Rabl's model of the interphase chromosome arrangement tested in Chinise hamster cells by premature chromosome condensation and laser-UV-microbeam experiments

Summary In 1885 Carl Rabl published his theory on the internal structure of the interphase nucleus. We have tested two predictions of this theory in fibroblasts grown in vitro from a female Chinese hamster, namely (1) the Rabl-orientation of interphase chromosomes and (2) the stability of the chromosome arrangement established in telophase throughout the subsequent interphase. Tests were carried out by premature chromosome condensation (PCC) and laser-UV-microirradiation of the interphase nucleus. Rabl-orientation of chromosomes was observed in G1 PCCs and G2 PCCs. The cell nucleus was microirradiated in G1 at one or two sites and pulse-labelled with ³H-thymidine for 2h. Cells were processed for autoradiography either immediately thereafter or after an additional growth period of 10 to 60h. Autoradiographs show unscheduled DNA synthesis (UDS) in the microirradiated nuclear part(s). The distribution of labelled chromatin was evaluated in autoradiographs from 1035 cells after microirradiation of a single nuclear site and from 253 cells after microirradiation of two sites. After 30 to 60h postincubation the labelled regions still appeared coherent although the average size of the labelled nuclear area fr increased from 14.2% (0h) to 26.5% (60h). The relative distance dr, i.e. the distance between two microirradiated sites divided by the diameter of the whole nucleus, showed a slight decrease with increasing incubation time. Nine metaphase figures were evaluated for UDS-label after microirradiation of the nuclear edge in G1. An average of 4.3 chromosomes per cell were labelled. Several chromosomes showed joint labelling of both distal chromosome arms including the telomeres, while the centromeric region was free from label. This label pattern is interpreted as the result of a V-shaped orientation of these particular chromosomes in the interphase nucleus with their telomeric regions close to each other at the nuclear edge. Our data support the tested predictions of the Rabl-model. Small time-dependent changes of the nuclear space occupied by single chromosomes and of their relative positions in the interphase nucleus seem possible, while the territorial organization of interphase chromosomes and their arrangement in general is maintained during interphase. The present limitations of the methods used for this study are discussed.Part of this work is included in the doctoral thesis of H. Baumann to be submitted to the Faculty of Biology of the University of HeidelbergPart of this work is included in the doctoral thesis of V. Teuber to be submitted to the Faculty of Medicine of the University of Freiburg i. Br.     

Features of interactions of p68 anchorosomal protein with the nuclear envelope in the cell cycle

Chromatin associated with the nuclear envelope appears in the interphase nuclei as a layer of anchorosomes, granules 20-25 nm in diameter. The fraction of chromatin directly associated with the nuclear envelope is resistant to decondensation, shows a low level of DNA methylation, and contains specific acid-soluble proteins. However, mechanisms underlying the interaction of chromatin with the nuclear envelope are not fully understood. Specifically, it is not known whether anchorosomes are permanent structures or if they undergo reversible disassembly during mitosis, when contacts between chromatin and the nuclear envelope are destroyed. We obtained immune serum recognizing a 68 kDa protein from the nuclear envelopes fraction and studied the localization of this protein in interphase and mitotic cells. We show that this protein present in the NE/anchorosomal fraction does not remain bound with chromosomes during mitosis. It dissociates from chromosomes at the beginning of the prophase and then can be identified again at the periphery of the newly forming nuclei in the telophase.     

In situ hybridization as a rapid means to assess meiotic pairing and detection of alien DNA transfers in interphase cells of wide crosses involving wheat and rye

Summary The objectives of this study were to determine if biotin-labelled total genomic DNA of rye (Secale cereale L.) could be used to (i) preferentially label rye meiotic chromosomes in triticale and (ii) detect translocation stocks at interphase and/or early prophase by in situ hybridization. Welsh triticale, a wheat-rye segmental amphiploid, and Kavkaz wheat, a wheat-rye translocation were used. The results indicated that labelled chromosomes of rye and unlabelled chromosomes of wheat could be observed throughout all meiotic stages in the triticale. For Kavkaz wheat, the presence of the translocated 1RS chromosome arm of rye was detected at the interphase or very early prophase stage. Rapid assessment of feasibility of gene transfers and detection of alien DNA in somatic cells at the interphase stage by in situ hybridization allows for rapid decision-making and saves time and expense in plant breeding programs.Plant Research Centre Contribution No. 1276     

The position of chromosomes at metaphase in human fibroblasts and their DNA synthesis behaviour

The peripheral location of H³-thymidine labelled chromosomes in spreads of colcemid blocked metaphases from human fibroblasts has been investigated in several karyotypes. Chromosomes show non-random distribution in relation to the periphery of the plate. Longer chromosomes are significantly more peripheral than smaller chromosomes. Those chromosomes which contain large amounts of late-synthesising DNA (Y, 18 and 13) are significantly more peripheral than early synthesising chromosomes of similar length (21–22, 19–20 and 14–15). These locations are compared with those from peripheral leucocytes obtained by other workers. When location and grain number of homologues of nos. 1, 2, 3, 16 and late-X are compared it was found that in late-S labelled cells, the more peripheral of each pair was significantly more heavily labelled; in early-S labelled cells the reverse was the case. Location and patterns of labelling between late-X homologues of XXXXY cells showed that peripheral location was related to more delay in DNA synthesis. These results are discussed in terms of peripheral and central interphase distribution of condensed chromatin. It is concluded that the apparent asynchrony of replication of homologues is principally the result of different degrees of condensation of the chromatin in the late-S phase at the time of synthesis, and these differences are related to the proximity to the nuclear membrane.     

Aspects of Interaction of Putative Anchorosomal Protein p68 with the Nuclear Envelope during the Cell Cycle

In the interphase nucleus, the chromatin associated with the nuclear envelope is represented by a layer of anchorosomes, granules with a diameter of 20–25 nm. Biochemically, the fraction of chromatin directly associated with the nuclear envelope is characterized by resistance against decondensing influences, a low level of DNA methylation, and presence of specific acid-soluble proteins. However, the mechanisms lying at the base of chromatin-nuclear envelope interaction have been insufficiently studied. Specifically, it is unknown whether anchorosomes are constant structures or subject to reversible disassembly, when the contacts between chromatin and nuclear envelope are destroyed. We obtained immune serum recognizing a 68 kDa protein from the nuclear envelopes fraction and studied the localization of this protein in interphase and mitotic cells. We show that this protein, present in the NE/anchorosomal fraction, does not remain bound with chromosomes during mitosis. It dissociates from chromosomes at the beginning of the prophase and then can be identified again at the periphery of the newly forming nuclei in the telophase.     

RABL DISTRIBUTION OF INTERPHASE AND PROPHASE TELOMERES IN ALLIUM CEPA NOT ALTERED BY COLCHICINE AND/OR ULTRACENTRIFUGATION

Neither colchicine nor ultracentrifugation, singly or in sequence, significantly alters the normal Rabl distribution of interphase or prophase telomeres in root tip cells of Allium cepa L. The position of telomeres was determined by C-banding, which stains A. cepa chromosomes only at the telomeres. Centrifugation displaces mitotic figures toward one side of the cell, but otherwise their mitotic configurations are little changed. These light microscope results are interpreted to show that a) interphase and prophase telomeres are attached strongly to some component of the nuclear envelope; b) a colchicine-sensitive component apparently does not attach interphase and prophase telomeres to the nuclear envelope; and c) chromosomes at all stages of the cell cycle are attached to some structure, nuclear envelope, and/or spindle fibers.     

PROPHASING OF INTERPHASE NUCLEI AND INDUCTION OF NUCLEAR ENVELOPES AROUND METAPHASE CHROMOSOMES IN HELA AND CHINESE HAMSTER HOMO- AND HETEROKARYONS

Fusing human HeLa metaphase cells with HeLa interphase cells resulted within 30 min in either of two phenomena in the resultant binucleate cell: either prophasing of the interphase nucleus or formation of a normal-appearing nuclear envelope around the metaphase chromosomes. The frequency of either occurrence was strongly dependent on environmental pH. At pH's of 6.6–8.0, prophasing predominated; at pH 8.5 nuclear envelope formation predominated. Additionally, the frequencies of the two events in multinucleate cells depended on the metaphase/interphase ratio. When the ratio was 0.33 nuclear envelope formation predominated; when it was 2.0 prophasing predominated. In their general features, the results with fused HeLa cells resembled those reported earlier with fused Chinese hamster Don cells. However, the results provided an indication that between pH 6.6 and 8.0 the HeLa metaphase cells possessed a much greater capacity than the Don metaphase cells to induce prophasing. Fusion of Don metaphase cells with HeLa interphase cells or of Don interphase cells with HeLa metaphase cells at pH 8.0 resulted in nuclear envelope formation or prophasing in each kind of heterokaryon. As in the homokaryons, the frequencies of the two events in the heterokaryons depended on the metaphase/interphase ratio. The statistics of prophasing and nuclear envelope formation in the homo- and heterokaryon populations were consistent with the notion that disruption or formation of the nuclear envelope depends on the balance attained between disruptive and formative processes.     

Reversible chromosome condensation induced in Drosophila embryos by anoxia: visualization of interphase nuclear organization

We have studied the morphology of nuclei in Drosophila embryos during the syncytial blastoderm stages. Nuclei in living embryos were viewed with differential interference-contrast optics; in addition, both isolated nuclei and fixed preparations of whole embryos were examined after staining with a DNA-specific fluorescent dye. We find that: (a) The nuclear volumes increase dramatically during interphase and then decrease during prophase of each nuclear cycle, with the magnitude of the nuclear volume increase being greatest for those cycles with the shortest interphase. (b) Oxygen deprivation of embryos produces a rapid developmental arrest that is reversible upon reaeration. During this arrest, interphase chromosomes condense against the nuclear envelope and the nuclear volumes increase dramatically. In these nuclei, individual chromosomes are clearly visible, and each condensed chromosome can be seen to adhere along its entire length to the inner surface of the swollen nuclear envelope, leaving the lumen of the nucleus devoid of DNA. (c) In each interphase nucleus the chromosomes are oriented in the "telophase configuration," with all centromeres and all telomeres at opposite poles of the nucleus; all nuclei at the embryo periphery (with the exception of the pole cell nuclei) are oriented with their centromeric poles pointing to the embryo exterior.     

Chromosome ends and the nuclear envelope at premeiotic interphase in the male grasshopper Brachystola magna by 3-D,E.M. reconstruction

During premeiotic interphase in the male grasshopper Brachystola magna the nucleus is divided into two nuclear envelope bound compartments, one containing the X chromosome and one the autosomes. — The autosomal compartment is characterized by an invaginated nuclear envelope with nuclear pores distributed throughout the envelope. In a polarized region of the cell the pericentric heterochromatic chromocenters are associated with the inner membrane of the envelope invaginations. In this species the chromosomes are telocentric (acrocentric?) and the pericentric heterochromatin marks the proximal chromosome ends. It is concluded that the chromosome ends are attached to the nuclear envelope at premeiotic interphase. — Comparisons are made between the present observations on chromosome arrangements and the nuclear envelope at premeiotic interphase to earlier observations at early meiotic prophase in the same species (Church, 1976). It is concluded that a rearrangement of both the proximal chromosome ends and the nuclear envelope occurs as cells enter meiotic prophase.     

Electron-radioautographic analysis of 3H-thymidine distribution in the cell nuclei of the Chinese hamster

Three types of the label localization in the nuclei of Chinese hamster fibroblasts, growing for 9 and 13 hours with 3H-thymidine, were detected using electron microscopic autoradiography: 1. The label is relatively evenly distributed throughout the karyoplasm. 2. Silver grains are concentrated as stripes through the nucleus; a high label density is also found in the nuclear periphery and around the nucleolus. 3. The label is mainly concentrated over the condensed chromatin adjacent to the nuclear membrane. The cells labeled in the first half of S-phase and selected with colchicine in postsynthetic phase of the 1st and the 2nd cycles are characterized by the second and third types of label distribution. In the cell nuclei fixed in the postsynthetic period of the second cycle, the label localization in stripes is discontinuous. The results indicate that during cell transition from S to G2 the newly-synthetized DNA changes its localization in the nucleus. It is suggested that the second type of label distribution depends on the interphase chromosome concentration in definite zones of the nuclear volume after S-phase termination, and the third type label localization is connected with the formation of prophase chromosomes.     

The redistribution of a conserved nuclear envelope protein during the cell cycle suggests a pathway for chromosome condensation

We describe a human autoantiserum that recognizes specific determinants present both on the nuclear envelope of interphase cells and the periphery of metaphase chromosomes. These determinants are highly conserved through evolution and present on a protein with an apparent molecular weight of 33,000. This 33 kd protein, which we call "perichromin," appears to be directly or indirectly bound to both interphase and metaphase DNA. Studies of the transformation of perichromin from a nuclear envelope association to a perichromosomal position during prophase suggests a pathway for chromosome organization throughout the cell cycle.     

Long duration of mitosis and consequences for the cell cycle concept, as seen in the isthmal cells of the mouse pyloric antrum. II. Duration of mitotic phases and cycle stages, and their relation to one another

The kinetics of isthmal cells in mouse antrum were examined in three ways: the duration of cell cycle and DNA-synthesizing (S) stage was measured by the 'fraction of labelled mitoses' method; the duration of interphase and mitotic phases was determined from how frequently they occurred; and mice were killed at various intervals after an intravenous injection of 3H-thymidine to time the acquisition of label by the various phases of mitosis. The duration of the isthmal cell cycle was found to be 13.8 hr and that of the DNA-synthesizing (S) stage, 5.8 h. Estimates for the duration of the G1 and G2 stages were 6.8 and 1.0 hr, respectively. From the frequency of mitotic phases, defined as indicated in the preceding article (El-Alfy & Leblond, 1987) and corrected for the probability of their occurrence, it was estimated that prophase lasted 4.8 hr; metaphase, 0.2 hr; anaphase, 0.06 hr and telophase, 3.3 hr, while the interphase lasted 5.4 hr. In accordance with this, the duration of the whole mitotic process was 8.4 hr. Ten minutes after an intravenous injection of 3H-thymidine, 38% of labelled isthmal cells were in interphase and 62% in early or mid prophase, while cells in late prophase and other mitotic phases were unlabelled. After 60 min, label was in late prophase, after 120 min, in mid telophase and after 180 min, in late telophase. We conclude that there is overlap between some mitotic phases and cycle stages. Thus, while nuclei are at interphase during the early third of S, they are in prophase during the late two-thirds as well as during G2. Also, nuclei are in telophase during the early half of G1 but at interphase during the late half. Differences in nuclear diameter show that subdivision of both S and G1 into early and late periods is practical.     

Neuroblastoma double minutes isolated by pulsed-field gel electrophoresis without prior strand-cleaving treatments

In a human neuroblastoma line, minute chromosomes were separable from the bulk of interphase nuclear DNA by contour-clamped homogeneous electric field (CHEF) gel electrophoresis. The minute chromosomes showed a homogeneous size of approximately 3 Mbp and contained amplified N-myc genes. Fractionation was accomplished without prior strand-cleaving treatment of the DNA, indicating that at least a portion of the minute chromosomes exist as free entities in the interphase nuclei. Human alphoid satellite DNA sequences were also detected in the 3-Mbp band. It is possible that alphoid sequences are contained in the constricted central region that joins these double minutes.     

Comparative study of human chromosome replication in primary cultures of embryonic fibroblasts and in cultures of peripheral blood leucocytes

By autoradiography with ³H-thymidine and ³H-deoxycytidine it is shown that chromosomes 1 and 16 in cultures of embryonic fibroblasts at the termination of the S period synthesise AT- and GC-rich DNA at different rats: in both chromosomes the labelling of AT-bases is more intensive. In leucocyte cultures both nucleotide pairs label equally in these chromosomes. Chromosomes 2, 3, 4–5 and 21–22 are labelled equally in both cultures with respect to AT-and GC-pairs. Fibroblasts and leucocytes differ in the relative intensity of DNA synthesis at the end of the S period: chromosomes 1,16 and 21–22 contain more label in the case of fibroblasts (chromosome 1 solely due to AT-pairs) and chromosome 4–5 in the case of leucocytes. Analysis of distribution of late label along chromosome 1 showed that in fibroblast cultures the pericentromeric regions of both arms are labelled more intensively in respect to both nucleotide pairs than in leucocyte cultures. Both in fibroblast and leucocyte cultures no significant distinctions in the distribution of AT-and GC-pairs along chromosome 2 were established. In fibroblast cultures the pericentromeric regions of both arms of chromosome 3 are labelled more intensively than other regions. In leucocyte cultures the pericentromeric region of the short arm of this chromosome is labelled with the same intensively as in fibroblasts, whereas in the pericentromeric region of the long arm the intensity of incorporation of labelled synthesis precursors decreases. — Analysis of results obtained in the present study together with data of previous studied (Slesinger et al., 1974; Lozovskaya et al., 1976; Lozovskaya et al., 1977) shows that differences between the two types of cells in the intensity of late ³H-thymidine labelling in the C-heterochromatin regions of chromosomes 1 and 16 may be explained both by variation of replication time in leucocytes as compared with fibroblasts and by variation of the content of AT- rich DNA. Differences observed in other chromosomes are probably due to different times of replication of these chromosomes in leucocytes and fibroblasts. — Thus, the process of cell system differentiation involves not only differential activity of the genome (the main mechanism) that is connected with differences in the replication time of chromosomes and of their regions but also variation of the quantity of genetic material.     

Immunocytochemical localization of chromatin regions UV-microirradiated in S phase or anaphase. Evidence for a territorial organization of chromosomes during cell cycle of cultured Chinese hamster cells

Chinese hamster cells (M3-1 line) in S phase were laser-UV-microirradiated (lambda, 257 nm) at a small site of the nucleus. Cells were fixed either immediately thereafter or in subsequent stages of the cell cycle, including prophase and metaphase. The microirradiated chromatin was visualized by indirect immunofluorescence microscopy using antibodies specific for UV-irradiated DNA. During the whole post-incubation period (4-15 h) immunofluorescent labelling was restricted to a small part of the nucleus (means, 4.5% of the total nuclear area). In mitotic cells segments of a few chromosomes only were labelled. Following microirradiation of chromosome segments in anaphase, immunofluorescent labelling was observed over a small part of the resulting interphase nucleus. A territorial organization of interphase chromosomes, i.e. interphase chromosomes occupying distinct domains, has previously been demonstrated by our group for the nucleus of Chinese hamster cells in G1. Our present findings provide evidence that this organization pattern is maintained during the entire cell cycle.     

Mitosis-inducing factors are present in a latent form during interphase in the Xenopus embryo

During the conversion to the mitotic state, higher eukaryotic cells activate a cascade of reactions which result in the disintegration of the nuclear envelope, the condensation of the DNA into chromosomes, and the reorganization of the cytoskeleton. In Xenopus, the induction of the mitotic state appears to be under the control of a cytoplasmic factor(s) known as mitosis-promoting factor or MPF. We have developed a rapid and highly sensitive version of an in vitro assay for MPF. The assay uses reconstituted nuclei in interphase cytoplasm from activated Xenopus eggs. The MPF-induced conversion from interphase to mitosis is conveniently monitored by the visual observation of the loss of the nuclear envelope from the substrate nuclei. At near saturating concentrations of MPF, nuclear breakdown requires 20-30 min. Preincubation experiments have revealed that the action of MPF requires only a few minutes and that the disassembly process itself takes up the remainder of the incubation period. Using this cell-free system, we have investigated the observation that protein synthesis is required for the progression through each successive mitotic cycle in the developing Xenopus embryo. A simple explanation for this finding would be that MPF is degraded after each mitosis and then resynthesized before the next mitotic cycle. However, using in vitro reactivation experiments, we have found that MPF is present in a latent, inactive form during interphase. These results suggest that the block in the cell cycle induced by inhibitors of protein synthesis is due to the lack of production of an activator of MPF.     

The nuclear skeleton and the spatial arrangement of chromosomes in the interphase nucleus of vertebrate somatic cells

Summary The topologic distribution of interphase chromosomes estabilished by using various cytologic methods and data concerning the DNA-nuclear skeleton interactions in isolated nuclear fractions were reviewed and discussed. Comparison of these different data clearly showed that the position of chromosomes observed in situ is in agreement with the results obtained from isolated nuclear fractions, indicating that all DNA molecules are bound to the peripheral nuclear skeleton. Moreover, the in situ position of the rDNA near the nuclear envelope can be correlated with the existence of a nuclear skeleton connected to the peripheral nuclear skeleton. Taking into account the discrepant results regarding the actual existence of an internal nuclear skeleton, we attempted to analyze how the various nuclear skeletal structures described in the literature can be involved in both the distribution of chromosomes and in their chromatin organization. As many questions are still unanswered, we considered the modes of investigation that seem to be the most promising.     

Dynamic interaction between BAF and emerin revealed by FRAP, FLIP, and FRET analyses in living HeLa cells

Barrier-to-autointegration factor (BAF) is a conserved 10 kDa DNA-binding protein. BAF interacts with LEM-domain proteins including emerin, LAP2 beta, and MAN1 in the inner nuclear membrane. Using fluorescence recovery after photobleaching (FRAP) and fluorescence loss in photobleaching (FLIP), we compared the mobility of BAF to its partners emerin, LAP2 beta, and MAN1 in living HeLa cells. Like endogenous BAF, GFP-BAF was enriched at the nuclear envelope, and found inside the nucleus and in the cytoplasm during interphase. At every location, FRAP and FLIP analysis showed that GFP-BAF diffused rapidly; the halftimes for recovery in a 0.8 microm square area were 260 ms at the nuclear envelope, and even faster inside the nucleus and in the cytoplasm. GFP-fused emerin, LAP2 beta, and MAN1 were all relatively immobile, with recovery halftimes of about 1 min, for a 2 microm square area. Thus, BAF is dynamic and mobile during interphase, in stark contrast to its nuclear envelope partners. FLIP results further showed that rapidly diffusing cytoplasmic and nuclear pools of GFP-BAF were distinctly regulated, with nuclear GFP-BAF unable to replenish cytoplasmic BAF. Fluorescence resonance energy transfer (FRET) results showed that CFP-BAF binds directly to YFP-emerin at the inner nuclear membrane of living cells. We propose a "touch-and-go" model in which BAF binds emerin frequently but transiently during interphase. These findings contrast with the slow mobility of both GFP-BAF and GFP-emerin during telophase, when they colocalized at the 'core' region of telophase chromosomes at early stages of nuclear assembly.     

Long duration of mitosis and consequences for the cell cycle concept, as seen in the isthmal cells of the mouse pyloric antrum. II. Duration of mitotic phases and cycle stages, and their relation to one another

Abstract. The kinetics of isthmal cells in mouse antrum were examined in three ways: (a) the duration of cell cycle and DNA-synthesizing (S) stage was measured by the 'fraction of labelled mitoses' method; (b) the duration of interphase and mitotic phases was determined from how frequently they occurred; and (c) mice were killed at various intervals after an intravenous injection of ³H-thymidine to time the acquisition of label by the various phases of mitosis.
The duration of the isthmal cell cycle was found to be 13.8 hr and that of the DNA-synthesizing (S) stage, 5.8 h. Estimates for the duration of the G₁ and G₂ stages were 6.8 and 1.0 hr, respectively.
From the frequency of mitotic phases, defined as indicated in the preceding article (El-Alfy & Leblond, 1987) and corrected for the probability of their occurence, it was estimated that prophase lasted 4.8 hr; metaphase, 0.2 hr; anaphase, 0.06 hr and telophase, 3.3 hr, while the interphase lasted 5.4 hr. In accordance with this, the duration of the whole mitotic process was 8.4 hr.
Ten minutes after an intravenous injection of ³H-thymidine, 38% of labelled isthmal cells were in interphase and 62% in early or mid prophase, while cells in late prophase and other mitotic phases were unlabelled. After 60 min, label was in late prophase, after 120 min, in mid telophase and after 180 min, in late telophase.
We conclude that there is overlap between some mitotic phases and cycle stages. Thus, while nuclei are at interphase during the early third of S, they are in prophase during the late two-thirds as well as during G₂. Also, nuclei are in telophase during the early half of G₁ but at interphase during the late half. Differences in nuclear diameter show that subdivision of both S and G₁ into early and late periods is practical.