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.     

Spatial localization of chromosome-nuclear envelope interaction sites.

In the interphase nucleus chromosomes are tightly associated with the nuclear envelope (NE) through special granular chromatin particles termed anchorosomes. It remains unclear whether anchorosomes represent constant nuclear structures, persisting throughout the cell cycle, or they appear only in the interphase during the formation of contacts between the chromosomes and NE. In other words, whether specific NE interaction sites do exist in chromosomes or any region can form anchorosome. In this work, we used micrononucleated PK cells, in which almost every micronucleus (MN) is formed by a single chromosome. The spatial distribution and quantitative characteristics of the anchorosomal layer in MN was studied using stereological analysis and three-dimensional computer reconstruction. It was shown that in cells with about 30 MN, the total surface area of NE reaches about 355 microm2, whereas in normal mononuclear cells it is 110 microm2. Hence, the NE surface increases 3-fold during MN formation. In contrast to normal cells, only 80% of the NE surface in MN is covered with anchorosomes, i.e., the total surface area of the anchorosomal layer increases by a factor of 2.5. The 3D reconstruction has demonstrated highly random distribution of anchorosome-free zones, the distribution patterns varying in individual MN. These findings are thought to be evidence for the existence of a limited number of specific chromosomal sites potentially capable of forming contacts with NE.     

Study of peripheral chromatin granules--anchorosomes

The granular particles of chromatin peripheral layer, were isolated together, with the nuclear envelope by treatment of nuclei with nuclease. These particles differ from total chromatin by a decreased content of histone H1, a specific set of minor acid-soluble proteins and a low DNA methylation level. Taking account of the fact that these particles facilitate chromatin interaction with the nuclear envelope, the latter were termed as "anchorosomes". Using UV-induced cross-linking of DNA to the proteins, it was found that all anchorosome-specific acid-soluble proteins can directly interact with anchorosomal DNA. Treatment of anchorosomes with staphylococcal nuclease and electron microscopic data showed that anchorosomes have a nucleosomal organization. Five to ten per cent of anchorosomal DNA appear to be firmly bound to nuclear lamina. This DNA cannot be separated from the lamina by treatment with 2 M NaCl, 1% SDS or heparin (1 mg/ml). The bulk of DNA in the laminal fraction after treatment with the above reagents is protected from hydrolysis with DNAase I by anchorosomal proteins and thus has a high molecular weight (10,000-30,000 base pairs). After treatment of anchorosomes with 0.6 M or 2 M NaCl, DNAase I splits this DNA, predominantly to minor fragments.     

NuMA interaction with chromatin is vital for proper chromosome decondensation at the mitotic exit

NuMA is an abundant long coiled-coil protein that plays a prominent role in spindle organization during mitosis. In interphase, NuMA is localized to the nucleus and hypothesized to control gene expression and chromatin organization. However, because of the prominent mitotic phenotype upon NuMA loss, its precise function in the interphase nucleus remains elusive. Here, we report that NuMA is associated with chromatin in interphase and prophase but released upon nuclear envelope breakdown (NEBD) by the action of Cdk1. We uncover that NuMA directly interacts with DNA via evolutionarily conserved sequences in its C-terminus. Notably, the expression of the DNA-binding–deficient mutant of NuMA affects chromatin decondensation at the mitotic exit, and nuclear shape in interphase. We show that the nuclear shape defects observed upon mutant NuMA expression are due to its potential to polymerize into higher-order fibrillar structures. Overall, this work establishes the spindle-independent function of NuMA in choreographing proper chromatin decompaction and nuclear shape by directly associating with the DNA.     

Nuclear envelope localization of an adenovirus tumor antigen maintains the integrity of cellular DNA.

The adenovirus early-region 1B 19,000-molecular-weight tumor antigen is required for oncogenic transformation of cells by adenovirus. We have demonstrated that this tumor antigen is located in the nuclear envelope of infected and transformed cells and that a fraction of the protein within the nuclear envelope is associated with the nuclear lamina. During cell division in the transformed cells, the nuclear envelope containing the tumor antigen dissociates at metaphase and then reforms around the separated daughter chromosomes at telophase. Adenovirus mutants carrying lesions in the gene encoding this tumor antigen cause degradation of host cell chromosomal DNA, and in these mutants, the intracellular localization of the 19,000-dalton protein is altered. These results demonstrate that components of the nuclear envelope function in the organization of chromatin in infected and transformed cells and that a virus-encoded protein plays a critical role in this process.     

A phosphorylation cluster in the chromatin-binding region regulates chromosome association of LAP2alpha

LAP2alpha is a LEM family protein associated with nucleoplasmic A-type lamins and chromatin in interphase. Like lamins and other lamina proteins LAP2alpha is cytoplasmic in metaphase, but it associates with chromosomes prior to nuclear envelope formation in late anaphase to telophase. In vitro phosphorylation analysis and mass spectrometry identified a cluster of at least three mitotic cyclin-dependent kinase 1 phosphorylation sites in the C-terminal chromatin-binding region of LAP2alpha as well as four additional potential sites in the cluster, some of which were targeted alternatively in LAP2alpha mutated at the major sites. LAP2alpha mutants containing serine --> alanine mutations at all seven sites revealed a clear phenotype. Mutated LAP2alpha remained associated with chromosomes throughout mitosis, but the dissociation of lamins into the cytoplasm and nuclear envelope disassembly were not affected. These data demonstrate the in vivo significance of mitotic phosphorylation for the dynamic behavior of LAP2alpha in the cell cycle and show that, unlike the interaction with lamins, the chromatin association of LAP2alpha is regulated by multiple mitosis-specific phosphorylation at sites clustered within a defined region in the C terminus of the protein.     

Effects of ultracentrifugation on the interphase nucleus of somatic cells with special reference to the nuclear envelope-chromatin relationship

Summary Ultracentrifugation of living cells from the liver of the mouse, rat, dog, frog, Necturus, follicle cells, of grasshopper testis, and meristem of the onion root tip shows evidence that the interphase chromatin is attached to the nuclear envelope. Because of its relatively high density, the bulk of the interphase chromatin, and often the nucleoli, are displaced to the centrifugal side of the nucleus and, when this occurs, the chromatin bodies attached to the centripetal side of the nucleus are drawn out into long filaments which extend across the nucleus centrifugally. They generally break before becoming detached from the envelope. Onion root tip chromosomes in early prophase also appear to be attached to the nuclear envelope. The Barr body strongly adheres to the nuclear envelope as evidenced by the high centrifugal force necessary to displace it. Nucleoli of ultracentrifuged meristematic cells of the onion root show evidence of a stratification of materials within them.Supported by Grant GM 04706 from the U.S.P.H.S.     

Ultrastructure of mitosis inAmoeba proteus

Summary The fine structure ofAmoeba proteus nuclei has been studied during interphase and mitosis. The interphase nucleus is discoidal, the nuclear envelope is provided with a honeycomb layer on the inside. There are numerous nucleoli at the periphery and many chromatin filaments and nuclear helices in the central part of nucleus.In prophase the nucleus becomes spherical, the numerous chromosomes are condensed, and the number of nucleoli decreases. The mitotic apparatus forms inside the nucleus in form of an acentric spindle. In metaphase the nuclear envelope loses its pore complexes and transforms into a system of rough endoplasmic reticulum cisternae (ERC) which separates the mitotic apparatus from the surrounding cytoplasm; the nucleoli and the honeycomb layer disappear completely. In anaphase the half-spindles become conical, and the system of ERC around the mitotic spindle persists. Electron dense material (possibly microtubule organizing centers—MTOCs) appears at the spindle pole regions during this stage. The spindle includes kinetochore microtubules attached to the chromosomes, and non-kinetochore ones which pierce the anaphase plate. In telophase the spindle disappears, the chromosomes decondense, and the nuclear envelope becomes reconstructed from the ERC. At this stage, nucleoli can already be revealed with the light microscope by silver staining; they are visible in ultrathin sections as numerous electron dense bodies at the periphery of the nucleus.The mitotic chromosomes consist of 10 nm fibers and have threelayered kinetochores. Single nuclear helices still occur at early stages of mitosis in the spindle region.     

Elimination of chromosomes in Hordeum vulgare x H. bulbosum crosses at mitosis and interphase involves micronucleus formation and progressive heterochromatinization

Uniparental chromosome elimination occurs in several interspecific hybrids of plants. We studied the mechanism underlying selective elimination of the paternal chromosomes during the development of Hordeum vulgare x H. bulbosum hybrid embryos that is restricted to an early stage of development. In almost all embryos most of the H. bulbosum chromatin undergoes a fast rate of elimination within nine days after pollination. There are differences in the mitotic behaviour between the parental chromosomes, with H. bulbosum chromatids segregating asymmetrically at anaphase. We provide evidence for a chromosome elimination pathway that involves the formation of nuclear extrusions during interphase in addition to postmitotically formed micronuclei. The chromatin structure of nuclei and micronuclei differs and heterochromatinization and disintegration of the nuclear envelope of micronuclei are the final steps of chromosome elimination.     

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.     

The A-kinase-anchoring protein AKAP95 is a multivalent protein with a key role in chromatin condensation at mitosis

Protein kinase A (PKA) and the nuclear A-kinase-anchoring protein AKAP95 have previously been shown to localize in separate compartments in interphase but associate at mitosis. We demonstrate here a role for the mitotic AKAP95-PKA complex. In HeLa cells, AKAP95 is associated with the nuclear matrix in interphase and redistributes mostly into a chromatin fraction at mitosis. In a cytosolic extract derived from mitotic cells, AKAP95 recruits the RIIalpha regulatory subunit of PKA onto chromatin. Intranuclear immunoblocking of AKAP95 inhibits chromosome condensation at mitosis and in mitotic extract in a PKA-independent manner. Immunodepletion of AKAP95 from the extract or immunoblocking of AKAP95 at metaphase induces premature chromatin decondensation. Condensation is restored in vitro by a recombinant AKAP95 fragment comprising the 306-carboxy-terminal amino acids of the protein. Maintenance of condensed chromatin requires PKA binding to chromatin-associated AKAP95 and cAMP signaling through PKA. Chromatin-associated AKAP95 interacts with Eg7, the human homologue of Xenopus pEg7, a component of the 13S condensin complex. Moreover, immunoblocking nuclear AKAP95 inhibits the recruitment of Eg7 to chromatin in vitro. We propose that AKAP95 is a multivalent molecule that in addition to anchoring a cAMP/PKA-signaling complex onto chromosomes, plays a role in regulating chromosome structure at mitosis.     

Architectural organization in the interphase nucleus of the protozoan Trypanosoma brucei: location of telomeres and mini-chromosomes.

We studied the spatial organization of chromatin in the interphase G1, S and G2 nucleus of the protozoan Trypanosoma brucei, applying in situ hybridization with conventional fluorescence and confocal scanning optical microscopy. The majority of the trypanosome telomere GGGTTA repeats from different chromosomes were found clustered together, either extending in a network through the nuclear interior or localized at the nuclear periphery. The population of one hundred mini-chromosomes was often asymmetrically located: either clustered in a narrow band in close association with the nuclear envelope or distributed into several clusters that segregated into roughly one half of the nucleus. The nuclear organization may undergo modifications during the cell cycle and development. We conclude that non-random spatial positioning of DNA exists in the nucleus of this protozoan. Finding a high level of structural organization in the interphase nucleus of T.brucei is an important first step towards understanding chromosome structure and functioning and its role in the control of gene expression.     

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.     

Essential roles for Caenorhabditis elegans lamin gene in nuclear organization, cell cycle progression, and spatial organization of nuclear pore complexes

Caenorhabditis elegans has a single lamin gene, designated lmn-1 (previously termed CeLam-1). Antibodies raised against the lmn-1 product (Ce-lamin) detected a 64-kDa nuclear envelope protein. Ce-lamin was detected in the nuclear periphery of all cells except sperm and was found in the nuclear interior in embryonic cells and in a fraction of adult cells. Reductions in the amount of Ce-lamin protein produce embryonic lethality. Although the majority of affected embryos survive to produce several hundred nuclei, defects can be detected as early as the first nuclear divisions. Abnormalities include rapid changes in nuclear morphology during interphase, loss of chromosomes, unequal separation of chromosomes into daughter nuclei, abnormal condensation of chromatin, an increase in DNA content, and abnormal distribution of nuclear pore complexes (NPCs). Under conditions of incomplete RNA interference, a fraction of embryos escaped embryonic arrest and continue to develop through larval life. These animals exhibit additional phenotypes including sterility and defective segregation of chromosomes in germ cells. Our observations show that lmn-1 is an essential gene in C. elegans, and that the nuclear lamins are involved in chromatin organization, cell cycle progression, chromosome segregation, and correct spacing of NPCs.     

Ultrastructure of the nuclei during different phases of the cell cycle in the antheridial filaments ofChara vulgaris L.

Summary Synchronously dividing nuclei of the antheridial filaments ofChara vulgaris at the 32-celled stage have different structure depending on the period of interphase.During S phase which begins as early as at the start of telophase (coincidently with the nuclear envelope formation and chromosome decondensation) one can observe a gradual reduction in the content of condensed chromatin, having the appearance of an indistinct network. During the middle S period the area of condensed chromatin decreases to the lowest level of about 29% of nuclear profile and the nuclear envelope becomes folded. At the end of S phase the condensed chromatin forms a more distinct and thicker reticulum which covers an area of about 52%.During the early G₂ phase, the area occupied by the condensed chromatin was about 41% and it was found to assume the shape of large and iregular clusters localized mainly near the nucleoli. The reticulate form of chromatin, characteristic of the S period, disappears almost completely. During the next period of interphase the condensed chromatin disperses considerably and covers now 24% of the area. At the end of the G₂ phase the condensed chromatin reappears and transforms into chromosomes. Then the condensed chromatin removes from the nuclear envelope.This work was supported by the Polish Academy of Sciences within the project 09.7.3.1.4.     

The anchorosome, a special chromatin granule for the anchorage of the interphase chromosome to the nuclear envelope

Peripheral chromatin granules bound to the nuclear envelope of rat liver nuclei have been further investigated. Judging by the results of Staphylococcal nuclease digestion of nuclei and electron microscopical observations, the peripheral granules have nucleosomal organization. As shown by ultraviolet radiation DNA-protein cross-linkage, the histone-like proteins present in the peripheral chromatin instead of histone H1 (Fais et al., 1982) are in close contact with DNA. The peripheral chromatin contains a DNA firmly bound to the lamina. This DNA, resistant to extraction in high salt, heparin and SDS, is protected against a DNase attack since, as shown by DNA electrophoresis data, high molecular weight molecules (up to 20 kbas) are still present in the lamina residue. However, the high molecular weight DNA disappeared if the nuclear envelope fraction was again DNase-digested after high salt treatment. Altogether, the data of the previous (Fais et al., 1982; Prusov et al., 1980: Prusov et al., 1982) and the present investigations demonstrate that the peripheral chromatin granules are endowed with properties which distinguish them from the bulk chromatin and account for the chromosome bond to the nuclear envelope during interphase. This is why we suggest the term "anchorosome" for the peripheral protein granule attached to the nuclear envelope.     

Nucleocytoplasmic sorting of macromolecules following mitosis: fate of nuclear constituents after inhibition of pore complex function

PtK2 cells in which pore complex-mediated transport is blocked by microinjection early in mitosis of a monoclonal antibody (specific for an Mr 68,000 pore complex glycoprotein) or of wheat germ agglutinin (WGA) complete cytokinesis. However, their nuclei remain stably arrested in a telophase-like organization characterized by highly condensed chromatin and the absence of nucleoli, indicating a requirement for pore-mediated transport for the reassembly of interphase nuclei. We have now examined this requirement more closely by monitoring the behavior of individual nuclear macromolecules in microinjected cells using immunofluorescence microscopy and have investigated the effect of microinjecting the antibody or WGA on cellular ultrastructure. The absence of nuclear transport did not affect the sequestration into daughter nuclei of components such as DNA, DNA topoisomerase I and the nucleolar protein fibrillarin that are carried through mitosis on chromosomes. On the other hand, lamins, snRNAs and the p68 pore complex glycoprotein, all cytoplasmic during mitosis, remained largely cytoplasmic in the telophase-arrested cells. Electron microscopy showed the nuclei to be surrounded by a double-layered membrane with some inserted pore complexes. In addition, however, a variety of membranous structures with associated pore complexes was regularly noted in the cytoplasm, suggesting that chromatin may not be essential for the postmitotic formation of pore complexes. We propose that cellular compartmentalization at telophase is a two-step process. First, a nuclear envelope tightly encloses the condensed chromosomes, excluding non-selectively all macromolecules not associated with the chromosomes. Interphase nuclear organization is then progressively restored by selective pore complex-mediated uptake of nuclear proteins from the cytoplasm.