Changes in the Nucleus during Cellular Development in the Pea Seedling

Nuclei were isolated from three regions of the root and fromthe epicotyls of growing pea seedlings. As the dry mass of thenuclei was the same before and after isolation, and as the DNAcontent of the nuclei accounted for the DNA of the cells, theisolated nuclei are assumed to be a random sample of the nucleiin the intact tissues. The DNA, RNA, and protein contents percell were much greater in the epicotyl than in the root, butthe RNA and protein contents of the nucleus were similar inboth epicotyl and root. Although the amounts of DNA, RNA, andprotein per cell increased with increasing distance from theroot tip, increase in the protein content of the nucleus occurredmainly between the meristematic and expanding regions, and atthis same point nuclear RNA decreased. Nuclear volume increasedwith increasing distance from the root tip, whereas nucleardry mass remained virtually unchanged. The nucleus thereforebecomes increasingly hydrated as the cells mature. The datasuggest a changing interaction between the nucleus and the cytoplasmduring cellular development.     

The relationship of DNA synthesis to protein accumulation in the cell nucleus

The relationship between DNA synthesis and protein accumulation in cell nucleus and cytoplasm has been investigated by the use of a combination of ultramicrointerferometric and ultramicrospectrophotometric methods. 5-Fluoro-2'-deoxyuridine (FUdR) inhibited DNA synthesis, resulting in inhibition of cell proliferation in G-1 and early S-phase. However, synthesis and accumulation of protein continued in the presence of FUdR, as indicated by a 54% increase in the average dry mass value per individual cell during 18-hour exposure to FUdR; due primarily to protein accumulation in the cytoplasm, the average cytoplasmic dry mass increased by as much as 85%, while the dry mass of the nucleus increased by only 21%. The dry mass values of individual nuclei were well-correlated to the nuclear DNA content throughout the period of exposure to FUdR. In contrast to the continued accumulation of protein in the cytoplasm during inhibition of DNA synthesis, protein accumulation in the nucleus was inhibited. When cells were released from inhibition of DNA synthesis by the addition of 2'-deoxythymidine, the nuclear DNA content and nuclear dry mass increased in near-synchrony, there being some evidence that DNA synthesis was initiated somewhat prior to initiation of increase in nuclear dry mass. Thus, it appears that DNA synthesis (or an increase in nuclear DNA content) is intimately related to the regulation of protein accumulation in the nucleus.     

Nuclear size control in fission yeast

Along-standing biological question is how a eukaryotic cell controls the size of its nucleus. We report here that in fission yeast, nuclear size is proportional to cell size over a 35-fold range, and use mutants to show that a 16-fold change in nuclear DNA content does not influence the relative size of the nucleus. Multi-nucleated cells with unevenly distributed nuclei reveal that nuclei surrounded by a greater volume of cytoplasm grow more rapidly. During interphase of the cell cycle nuclear growth is proportional to cell growth, and during mitosis there is a rapid expansion of the nuclear envelope. When the nuclear/cell (N/C) volume ratio is increased by centrifugation or genetic manipulation, nuclear growth is arrested while the cell continues to grow; in contrast, low N/C ratios are rapidly corrected by nuclear growth. We propose that there is a general cellular control linking nuclear growth to cell size.     

Cellular and nuclear volume during the cell cycle of NHIK 3025 cells

The distribution of cellular and nuclear volume in synchronous populations of NHIK 3025 cells, which derive from a cervix carcinoma, have been measured by electronic sizing during the first cell cycle after mitotic selection. Cells given an X-ray dose of 580 rad in G1, were also studied. During the entire cell cycle the volume distribution of both cells and nuclei is an approximately Gaussian peak with a relative width at half maximum of about 30%. About half of this width is due to imperfect synchrony whereas the rest is associated with various time invariant factors. During S the mean volume of the cells grows exponentially whereas the nuclear volume increases faster than for exponential kinetics. Hence, although cellular and nuclear volumes are closely correlated, their ratio does not remain constant during the cell cycle. Volume growth during the first half of G1 is negligible especially for nuclei where the growth appears to be closely associated with DNA-synthesis. For unirradiated cells the growth of cellular and nuclear volume is negligible also during G2 + M. In contrast, the X-irradiated cells continue to grow during the 6 hr mitotic delay with a rate that is constant and about half of that observed in late S. Hence, radiation induced mitotic delay does not appear merely as a lengthening of an otherwise normal G2. During G1 and S the irradiated cells were identical to unirradiated ones with respect to all the parameters measured.     

Manipulation of the amount of RNA in post-mitotic nuclei

Because all (or almost all) nuclear RNAs are liberated to the cytoplasm during mitosis and then return to the post-mitotic nuclei, we expected that if cytoplasm were amputated from mitotic cells the post-division nuclei would possess less than normal amounts of RNA. Experiments performed with amebae (A. proteus) show that this is in fact what happens. Furthermore, since the enucleate fragment cut from a mitotic cell possesses an “excess” of returnable nuclear RNAs, a normal interphase nucleus implanted into such mitotic cytoplasm might be expected to acquire above-normal amounts of RNA. Experiments reported here show that this expectation also is realized. Thus, the regulation of the normal nuclear concentration of these RNAs involves mechanisms other than a limited number of intranuclear “binding” sites and most likely is restricted by the rate of synthesis of these RNAs.The demonstration that nuclei can be depleted or enriched for RNAs, many of which are unique to nuclei, makes it possible to determine the consequences for cell metabolism of altered amounts of nuclear RNA. Hopefully, such studies will reveal the function(s) of these RNAs.     

The Nuclear Endoreduplication Cycle in Metaxylem Cells of Primary Roots of Zea mays L.

The nuclear DNA content of metaxylem cells in roots of Zea mayscv. Golden Bantam reaches 16C or 32C by successive rounds ofDNA endoreduplication. Each phase of endoreduplication (endo-S)is separated by a non-DNA synthetic phase (endo-G). These phasesseem to occur in zones at fixed distances from the root tip.The duration of the phases in two of the endoreduplication cycles(4C–8C, 8C–16C) has been estimated in two ways.The first makes use of the rate of movement of cells throughthe positions along the root where the different phases of thecycle are occurring, the second uses labelling with methyl-[³H]thymidineand autoradiography. Both methods indicate that the endo-S phaseswhich cause the nuclear DNA content to rise from 4C to 8C andfrom 8C to 16C last 8–10 h, and that the intervening endo-Gphase lasts 8–12 h. DNA endoreduplication keeps pace withthe increase of nuclear volume; cell volume increases at a morerapid rate, however. Comparison of the endoreduplication cyclein the metaxylem with the mitotic cycle in the adjoining filesof parenchyma cells shows that the mitotic cells complete theircycle more slowly. DNA synthesis, endoreduplication cycle, mitotic cycle, root apex, Zea mays     

Cellular and nuclear volume of human cells during the cell cycle

Summary The volumes of whole cells and nuclei of cultured human cells were studied at different times after synchronization of growth using the Coulter counter and scanning microphotometry. It was found that the increase in cell volume is compatible with both linear or exponential growth during the cell cycle. The growth of the nuclear volume is not correlated with the beginning of the DNA synthesis. The nuclear volume starts to increase already 6 h prior DNA synthesis. The data also indicate that the nuclear volume growth could proceed in two stages. The relation of this result to radiation sensitivity is discussed.This research was carried out under contract no. 215-76-10-BIO-D, Radiation Protection programme of the Commission of the European Community (Publication no. BIO 1747)     

CELLULAR AND NUCLEAR VOLUME DURING THE CELL CYCLE OF NHIK 3025 CELLS

The distribution of cellular and nuclear volume in synchronous populations of NHIK 3025 cells, which derive from a cervix carcinoma, have been measured by electronic sizing during the first cell cycle after mitotic selection. Cells given an X-ray dose of 580 rad in G₁, were also studied. During the entire cell cycle the volume distribution of both cells and nuclei is an approximately Gaussian peak with a relative width at half maximum of about 30%. About half of this width is due to imperfect synchrony whereas the rest is associated with various time invariant factors. During S the mean volume of the cells grows exponentially whereas the nuclear volume increases faster than for exponential kinetics. Hence, although cellular and nuclear volumes are closely correlated, their ratio does not remain constant during the cell cycle. Volume growth during the first half of G₁ is negligible especially for nuclei where the growth appears to be closely associated with DNA-synthesis. For unirradiated cells the growth of cellular and nuclear volume is negligible also during G₂+ M. In contrast, the X-irradiated cells continue to grow during the 6 hr mitotic delay with a rate that is constant and about half of that observed in late S. Hence, radiation induced mitotic delay does not appear merely as a lengthening of an otherwise normal G₂. During G₁ and S the irradiated cells were identical to unirradiated ones with respect to all the parameters measured.     

SOME OBSERVATIONS ON DNA CONTENT AND CELL AND NUCLEAR VOLUME GROWTH IN THE DEVELOPING XYLEM CELLS OF CERTAIN HIGHER PLANTS

List , Albert , Jr . (Douglass Coll., Rutgers U., New Brunswick, N. J.) Some observations on DNA content and cell and nuclear volume growth in the developing xylem cells of certain higher plants. Amer. Jour. Bot. 50(4): 320–329. Illus. 1963.—The developing metaxylem cells of Acorus calamus roots undergo an over-all growth in cell and nuclear volume that may be expressed roughly as a constant ratio of relative growth rates. Within this over-all growth picture, however, there is a periodicity of both nuclear and cell volume growth. Other plants such as Peltandra, Eleocharis, and Dennstaedtia undergo a similar volume growth. Marsilea tracheary elements have an increase in nuclear number per cell by simultaneous divisions. Arisaema metaxylem nuclei go through a series of DNA doublings correlated with nuclear volume doubling and cell volume increase, at least up to the 16- or 32-ploid level. The cells display some tendency to fall into size classes, expressing a pulsation in growth. A fluctuating alternation or stepwise growth of cell and nucleus appears to describe the data more suitably than the allometric growth equation. In Zea, the cell and nuclear volumes for metaxylem cells fit a fluctuating envelope better than the straight line, and there is again the probability that cell volumes fall into size classes related to nuclear volume class. The DNA content of the nuclei was determined to fall into a frequency distribution having peaks at the 4-, 8-, 16-, and 32-ploid equivalent, agreeing with an earlier report for diploid maize. DNA content was highly correlated with nuclear volume in the over-all growth of the metaxylem cells.     

Relation between Water Stress and DNA Synthesis during Germination of Zea mays L.

Mitotic index, percent nuclei in DNA synthesis and the relativeDNA content per nucleus were determined from cells of the Zeamays radicle at various times after the beginning of germination.Nuclear DNA synthesis was initiated after 45 h and mitosis wasfirst observed after 74 h from sowing. Most of the dormant nucleiwere in the pre-synthetic or G₁ phase of the mitotic cycle.By 72 h most cells were in S and 77 h after the beginning ofgermination, the cells of the primary root were observed inall phases of the mitotic cycle. Dehydration of karyopses after45–74 h of imbibition progressively reduced the percentof germination to zero upon dehydration and subsequent replantingdemonstrating that drought sensitivity was related to the onsetof nuclear DNA synthesis and genome duplication.     

The distribution of nuclear and cytoplasmic proteins in the blastoderm of the loach, Misgurnus fossilis L

The concentration of dry substance (protein) and the dry weight of nuclei, cytoplasm and cells from different blastoderm regions at the early blastula and midgastrula stages were determined by interferentional microscopy. It was shown that at the early blastula stage the dry weight of cells in the basal layer is higher than that in the outer layer. Although the protein concentration in the basal layer cells appears to be somewhat higher, differences in their dry weight are due primarily to the big volume of cytoplasm of the basal layer cells. By the midgastrula stage, the total (nucleus + cytoplasm) protein concentration increases (by 17% in the basal layer cells and by 9% in the outer layer cells) due to the increase of nuclear protein concentration. At the same time dry weight of these cells markedly decreases due to the decrease of their volumes in the process of cell divisions. At the midgastrula stage the epiblast cells have the highest dry weight due to the highest protein concentration in the cytoplasm and the biggest cell volume. The results obtained are discussed with respect to the data on the pattern of accumulation of newly synthesized protein in nuclei and cytoplasm with special reference to the duration of individual cell cycle phases.     

Defective control of mitotic and post-mitotic checkpoints in poly(ADP-ribose) polymerase-1(-/-) fibroblasts after mitotic spindle disruption

Poly(ADP-ribose) polymerase-1 (PARP), a DNA damage-responsive nuclear enzyme present in higher eukaryotes, is well-known for its roles in protecting the genome after DNA damage. However, even without exogenous DNA damage, PARP may play a role in stabilizing the genome because cells or mice deficient in PARP exhibit various signs of genomic instability, such as tetraploidy, aneuploidy, chromosomal abnormalities and susceptibility to spontaneous carcinogenesis. Normally, cell cycle checkpoints ensure elimination of cells with genomic abnormalities. Therefore, we examined efficiency of mitotic and post-mitotic checkpoints in PARP-/- and PARP+/+ mouse embryonic fibroblasts treated with mitotic spindle disrupting agent colcemid. PARP+/+ cells, like most mammalian cells, eventually escaped from spindle disruption-induced mitotic checkpoint arrest by 60 h. In contrast, PARP-/- cells rapidly escaped from mitotic arrest within 24 h by downregulation of cyclin B1/CDK-1 kinase activity. After escaping from mitotic arrest; both the PARP genotypes arrive in G1 tetraploid state, where they face post-mitotic checkpoints which either induce apoptosis or prevent DNA endoreduplication. While all the G1 tetraploid PARP+/+ cells were eliminated by apoptosis, the majority of the G1 tetraploid PARP-/- cells became polyploid by resisting apoptosis and carrying out DNA endoreduplication. Introduction of PARP in PARP-/- fibroblasts partially increased the stringency of mitotic checkpoint arrest and fully restored susceptibility to G1 tetraploidy checkpoint-induced apoptosis; and thus prevented formation of polyploid cells. Our results suggest that PARP may serve as a guardian angel of the genome even without exogenous DNA damage through its role in mitotic and post-mitotic G1 tetraploidy checkpoints.     

Studies on the Mitotic Prophase Chromosomal Fibers in Vicia faba

The observations have been made on the structures of mitotic prophase nuclei and chromosomes in Vicia faba root meristematic cells. Two methods, i.e., the cell squashing and the nucleus isolation methods, were applied in present study to prepare the specimen of chromosomes and nuclei. Chromosomal fibers 0.3—0.5 μm in diameter were observed in the squashed preparations stained with Giemsa, and in the isolated nucleus preparations treated with 0.05% EDTA followed by Giemsa staining. Using Feulgen reaction, it has been demonstrated that these fibers are nuclear origin containing DNA. The results suggest that this order of chromosomal fiber may be one structural level in the chromosomes in Vicia faba. This conclusion is in support of the view which holds that there exists an intermediate level of structure between the 250–300Å chromatin fiber and the chromosome.     

Relationship between Endopolyploidy and Cell Size in Epidermal Tissue of Arabidopsis

Relative quantities of DNA in individual nuclei of stem and leaf epidermal cells of Arabidopsis were measured microspectrofluorometrically using epidermal peels. The relative ploidy level in each nucleus was assessed by comparison to root tip mitotic nuclei. A clear pattern of regular endopolyploidy is evident in epidermal cells. Guard cell nuclei contain levels of DNA comparable to dividing root cells, the 2C level (i.e., one unreplicated copy of the nuclear DNA). Leaf trichome nuclei had elevated ploidy levels of 4C, 8C, 16C, 32C, and 64C, and their cytology suggested that the polyploidy represents a form of polyteny. The nuclei of epidermal pavement cells were 2C, 4C, and 8C in stem epidermis, and 2C, 4C, 8C, and 16C in leaf epidermis. Morphometry of epidermal pavement cells revealed a direct proportionality between nuclear DNA level and cell size. A consideration of the development process suggests that the cells of highest ploidy level are developmentally oldest; consequently, the developmental pattern of epidermal tissues can be read from the ploidy pattern of the cells. This observation is relevant to theories of stomate spacing and offers opportunities for genetic analysis of the endopolyploidy/polyteny phenomenon.     

Preparation of isolated cells by alkaline dissociation of formalin fixed tissue]

A procedure is described for preparation of isolated cells by treating formaldehyde fixed tissues with a 50%-solution of KOH. This results in complete yield of cells from a variety of organs (liver, kidney, heart, spleen, etc.). The alkali-treated cells entirely retain their morphological and tinctorial peculiarities. It was shown that preparations derived from alkali-treated tissues were useful for a series of quantitative cytological and cytochemical techniques: cytofluorometric estimation of nuclear DNA; interferometric determination of dry cell mass; autoradiographic studies of nuclear DNA synthesis; cell number counts; evaluation of cell distribution according to the number of their nuclei; estimation of the mitotic index.     

Mitotic cycle time and DNA content in annual and perennialMicroseridinae (Compositae,Cichoriaceae)

Within eight annual and perennialMicroseridinae species studied, the duration of the mitotic cycle is positively correlated with the nuclear DNA content, cycle time (hrs) = 7.3 + 0.32 × pg DNA/nucleus. Within the generaAgoseris andMicroseris, the annuals have lower DNA contents and more rapid mitotic cycle times than do the perennials. This relationship is predicted by the nucleotypic theory ofBennett. Annual species ofPyrrhopappus have relatively high DNA contents and a proportionately longer mitotic cycle time, but contrary to that expected by the nucleotypic theory as originally proposed have the fastest growth rate and shortest generation time observed in theMicroseridinae. This rapid developmental rate is discussed, nucleotypically, however, by analyzing relationships between DNA content, mitotic cycle time, and cell size.     

Patterns of Nuclear and Nucleolar Growth in Synchronously Dividing Explants from Tubers of Helianthus tuberosus L.

The nucleus and nucleolus have been examined by phase contrastmicroscopy of isolated fixed nuclei from synchronously dividingcells of Helianthus tuberosus L. tuber explants grown in nutrientmedium on filter paper. The volumes of nuclei and nucleoli werecomputed from their areas and perimeters obtained by digitizingimages projected from film. The nuclei did not show a pattern of growth related to the Sphase but enlarged at times of both de-differentiation and differentiation.There was also rapid post-mitotic nuclear enlargement. The sizeattained by nuclei in the three successive divisions followingcell activation decreased progressively, but started to riseagain at the time of cell differentiation. The changes are discussed in relation to nuclear size regulation,the nuclear matrix and hypotheses relating nuclear growth toDNA, protein and water in the processes of de-differentiation,mitosis and differentiation. Nucleoli showed a clear fusion and growth cycle. The patternof fusion can be used to identify the position of a sample ofcells, though not any particular cell, within the cycle. Nucleolargrowth was different in the succeeding cell cycles that wereinduced in the de-differentiating tissue. Nucleolar enlargementwas slow in the first cycle and continued until mitosis. Therewas rapid nucleolar growth in the second cycle and none in latercycles until the time of cell differentiation. Nucleolar changes are discussed in relation to rRNA gene dosage,replication and polymerase availability. Helianthus tuberosus L. Jerusalem artichoke, isolated-nuclei, tissue culture, cell cycle, nucleolar cycle     

DIPLOIDY IN DNA CONTENT IN VEGETATIVE CELLS OF CLOSTERIUM EHRENBERGII (CHLOROPHYTA)1

DNA content of the nucleus in the placoderm desmid, Closterium ehrenbergii Meneghini was measured throughout the life cycle by epifluorescence microspectrophotometry after DNA specific dye [4′,6-diamidino-2-phenylindol (DAPI)] staining. Postulating a mean DNA content of gamete nuclei as 1C, the nucleus of a newly divided vegetative cell was 2C. Most vegetative cells in the stage of exponential growth had a DNA content from 2C to 4C, while most in stationary phase, with the highest frequency of zygote formation, were 2C. They became pre-gametes (2C) upon mixing two heterothallic strains. Four gametes were made by a DNA reduction division of each pre-gamete cell. Therefore, there was a nonmeiotic DNA reduction stage by one half. During germination, the zygote underwent meiosis to produce two gones, each of which contained one surviving nucleus (large nucleus) and one degenerating nucleus (small nucleus). The DNA content of these four nuclei was 1C basically. The DNA of the surviving nucleus duplicated to 2C and further quadruplicated to 4C without cell or nuclear division. These two 4C gones had different cell morphology from ordinary vegetative cells. After the first cell division following meiosis, each gone produced two vegetative cells in which the DNA content became 2C to 4C again.     

Method of determining the concentration of glycogen, DNA, 3H-thymidine label and dry weight in one and the same cell]

A method is proposed for determination of glycogen, DNA, 3H-thymidine incorporation and dry weight in the same cell, the technique being based on successive discovery and measuring of each of these indices. Cells are obtained from animals, previously injected with 3H-thymidine, to be charted on preparation, made pictures and measured in square units. Then on preparations embedded into glycerine or vaseline oil, the optical path difference of rays for the nucleus and cytoplasm of selected cells is measured with the interferencial microscope. This is followed by the fluorescent PAS reaction and the content of glycogen is registered microfluorimetrically in the same cells. Preparations after that are treated with a freshly prepared water solution of 0.025% borohydride sodium, stained with the routine or fluorescent Feulgen reaction, and DNA content is determined in the same cells in which glycogen and delta delta were previously measured. The stained nuclei are photographed, their areas are measured and the dry weight of the nucleus and cytoplasm of marked cells is calculated from the values of the nuclear areas and of delta delta. Eventually the preparations are covered by emulsion and exposed, and 3H-thymidine-containing nuclei are determined, the index of marked nuclei and the marking intensity over the nucleus are calculated. As a result, a precise and reliable determination of glycogen, DNA, dry weight and 3H- or 14C-thymidine incorporation is made in either of the marked cell.