, and normal sperm chromatin structure is important for sperm fertilizing ability. The routine examination of semen, which includes sperm concentration, motility and morphology, does not identify defects in sperm chromatin structure. The origin of sperm DNA damage and a variety of methods for its assessment are described. Evaluation of sperm DNA damage appears to be a useful tool for assessing male fertility potential both in vivo and in vitro. The possible impact of sperm DNA defects on the offspring is also discussed.

Toluidine blue cytometry test for sperm DNA conformation: comparison with the flow cytometric sperm chromatin structure and TUNEL assays

BACKGROUND

Sperm DNA integrity (SDI) is an important factor in the prognosis of male fertility. Here we compare the toluidine blue (TB) image cytometry test, recently proposed by us for SDI assessment, with two other tests-the sperm chromatin structure assay (SCSA) and the terminal nick-end labelling (TUNEL) assay.

METHODS

Sperm samples from 35 men were evaluated for standard sperm parameters and subjected to the TB test and SCSA. Eighteen of the 35 samples were also subjected to the TUNEL assay.

RESULTS

The proportion of sperm cells with abnormal DNA integrity assayed by the TB test correlated strongly with the proportion of abnormal cells detected by the SCSA and TUNEL assay (rho=-0.84 and rho=0.80, P<0.001, respectively). Furthermore, the fractions of abnormal cells by the TB test corresponded closely to the sum of two SCSA parameters, the DNA fragmentation index (DFI) and the fraction of highly DNA-stainable cells (HDS) (medians 33.0 versus 32.0%, P=0.6).

CONCLUSIONS

Abnormal cells in a TB test correspond to the sum of DFI and HDS fractions in the SCSA. TB-positive cells may represent sperm with fragmented DNA and/or abnormal chromatin structure. Because the TB test is an easy and inexpensive method, its potential use as a routine test for sperm DNA integrity, complementary to standard semen parameters, should be investigated further.

Comparative study of cytochemical tests for sperm chromatin integrity

Tests were carried out on sperm from 40 fertile and infertile men to evaluate 2 DNA in situ denaturation methods using acridine orange (AO; the modified Rigler-Roschlau method and the Tejada method), alongside routine aniline blue (AB) and toluidine blue (TB) tests in our modification, and in order to estimate and compare the practical value of different in situ cytochemical tests for sperm chromatin structure. In addition, the methods were applied to rat and boar spermiogenesis models. The sperm heads with abnormal versus normal chromatin structure were specified as orange-red versus green by the AO method, blue versus uncolored by the AB method, and purple-violet versus light blue by the TB method. A good correlation for the proportion of sperm heads with abnormal chromatin structure was found among all the methods (r = .63-.70; P < .01), which characterized all 4 techniques as sensitive enough to estimate in situ sperm DNA integrity. In our study, the average value of abnormal cells was 17% +/- 3.8% and 30.2% +/- 6.8% for the fertile and infertile groups of men, respectively, setting a threshold of 95% probability at 23% as judged by the Rigler-Roschlau method. This compared with 23.9% +/- 7.5% and 52.1% +/- 20.8% (P < or = .05) for the fertile and infertile groups, respectively, setting a threshold at 31%, as judged by the Tejada method. The technical advantages and disadvantages of each method are briefly reported. Key words: Fertility, DNA normality, sperm maturation.

Aberrations of cell cycle and cell death in normal development of the chick embryo growth plate

The epiphyses of femurs from 7.5-15 day chicken embryos were studied by electron microscopy. Several forms of aberrant cell cycles were present: (1) in the perichondrium, polyploid metaphases, segmentating large (giant) cells, and mitotic catastrophe (midway between mitosis and apoptosis) were observed; (2) in the resting zone, premature chromosome condensation was found; (3) in the proliferative zone, approximately 5% of divisions were aberrant, representing most often mitosis restitution from metaphase and more seldom from the anaphase; (4) in all layers, 'dark chondrocytes' representing a premortal form of hypersecretory cells undergoing often a-mitotic nuclear segmentation were present. Many of the aberrations of cell cycle were combined with cell death. These deviations omitting or adapting the cell cycle check-points represent evidently the normal epigenetic mechanisms of development and repair. At the same time, by origin and appearances they seem very close to the loss of the growth control displayed by malignant tumours. This connection is briefly analysed in view of some current concepts of carcinogenesis.

Aberrant death in dark chondrocytes of the avian growth plate

Growth plate chondrocytes of embryonic chick femurs were examined by electron microscopy, cytophotometry and autoradiography. Apart from the well-described 'light' chondrocyte, a different 'dark' type of chondrocyte was present, comprising 10 - 35% of the cell population. They were found at all stages of chondrocyte differentiation and in all ages of the femurs studied. Well developed rough endoplasmatic reticulum and Golgi complex, many secretory vesicles, energetically active mitochondria and a lot of glycogen, indicating high activity of the cytoplasm, were combined with low RNA synthesis, gentle margination and scattered compaction of the chromatin. DNA cytometry revealed that most of dark cells were diploid, but 15 - 30% were tetraploid, with the absence of an S-phase. Substantial loss of DNA was found in about 10% of dark chondrocytes. The TUNEL reaction demonstrated a limited number of DNA strand breaks. Advanced dark cells possessed the nuclear features of both apoptosis and necrosis. Besides chromomeric-chromonemic compaction, a chromatin arrangement similar to that of prometaphase and metaphase, as well as amitotic nuclear segregation, all of them degenerative, were found. Our interpretation is that the dark chondrocytes undergo an aberrant type of cell death which may be combined with aberrant cell cycle. Cell death of dark chondrocytes is preceded by a pre-mortal burst of secretion.

Apoptotic cell nuclei favour aggregation and fluorescence quenching of DNA dyes

Apoptotic cell nuclei are known to stain hyperchromatically with absorption dyes and dimly with many DNA fluorochromes. We hypothesised that both optical phenomena have the same cause--the ability of apoptotic chromatin to aggregate cationic dyes. This hypothesis was tested using prednisolone-primed rat thymus, which is known to contain apoptotic cells. The apoptotic cells were classified as early and late, based on their morphology, in thin and semithin sections and in thymus imprints on slides. Direct reaction for DNA strand breaks (TUNEL) indicated the presence of breaks in both categories of cells, with more intense labelling in late apoptosis. The chromatin ultrastructure of early apoptotic cells initially retained the supranucleosomal order of packaging which characterises control cells, whereas the dense chromatin of late apoptotic cells possessed the degraded structure. Absorption spectra of the toluidine blue-stained early apoptotic cell chromatin revealed a metachromatic shift, indicating a change of DNA conformation and polymerisation of the dye. When the staining was performed by acridine orange (preceded by a short acid treatment), a paradoxical several-fold increase of fluorescence intensity at a several-fold dilution of the dye was found. The simultaneous reduction of the ratio of red to green components of fluorescence confirmed that the concentration-dependent fluorescence quenching was due to aggregation of the dye. The results suggest that the enhanced affinity of the chromatin of early apoptotic cells for cationic dyes is associated with conformational relaxation rather than degradation of DNA. In late apoptotic cells, the very dense packaging of degraded DNA promotes further aggregation of dyes. The results suggest alternative methods for detection and discrimination of early and late apoptotic cells.

Epigenetic selection as a possible component of transdifferentiation. Further study of the commitment of hypertrophic chondrocytes to become osteocytes

Transdifferentiation of hypertrophic chondrocytes into osteogenic cells was induced in 14 day chick embryo femurs by cutting through the region of hypertrophic cartilage. The process was studied in organ culture, using electron microscopy, staining for alkaline phosphatase, immunocytochemistry of collagen type I and proliferative cell nuclear antigen, and in situ localization of DNA strand-breaks. In addition, DNA and RNA synthesis were studied by 3[H]-T and 3[H]-U radioautography. Loss of ECM components from the cut edge occurred in culture. During the 12 day period necessary for transdifferentiation we observed phenotypic instability and bi-potentiality, the death of some cells and the gradual promotion of the osteoblastic phenotype in the survivors. Transition from chondrocytic to osteoblastic phenotype progressed stepwise, through variable mosaic intermediates, and involved a few cell cycles including asymmetric (differential) divisions. Proliferating and apoptotic cells were found in close proximity. As judged by the relative proportion of apoptotic cells and composition of the surrounding intralacunar matrix, negative selection of intermediate cell types displaying chondrocytic and altered mosaic phenotypes occurred. When the osteoblastic lineage was finally established, apoptotic cells were no longer present. Our hypothesis is that after disruption of cell-cell or cell-matrix interactions and lack of growth factors certain cells are selected and channelled through proliferation into the new stable phenotype. This process is targeted by the environment through a set of pre-determined steps.

The phenotypic switch from chondrocytes to bone-forming cells involves asymmetric cell division and apoptosis

We have investigated the early cellular events that take place during the phenotypic switch from hypertrophic chondrocytes to bone-forming cells in a) chondrocytes located inside intact lacunae after embryonic chick femurs had been cut through the hypertrophic cartilage and cultured for 1-15 days; and b) at the cartilage/marrow interface of femurs after short-term culture. Ultrastructural studies were combined with in situ methods localizing proliferating and apoptotic cells, and 3D-reconstructions of confocal images of the cartilage/marrow edge. The crucial event in the phenotypic switch was an asymmetric cell division which resulted in one daughter cell which underwent apoptosis and another viable daughter cell which subsequently differentiated to an osteogenic cell, i.e to a smaller basophilic cell that was positive for alkaline phosphatase, type I collagen, osteonectin, osteopontin, bone sialoprotein and osteocalcin and that, after 12-15 days in culture, could synthesize a mineralized bone matrix within intact lacunae. The present results suggest a mechanism whereby differentiated cells can change their phenotype. At least one mitotic division seems to be required to fix the commitment to the new phenotype.

Osteogenic differentiation of hypertrophic chondrocytes involves asymmetric cell divisions and apoptosis

We have investigated the early cellular events that take place during the change in lineage commitment from hypertrophic chondrocytes to osteoblast-like cells. We have induced this osteogenic differentiation by cutting through the hypertrophic cartilage of embryonic chick femurs and culturing the explants. Immunocytochemical characterization, [3H]thymidine pulse-chase labeling, in situ nick translation or end labeling of DNA breaks were combined with ultrastructural studies to characterize the changing pattern of differentiation. The first responses to the cutting, seen after 2 d, were upregulation of alkaline phosphatase activity, synthesis of type I collagen and single-stranded DNA breaks, probably indicating a metastable state. Associated with the change from chondrogenic to osteogenic commitment was an asymmetric cell division with diverging fates of the two daughter cells, where one daughter cell remained viable and the other one died. The available evidence suggests that the viable daughter cell then divided and generated osteogenic cells, while the other daughter cell died by apoptosis. The results suggest a new concept of how changes in lineage commitment of differentiated cells may occur. The concepts also reconcile previously opposing views of the fate of the hypertrophic chondrocyte.

Differentiation and programmed cell death in Sa-45 tumour treated with bone inducer

The relationship between differentiation and concerted cell death was studied using ultrastructural, histochemical and immunochemical methods in solid rat fibrosarcoma Sa-45 grown in the presence of demineralized bone matrix. The control tumour consisted mostly of undifferentiated cells with few poorly or moderately differentiated cells. In the presence of the inducer, cells with a more differentiated pattern appeared in the surrounding area. The proliferative activity in the presence of the inducer was 3 to 5 times lower but the apoptotic index was higher than in the controls. However, complete differentiation was induced only in stromal cells, whereas the parenchymal cells showed signs of enhanced but incomplete differentiation. The ultrastructural signs of programmed cell death progressed in them faster than the corresponding features of maturation, thus leaving differentiation incomplete.

Interphase genome as the active space: chromatin dynamics during chick embryo chondrogenesis

The rearrangement of the chromatin that takes place during cytodifferentiation was studied using TV image analysis in chick limb bud cartilage stained for DNA. The redistribution of the chromatin was compatible with the Rabl orientation: chromatin was extended radially from the centromeric ring to the telomere pole in young chondroblasts, and contracted back in ageing chondrocytes. The direction and gradient of this redistribution correlate with the changes in DNA content within the chromocentres formed by pericentromeric heterochromatin. In turn, intercalary heterochromatin regulates the condensation of the adjacent euchromatin depending upon the position in this radial-polar gradient.

Influence of chromatin condensation on the absorption spectra of nuclei stained with toluidine blue

To study the influence of chromatin condensation on the absorption spectra of nuclei stained with toluidine blue, DNA staining methods--which favour or prevent dye polymerization--were applied to the imprints of rat tissues that differed greatly in the density of chromatin packing. It is stated that all factors promoting dye polymerization cause a left shift of the spectra while the factors preventing it, a right one. It was found that condensation of the chromatin can raise prerequisites that both enhance and hinder polymerization, and that the final result depends on the staining method, the manner of chromatin folding, and the density of its packing.

Accumulation of DNA within chromocentres of terminally differentiating chick embryo chondrocytes

Automated television (TV) densitometric technique which allows the recognition and recording of chromatin compartments was applied to the study of chromatin rearrangement during chondrogenesis. Genetically active chondroblasts and inactive definite chondrocytes of E7 chick cartilage model, stained on the imprints for DNA, were a subject for the comparative study. Large chromatin granules with constant morphometric parameters, displaying positive staining for C-heterochromatin and identified as chromocentres, were found to accumulate 30% of cellular DNA, doubling its concentration during chondrogenic maturation. A test for the DNA content ethalonization proved this to be due to redistribution of DNA from the euchromatinic compartment.

Two mechanisms of chromatin compaction

2 types of chromatin compaction were studied by cytochemical and ultrastructural approach. The 1st type was induced by cultivating transformed cells with dimethylsulfoxide. It caused cell transition into a more differentiated state coupled with the appearance of multiple small chromatin condensates. The 2nd type was induced by nonionic detergent Triton X-100 and/or saline penetration inside the nuclei. It was found to be connected with hypercompaction of chromocenters with their integral areas left unincreased. Both types of chromatin compaction differ in their capacity to induce toluidine blue polymerization on DNA substrate and in stability of DNA towards an early step of acid hydrolysis. The relation of the 2 mechanisms of chromatin compaction to different ways of DNA folding is discussed.

Lysis of cell nuclei on perforated electron microscopic supports

The technique of gentle nuclear lysis for electron microscopic observation is suggested, which comprises adsorption of isolated nuclei on a positively charged pricked supporting film and sequential short-timed installation of the support with its back onto the filter paper moistened by lysing solution. The advantage of the method is slow, gradient-like, and to some extent regulated treatment allowing to visualize nuclear structures in their integrity.

Staining of DNA with uranylacetate in hydrolysed ultrathin sections

Rat liver and hepatoma cells fixed with formaldehyde, embedded into Epon and treated on sections with 5 n HCl and then with aqueous uranylacetate show preferential DNase-sensitive reaction. The reaction is highly dependent upon proper fixation, hydrolysis improves its specificity. The binding of the contrast with DNA is of ionic nature. Because of its simplicity, sufficient contrast and resolution the suggested technique is recommended for ultrastructural studies of DNA-containing substrates.

Anisotropic staining of apurinic acid with toluidine blue

Using normal rat liver imprints, studies were carried out on the effects of histone extraction and the formation of aldehyde groups from deoxyribose on anisotropic toluidine blue staining of depurinized DNA after sodium bisulfite treatment. The anisotropic effect of bisulfite was found to be determined by binding of bisulfite ions to the aldehyde groups of apurinic acid which, together with free phosphate groups of DNA ensure coparallel attachment of the dye molecules. It was also shown that at pH 5.0 toluidine blue binds with both the phosphate and aldehyde groups of apurinic acid, to give anisotropic staining.

Feulgen hydrolysis at refrigerator temperature

In order to search for the better FEULGEN hydrolysis conditions, the 2 kinds of hydrolysis with 5 N HCl - at room temperature and at refrigerator temperature - were comparatively studied on rat liver imprints. 2 reactions were used: with the SCHIFF reagent binding to aldehyde groups and with methylene blue staining phosphate groups of DNA. Cytophotometry was coupled with morphological examination of stained nuclei. It was found that 1. cold hydrolysis has no substantial advantage when revealing DNA with the SCHIFF reagent but 2. it has undoubtful profit to reveal DNA, and in particular its acid-labile fraction, when staining with methylene blue. With the cold hydrolysis-methylene blue technique at least 3 categories of DNA with different acid-lability can be revealed and characterized morphologically in rat liver nuclei.

Evaluation of Feulgen reaction performed on unfixed smears

Feulgen reaction--both the original one with Schiff reagent and the modified one with toluidine- or methylene blue, pH = 4.0--can be carried out on air-dried smears without fixing. Hydrolysis--5 n HCl at room temperature should be 15 to 20 min for the original and 5 to 10 min--for the modified reaction. Binding of the dyes is stoichiometric in both cases.