A rapid and simple staining method, using Toluidine Blue, for analysing mitotic figures in tissue sections

Summary Mitotic index is a clinically important parameter in cancer pathology. We developed a staining method using Toluidine Blue to detect efficiently and rapidly mitotic figures in sections of formalin-fixed paraffin-embedded human and rat tisues. Sections were stained at acid pH with a 0.01% Toluidine Blue solution after removal of RNA with hydrochloric acid or ribonuclease. The optimal pH of the TB staining solution was found to be 4.5 for rat tissues and 3.5 for human tissues. This procedure stained mitotic figures much more intensely than other (extra)cellular structures. A quantitative estimate of the total number of nuclei in the field where mitotic figures were counted, was obtained in an adjacent section hydrolysed in 5 N hydrochloric acid and stained by the Feulgen reaction with a Schiff-type reagent containing 0.01% Toluidine Blue. This method specifically stained interphase and mitotic nuclei and the field cellularity could be quantified by image cytometry. When these procedures were performed on two consecutive serial sections, a mitotic index could be determined accurately by relating the count of mitotic figures to the number of tumour cells.     

Distribution of mitoses within a lobule of the rat liver in recovery after various types of injuries]

The distribution of mitotic activity inside the rat's liver lobe was found to depend on the time that elapsed after the injury. At the early stages, the maximal quantity of mitotic figures in hepatocytes was observed along the periphery of the lobe, being less in the middle parts. At the later stages, mitotic figures were noted around the central veins. With the prolonged injury of the liver, the maximal amount of dividing hepatic cells was localized in the middle sections of the liver.     

Observation on the cycle of the seminiferous epithelium in the Japanese macaque (Macaca fuscata) using semithin sections

The stages of the cycle of the seminiferous epithelium in the Japanese macaque are investigated using testes fixed by a mixture of formaldehyde and glutaraldehyde containing picric acid and embedded in a methacrylate resin, Quetol 523M. Sections, 1.0–2.0 μm in thickness, were cut with glass knives and stained with periodic acid-Schiff (PAS) and hematoxylin. Sections from such resin blocks illustrated cellular detail without structural distortion during the polymerization process. Furthermore, staining affinity with PAS and hematoxylin was excellent. In stained sections, typical germ cell associations were described, based on the nuclear morphology of type A (dark and pale) spermatogonium, type B spermatogonium, various developmental stages of primary spermatocytes during meiosis, and the development of the acrosomic system. In the Japanese macaque, two different steps of spermatids (steps 3 and 4) were constantly seen in the same area of the tubular epithelium during stage III. Therefore, a classification into ten stages is proposed for the cycle in this species. Additional characteristics are described based on the observation of the seminiferous epithelium using semithin sections.     

Morphology and kinetics of spermatogenesis in Xenopus laevis.

The light microscopic characteristics of spermatogenic stages of the germ cell line in the anuran, Xenopus laevis, have been described as they appear in both nuclear squash preparations and plastic embedded thick sections of intact testes. Tritiated thymidine autoradiography was employed to unequivocally identify stages. Using this methodology, it was determined that the premeiotic DNA synthetic period occurs in a cell which is morphologically indistinguishable from a late secondary spermatogonial cell. In addition, kinetic studies with tritiated thymidine were employed to determine the duration of meiotic prophase and spermiogenesis in Xenopus. Results indicate that at 18 degrees C, the most rapidly matururing cells in the testis spend four days in leptotene, six days in zygotene, twelve days in pachytene, one day in diplotene, one day in meiotic division, and twelve days in spermiogenesis. An estimate for the duration of the premeiotic S stage was indirectly calculated from combined data to yield a value of six to seven days. Pooled spermatocyte counts measuring the frequency of occurrence of individual stages produced results which correlated closely with estimates obtained by tritiated thymidine labelling. Individual counts, however, show wide variations between testes from single animals and between testes from different animals, whether sacrificed together or at different times of the year. Nevertheless, in all cases, both morphology and labelling patterns indicate that spermatogenesis is continuously active. The variation observed in individual testes appears to be the result of waves of non-random entry of spermatogonial stem cells into the population of cells irreversibly committed to differentiation.     

Beta-nerve growth factor influences the expression of androgen-binding protein messenger ribonucleic acid in the rat testis.

The effect of infusion of nerve growth factor (NGF) into the rat testis on the expression of androgen-binding protein (ABP) mRNA was studied. A major 1.7-kb and a minor 3.7-kb ABP mRNA were present at all stages of the seminiferous epithelium with maximal levels at stages VIII-XI and the lowest levels at stages IV-VI. Infusion of 15 ng/h of NGF with a mini-osmotic pump for 14 days resulted in a 2-fold increase of ABP mRNA as revealed by Northern blots, whereas the mRNA level of another Sertoli cell protein, urokinase-type plasminogen activator, remained unchanged. Image analysis of autoradiograms obtained by in situ hybridization of sections from treated testes showed a similar increase in APB mRNA compared to noninfused or PBS-infused testes. However, at the cellular level the labeling intensity for ABP mRNA over Sertoli cells of different stages of the seminiferous epithelium was the same in NGF-infused and control testes. This suggests that the increase of ABP mRNA in NGF-infused testes was caused by prolongation of stages VII-VIII with maximal ABP mRNA expression; the suggestion is supported by an increase of 30 percent in frequency of these stages in histological sections from NGF-infused testes.     

Structure and Cytogenesis of the Shoot Apex of Syringa oblata var. affinis Lingelsh

The structure, growth and mitotic activity of 211 shoot apices of developing sprouts of Syringa oblata var. affinis Lingelsh. in longitudinal sections and 67 in transverse sections have been studied with the view to understanding the nature of zonation patterns and cytogenesis of the apical meristems during a double plastochron. The external morphology and the anatomical structure of the apices in 4 plastochronic stage-early, middle, late Ⅰ and late Ⅱ stages are described. In the shoot apices examined, especially those at late plastochronic stage, the following zones may be delimited: Zone of tunica initials, zone of corpus initials, peripheral zone and zone of rib meristem. The location and orientation of mitotic figures observed in longisections of the apices in 4 plastochronic stages are plotted in diagrams and the mitotic frequency has been calculated. Information obtained from these investigations reveals that the tunica and corpus inititals constitute an active region of the apex, but their mitotic activity changes periodically within the double plastochron. In the middle plastochronic stage when the apex is at its minimal area and the cells of peripheral zone and rib meristem zone have been completely transformed into constituent parts of foliar primordia and the subjacent tissues of the stem and the pith mother cells respectively, the mitotic frequency of the initials is at its maximium and its intensity of mitotic activity is not much lower than that of any other meristematic zone at any stage. When the apical dome is reformed by the activity of these initials in late plastochronic stages, the mitotic frequency of the initials gradually drops and the region of high mitotic frequency shifts to the flank of the apex, the peripheral zone. Anticlinal divisions are predominant in this zone. On the other hand, those cells directly left behind by the corpus initials, which constitute the rib meristem, are vacuolated and marked by the pre- dominance of transverse divisions. Thus the entire zonation pattern reappears. In the next early plastochronic stage, the mitotic frequency of the tunica and corpus initials drops to its mimimium, but other regions of the apex still maintain a high mitotic frequency. It may be concluded that the tunica and corpus initials form a cytogenerative center of the shoot, and the cytohistological zonation is actually a result of the fact that different regions of apical meristems are different in mitotic activety, different in state of cell differentiation and different in their function in morphogenesis.     

Mitotic activity and cell degeneration in the mouse thymus over a period of 24 hrs

Summary The mitotic and pyknotic indices were calculated over a period of 24 hrs in four different zones of the mouse thymus (Balb/C). Counts were based on 1 micron sections of Epon-embedded tissue. This technique gives a more accurate mitotic index than has been calculated in the past because mitotic figures in the prophase stage are more easily recognizable. Mitotic as well as pyknotic index showed a distinct diurnal rhythm in the subcapsular zone, the rhythm being less distinct towards the medulla, where no significant diurnal fluctuations were demonstrated. It was shown that the index variations could be correlated to significant variations in the mitotic time.     

Coelomic gonadal epithelia during the period of human embryonic morphologic sex differentiation]

The course of divergent differentiation of coelomic epithelium in the indifferent gonad has been traced up to the stage when morphological sex signs are distinctly seen. Eleven human embryos fixed in Carnoy and Bouin's fluid have been studied from 6 to 10 weeks of gestation. Paraffin sections were stained with hematoxylin, ferric hematoxylin after Heidenhain. Basal membrane fibres were revealed by silver impregnation after Karupu. PAS-reaction after McManus and additional staining with hematoxylin and light green were applied, as well as the reaction for total proteins with bromphenol blue after Miguel--Calvo. Sex differentiation of coelomic epithelium in the gonad developing according to the male type begins a little later than in the ovary. In the epithelium of the forming testis a great amount of mitotic figures is observed that might be connected with the presence of Y-chromosome stimulating cells for extra mitotic cycles. The increasing presence of Y-chromosome stimulating cells for extra mitotic cycles. The increasing number of mitotic figures in the epithelium should be considered as a sign demonstrating that differentiation according to the male type has started. Superficial epithelium of the embryonic ovary has a peculiar false pseudostratified structure. This secures cellular reserve for the ovarian cortex formation from the external epithelium. The apical surface of the cells in the external epithelium has a border which is evidently formed by microvilli and revealed by PAS-reaction and bromphenol blue. Ovarian follicular cells and Sertoli's cells (sustentocytes) in testis have the common origin in the human fetus--from coelomic epithelium of the gonad germ.     

A selective stain for mitotic figures, particularly in the developing brain

A selective stain for mitotic figures is valuable where autoradiographic counting is not required, especially in the developing brain. Most work in this field has been based on conventional nuclear stains which do not differentiate mitotic figures from resting cells by color. Hematoxylin, Feulgen, gallocyanin and Nissl methods have been used particularly. The method described uses a modified Bouin fixative, followed by hydrolysis in 1 N HCl. Mitotic figures are selectively stained using crystal violet, with nuclear fast red as the counterstain for resting cells. The method has been tested using material from postnatal and fetal sheep, guinea pig and rat. Using paraffin mounted serial sections it is applicable to all organs. The method was very successful on developing rat brain, particularly for detail and quantitative estimation in the early stages of prenatal development, which was of primary interest. Nucleated cells of the erythrocytic series, keratin and what appear to be mast cells were found to stain. When nuclear counting or cell recognition were required these did not cause any difficulty, except in prenatal liver. The highly selective method presented stains mitotic figures, in all tissue tested, an intense blue against a background of red resting cells.     

A Selective Stain for Mitotic Figures, Particularly in the Developing Brain

A selective stain for mitotic figures is valuable where autoradiographic counting is not required, especially in the developing brain. Most work in this field has been based on conventional nuclear stains which do not differentiate mitotic figures from resting cells by color. Hematoxylin, Feulgen, gallocyanin and Nissl methods have been used particularly. The method described uses a modified Bouin fixative, followed by hydrolysis in 1 N HCl. Mitotic figures are selectively stained using crystal violet, with nuclear fast red as the counterstain for resting cells. The method has been tested using material from postnatal and fetal sheep, guinea pig and rat. Using paraffin mounted serial sections it is applicable to all organs. The method was very successful on developing rat brain, particularly for detail and quantitative estimation in the early stages of prenatal development, which was of primary interest. Nucleated cells of the erythrocytic series, keratin and what appear to be mast cells were found to stain. When nuclear counting or cell recognition were required these did not cause any difficulty, except in prenatal liver. The highly selective method presented stains mitotic figures, in all tissue tested, an intense blue against a background of red resting cells.     

Scoring mitotic activity in longitudinal sections of crypts of the small intestine

Various counts have been made of the number of mitotic figures in whole crypts and sections of crypts of the small intestine of the mouse. Samples were analysed from animals killed at different times of the day and at different times after administration of vincristine. Measurements have been made of the size of mitotic and interphase nuclei and of the radial position of mitotic figures. The correction factor, f, which is required to take into account the enhancement of mitotic counts in sections as a consequence of their centripetal position has been investigated. The results indicate the following: (1) transverse sections of the crypt differ from longitudinal sections if they involve cutting the intestine before fixation which may result in a relaxation of the crypt and its widening by 25%; (2) columnar cell nuclei have a shape that resembles a sphere flattened so that the average diameter is 20% greater in crypt transverse sections; (3) mitotic nuclei tend to be about half-way between the crypt edge and the central axis of the crypt; (4) between about four and seven times more mitotic figures have their mitotic axis parallel to the long axis of the crypt; (5) about one-third of all mitotic figures in a crypt are seen in a longitudinal section of the crypt. If this is related to the number of cells in the crypt as a whole and in a section, a correction factor fD for the mitotic index of 0.59 is obtained; (6) the correction factor fT derived from the shape and position of the mitotic figures measured in 3 microns longitudinal sections is 0.53; (7) relating cell cycle and mitotic accumulation data using a computer-based model of the crypt also permits a correction factor fmod to be estimated. This gives a value of 0.66. When sectioned material is used to calculate a mitotic index the most appropriate correction factor is fD; for mouse small intestine it is 0.59.     

Scoring Mitotic Activity In Longitudinal Sections of Crypts of the Small Intestine

Abstract. Various counts have been made of the number of mitotic figures in whole crypts and sections of crypts of the small intestine of the mouse. Samples were analysed from animals killed at different times of the day and at different times after administration of vincristine. Measurements have been made of the size of mitotic and interphase nuclei and of the radial position of mitotic figures. the correction factor, f, which is required to take into account the enhancement of mitotic counts in sections as a consequence of their centripetal position has been investigated. the results indicate the following: (1) transverse sections of the crypt differ from longitudinal sections if they involve cutting the intestime before fixation which may result in a relaxation of the crypt and its widening by 25%; (2) columnar cell nuclei have a shape that resembles a sphere flattened so that the average diameter is 20% greater in crypt transverse sections; (3) mitotic nuclei tend to be about half-way between the crypt edge and the central axis of the crypt; (4) between about four and seven times more mitotic figures have their mitotic axis parallel to the long axis of the crypt; (5) about one-third of all mitotic figures in a crypt are seen in a longitudinal section of the crypt. If this is related to the number of cells in the crypt as a whole and in a section, a correction factor f_d for the mitotic index of 0.59 is obtained; (6) the correction factor f_T derived from the shape and position of the mitotic figures measured in 3 μm longitudinal sections is 0.53; (7) relating cell cycle and mitotic accumulation data using a computer-based model of the crypt also permits a correction factor f_mod to be estimated. This gives a value of 0.66. When sectioned material is used to calculate a mitotic index the most appropriate correction factor is f_D; for mouse small intestine it is 0.59.     

Mitosis in embryonic trisomy 1 mouse eye

Trisomy 1 embryos consistently show eye defects (e.g., aphakia, microphakia, retention of lens stalk). To determine if the plane of division of mitotic figures is abnormal in the eyes of these animals, trisomic embryos (9.5 through 12 gestational days) were produced from mice doubly heterozygous for Robertsonian translocation chromosomes [Rb(1.3)/Rb(1.10)]. To accommodate for the known delay in trisomic embryo development, animals were grouped according to stages of eye development rather than to gestational age. Serial sections were evaluated without knowledge of karyotype for orientation of mitotic figures (parallel, perpendicular, oblique) in lens, optic cup, and diencephalon. Location of mitotic figures was scored as apical (nearest the lumen), middle, and basal. Numerous anomalies were noted in trisomic eye development. No difference was found between orientation of mitotic figures in the lens and optic cup of trisomy 1 and normal embryos. Location of mitotic figures in trisomy 1 lens was significantly different from that of normal littermates. The data confirm earlier studies that trisomy 1 affects the eye, and they tend to corroborate evidence that this trisomy affects the lens more than it affects the optic cup.     

The effects of vinblastine in assessment of the influence of age on proliferative activity of murine palate and footpad epithelium

Abstract
Data concerning changes in the rate of cell proliferation of stratified epithelia with increasing age are conflicting. In the present study young (3-month-old) and old (22-month-old) C57B1/6NNia male mice were injected intraperitoneally with 2, 3, 4 or 8 mg vinblastine sulfate/kg body weight and killed after 1.5, 3, 4.5 or 6 h. The number of arrested metaphase figures per 1000 basal cells was counted in histological sections. Data were analysed using a multivariate analysis of variance. There was a significant difference between the accumulation of mitotic figures in footpad epidermis and palate epithelium and both tissues contained an increased number of mitotic figures with increasing periods of accumulation at all dose levels. In the footpad epidermis neither the age of the animal nor the dose of vinblastine had a significant effect on the number of mitotic figures. In contrast, for palate epithelium the accumulation of mitotic figures was significantly less in the old mice compared with the young mice and at a dose of vinblastine of 2mg/kg compared with the higher doses. There was a statistically signifycant interaction between the dose of vinblastine and its period of action. It was concluded that the different tissues manifest a differential sensitivity to vinblastine and that only palate epithelium showed a significant reduction in proliferative activity with age.     

Morphology of preovulatory bovine follicles as related to oocyte maturation

Thirty-three preovulatory bovine oocytes and their follicles were collected during the period of final maturation in normally cyclic cows. Cell density of the membrana granulosa, mitotic index of the membrana granulosa, and the occurrence of eosinophylic granulocytes around the basal membrane as well as the maturational stage of the oocyte were determined. Cell density decreased during the period of final maturation. Mitotic indices also decreased after an initial high level in the first hours of the final maturation. Eosinophylic granulocytes were only seen during the last hours of final maturation. The maturational stages of the oocytes were related to distinct maturational stages of the follicular wall as determined by morphological characteristics. We propose a scoring system for the maturity of the follicular wall based on cell density, presence of mitotic figures and the presence of eosinophylic granulocytes outside the vascular compartment.     

Visualization of chromosome assembly during the S and G2 stages of the cycle and chromosome disassembly during the G1 stage in semithin sections of mouse duodenal crypt cells and other cells

Previous examination of dividing cells in the isthmus of the mouse pyloric antrum by using semithin (0.5-micron-thick) Epon sections revealed that the prophasic condensation of chromosomes began early in the DNA-synthesizing (S) stage. In order to examine whether the same observation could be made in other proliferating cell types, the crypt base columnar cells in mouse duodenum and the hepatocytes of the rat 48 hr after partial hepatectomy were investigated by morphologic and radioautographic techniques. When crypt base columnar cells were studied in semithin Epon sections, the four phases of mitosis showed the characteristic features described by classical cytologists. Moreover, the proportion of cells in prophase and telophase was high. To relate the mitotic phases to the stages of the cell cycle, the "frequency of labeled mitoses method" provided the duration of the cell cycle, 12.3 hr, and of the S stage, 7.3 hr. From the frequency of the occurrence of mitotic phases, it was estimated that metaphase lasted 0.3 hr and anaphase 0.11 hr, in line with previous estimates. However, the durations of prophase and telophase were long, 5.9 and 1.9 hr, respectively. The whole mitotic process took over 8 hr. From the duration of prophase and cycle stages, it was calculated that 67% of the S stage was occupied by prophasic cells. In fair agreement with this estimate, 68% of the labeled cells 10 min after a 3H-thymidine injection were found to be in prophase. In regenerating hepatocytes, the morphological features and frequency of prophase and telophase cells were similar to those observed in duodenal crypt cells. While the cycle time was not measured and, therefore, the duration of cycle stages and mitotic phases could not be estimated, it is likely that their duration would be of the same order of magnitude. In conclusion, the mitotic process in duodenal crypt cells takes over 8 hr. Moreover, the crypt cells, like antral isthmal cells, show features of early prophase soon after they enter the S stage of the cycle.     

Seasonal anatomical variations in the testes of European pike, Esox lucius L.

The seasonal development of the testes in European pike was examined using wild fish and biopsies from pike housed in tanks. The size of the tubules and the different cell types were measured and their histological appearance described. Four stages of development can be distinguished during the annual cycle. They are: (I) the stage of rest from June to August; (II) the stage of development from September to November with intensive spermatogenesis; (III) the stage of maturity from December to March/April with spermatogenesis completed; and (IV) the post-spawning stage from March to May.     

Stages and duration of spermatogenesis in the domestic ferret (Mustela putorius furo)

Classification of seminiferous tubules is the basis for understanding normal and abnormal spermatogenesis. The aim of the present study was to determine spermatogenic stages and the duration of the cycle in the domestic ferret using bromodeoxyuridine (BrdU) as a tracer. Eleven adult male ferrets that were maintained in a breeding condition were used. Testicular sections were stained with the periodic acid-Schiff reaction for light microscopy. To determine the cycle duration, six ferrets were injected intraperitoneally with BrdU, and testes were collected 3h later and 10 days and 3h later. BrdU was detected by immunohistochemistry. Seminiferous tubules were classified into eight stages, and frequencies of stages I-VIII were 10.6, 2.2, 7.9, 13.1, 22.3, 21.9, 14.0 and 8.0%, respectively. The most advanced BrdU-labeled cells at 3h post-injection were leptotene spermatocytes in stage VI and those at 10 days and 3h were pachytene spermatocytes in stage V. From differences in stage frequency and BrdU staining frequency between two time points, the duration of one cycle was estimated to be 13.0 days. The present observations indicate that stages and the cycle duration of the ferret spermatogenesis are similar to those reported in other carnivores.     

Preservation of hepatocyte plasma membrane domains during cell division in situ in regenerating rat liver

We have utilized antibodies against five domain-specific integral proteins of the rat hepatocyte plasma membrane to examine the fates of the plasma membrane domains during hepatocyte division in the regenerating rat liver. The proteins were quantified on immunoblots of liver homogenates prepared during the peak of hepatocyte mitotic activity, 28-30 hr after two-thirds hepatectomy. Two sinusoidal/lateral proteins, CE 9 and the asialoglycoprotein receptor, and one bile canalicular protein, dipeptidylpeptidase IV, were not changed significantly in amount; whereas one sinusoidal/lateral protein, the epidermal growth factor receptor, and one bile canalicular protein, HA 4, were reduced to less than or equal to 50% of control levels. Light microscopic examination of plastic sections of regenerating liver tissue revealed that the mitotic hepatocytes generally appeared to retain normal contacts with neighboring interphase hepatocytes. Immunofluorescence was used to localize the domain-specific proteins on mitotic hepatocytes identified in 0.5-micron frozen sections of 28- to 30-hr regenerating liver tissue. Independent of mitotic stage, the hepatocytes retained mutually exclusive bile canalicular and sinusoidal/lateral domains, as defined at the molecular level by the distributions of specific proteins, such as HA 4 and CE 9, respectively.     

Effects of methylmercury on the morphogenesis of the rat cerebellum

Developing rat cerebellums were examined following continuous methylmercury exposure via maternal drinking water at 12.5 ppm during gestation and the suckling period. The continuous exposure resulted in reductions of the total cerebellar cell population and higher mercury tissue burdens than previous acute-dose studies. Cell necrosis was not evident, but rather alterations in the pattern of mitotic figures were observed. A decreased number of cells in the methylmercury exposed cerebellums was associated with an increased number of mitotic figures in the early stages of mitosis and a decrease in the number in the middle and late stages. These in vivo exposure observations are consistent with in vitro cell cycle studies in which the cells were found to have accumulated in G2 and early M phases. Impaired cell proliferation is suggested to be a major mechanism of developmental neurotoxicity following continuous low-dose exposure to methylmercury.