Loss of lamin B receptor is necessary to induce cellular senescence.

Cellular transition to senescence is associated with extensive chromatin reorganization and changes in gene expression. Recent studies appear to imply an association of lamin B1 (LB1) reduction with chromatin rearrangement in human fibroblasts promoted to senescence, while the mechanisms and structural features of these relationships have not yet been clarified. In this work, we examined the functions of LB1 and the lamin B receptor (LBR) in human cancer cells. We found that both LB1 and LBR tend to deplete during cancer cell transfer to senescence by γ-irradiation. A functional study employing silencing of LBR by small hairpin ribonucleic acid (shRNA) constructs revealed reduced LB1 levels suggesting that the regulation of both proteins is interrelated. The reduced expression of LBR resulted in the relocation of centromeric heterochromatin (CSH) from the inner nuclear membrane (INM) to the nucleoplasm and is associated with its unfolding. This indicates that LBR tethers heterochromatin to INM in cycling cancer cells and that LB1 is an integral part of this tethering. Down-regulation of LBR and LB1 at the onset of senescence are thus necessary for the release of heterochromatin binding to lamina, resulting in changes in chromatin architecture and gene expression. However, the senescence phenotype was not manifested in cell lines with reduced LBR and LB1 expression suggesting that other factors, such as deoxyribonucleic acid (DNA) damage, are needed to trigger senescence. We conclude that the primary response of cells to various stresses leading to senescence consists of the down-regulation of LBR and LB1 to attain reversal of the chromatin architecture.

Permeabilization of the nuclear envelope following nanosecond pulsed electric field exposure.

Permeabilization of cell membranes occurs upon exposure to a threshold absorbed dose (AD) of nanosecond pulsed electric fields (nsPEF). The ultimate, physiological bioeffect of this exposure depends on the type of cultured cell and environment, indicating that cell-specific pathways and structures are stimulated. Here we investigate 10 and 600 ns duration PEF effects on Chinese hamster ovary (CHO) cell nuclei, where our hypothesis is that pulse disruption of the nuclear envelope membrane leads to observed cell death and decreased viability 24 h post-exposure. To observe short-term responses to nsPEF exposure, CHO cells have been stably transfected with two fluorescently-labeled proteins known to be sequestered for cellular chromosomal function within the nucleus - histone-2b (H2B) and proliferating cell nuclear antigen (PCNA). H2B remains associated with chromatin after nsPEF exposure, whereas PCNA leaks out of nuclei permeabilized by a threshold AD of 10 and 600 ns PEF. A downturn in 24 h viability, measured by MTT assay, is observed at the number of pulses required to induce permeabilization of the nucleus.

Nuclear envelope defects impede a proper response to micronuclear DNA lesions.

When damage is inflicted in nuclear DNA, cells activate a hierarchical plethora of proteins that constitute the DNA damage response machinery. In contrast to the cell nucleus, the ability of micronuclear DNA lesions to activate this complex network is controversial. In order to determine whether the DNA contained in micronuclei is protected by the cellular damage response system, we studied the recruitment of excision repair factors to photolesions inflicted in the DNA of radiation-induced micronuclei. To perform this analysis, primary human dermal fibroblasts were exposed to UV-C light to induce photolesions in nuclear and micronuclear DNA. By means of immunofluorescence techniques, we observed that most micronuclei were devoid of NER factors. We conclude that UV photoproducts in micronuclei are mostly unable to generate an effective DNA damage response. We observed that the micronuclear envelope structure is a determinant factor that influences the repair of the DNA lesions inside micronuclei. Therefore, our results allow us to conclude that photolesions in radiation-induced micronuclei are poorly processed because the repair factors are unable to reach the micronuclear chromatin when a micronucleus is formed or after a genotoxic insult.

[An analysis on biomedical effects of bipolar electric pulses at different central frequency].

Adopting the cell model of multilayer spherical symmetry and the circuit analysis, the present paper gives the calculated results of the voltages on each of several parts of malignant Tonsillar B-cells and Jurkat T lymphocytes when the first-order Gaussian pulses at different central frequency apposed on them. The relationship between the central frequency and the transmembrane voltages of plasma membrane is also given. The optimum frequency causing electroporation in nuclear envelope is given as well. The paper discusses the reasons of electroporation in membrane and DNA degradation in nuclear. The work provides a reference for usage of transient bipolar electric pulses in cancer treatment.

[Electric pulse duration and windows effect of nuclear envelope].

Nuclear envelope voltages of T cells were analyzed with a lumped circuitry for cells in combination with frequency domain power density of Gaussian pulses and monocycle pulses. According to the differences in geometric and electric parameters between normal and malignant T cells, circuitry analysis was performed. Theoretical evaluations indicated that apoptosis of malignant T cells was of feasibility, which could be applied in cancer therapy. The evaluations were in accord with the published experimental findings.

Formation of the nuclear envelope permeability barrier studied by sequential photoswitching and flux analysis.

In higher eukaryotes, the nuclear envelope breaks down during mitosis. It reforms during telophase, and nuclear import is reestablished within <10 min after anaphase onset. It is widely assumed that import functionality simultaneously leads to the exclusion of bulk cytoplasmic proteins. However, nuclear pore complex assembly is not fully completed when import capacity is regained, which raises the question of whether the transport and permeability barrier functions of the nuclear envelope are indeed coupled. In this study, we therefore analyzed the reestablishment of the permeability barrier of the nuclear envelope after mitosis in living cells by monitoring the flux of the reversibly photoswitchable fluorescent protein Dronpa from the cytoplasm into the nucleus after photoactivation. We performed many consecutive flux measurements in the same cell to directly monitor changes in nuclear envelope permeability. Our measurements at different time points after mitosis in individual cells show that contrary to the general view and despite the rapid reestablishment of facilitated nuclear import, the nuclear envelope remains relatively permeable for passive diffusion for the first 2 h after mitosis. Our data demonstrate that reformation of the permeability barrier of nuclear pore complexes occurs only gradually and is uncoupled from regaining active import functionality.

Entry into mitosis in vertebrate somatic cells is guarded by a chromosome damage checkpoint that reverses the cell cycle when triggered during early but not late prophase.

When vertebrate somatic cells are selectively irradiated in the nucleus during late prophase (<30 min before nuclear envelope breakdown) they progress normally through mitosis even if they contain broken chromosomes. However, if early prophase nuclei are similarly irradiated, chromosome condensation is reversed and the cells return to interphase. Thus, the G2 checkpoint that prevents entry into mitosis in response to nuclear damage ceases to function in late prophase. If one nucleus in a cell containing two early prophase nuclei is selectively irradiated, both return to interphase, and prophase cells that have been induced to returned to interphase retain a normal cytoplasmic microtubule complex. Thus, damage to an early prophase nucleus is converted into a signal that not only reverses the nuclear events of prophase, but this signal also enters the cytoplasm where it inhibits e.g., centrosome maturation and the formation of asters. Immunofluorescent analyses reveal that the irradiation-induced reversion of prophase is correlated with the dephosphorylation of histone H1, histone H3, and the MPM2 epitopes. Together, these data reveal that a checkpoint control exists in early but not late prophase in vertebrate cells that, when triggered, reverses the cell cycle by apparently downregulating existing cyclin-dependent kinase (CDK1) activity.

Controlled damage in thick specimens by multiphoton excitation.

Controlled damage by light energy has been a valuable tool in studies of cell function. Here, we show that the Ti:Sapphire laser in a multiphoton microscope can be used to cause localized damage within unlabeled cells or tissues at greater depths than previously possible. We show that the damage is due to a multiphoton process and made wounds as small as 1 microm in diameter 20 microm from the surface. A characteristic fluorescent scar allows monitoring of the damage and identifies the wound site in later observations. We were able to lesion a single axon within a bundle of nerves, locally interrupt organelle transport within one axon, cut dendrites in a zebrafish embryo, ablate a mitotic pole in a sea urchin egg, and wound the plasma membrane and nuclear envelope in starfish oocytes. The starfish nucleus collapsed approximately 1 h after wounding, indicating that loss of compartmentation barrier makes the structure unstable; surprisingly, the oocyte still completed meiotic divisions when exposed to maturation hormone, indicating that the compartmentalization and translocation of cdk1 and its regulators is not required for this process. Multiphoton excitation provides a new means for producing controlled damage deep within tissues or living organisms.

Properties of fluorescently labeled Xenopus lamin A in vivo.

Wild type Xenopus lamin A, a lamin A mutant lacking the carboxy-terminal cysteine (C662-->S), and human vimentin were expressed in bacteria and fluorescently labeled with 5-iodoacetamidofluorescein (5-IAF). In vitro reconstitution experiments and microinjection of both lamins into living cells revealed that they were indistinguishable from the non-fluorescently labeled proteins. When the 5-IAF lamin A was microinjected into the cytoplasm of 3T3 cells it was rapidly transported into the nucleus, giving rise within 1 h to a strong lamina fluorescence, whereas the lamin A mutant formed dotlike intranuclear aggregates. 5-IAF lamin A associated with the nuclear envelope of microinjected 3T3 cells and 5-IAF vimentin which was incorporated into the preexisting vimentin filaments of this cell line, were analyzed by photobleaching employing two different methods, (i) scanning microphotolysis using a modified laser scanning microscope, and (ii) the conventional photobleaching technique in which the integral fluorescence of a single spot was measured by photon counting. A low but significant fluorescence recovery was measured within 10 min for both 5-IAF-labeled intermediate filament proteins, lamin A and vimentin, in bleached areas of the nuclear envelope and the cytoplasmic intermediate filaments, respectively.

Effect of gamma radiation on membrane fluidity of MOLT-4 nuclei.

These experiments measured the effect of gamma radiation on the nuclear envelope using doxyl-fatty acid spin-label probes. Nuclei were isolated from cultured MOLT-4 cells, a radiation-sensitive human T-cell lymphocyte. Membrane fluidity was measured from the electron paramagnetic resonance spectra of the probes. MOLT-4 cells were grown under standard conditions, and suspensions were exposed to 60Co gamma radiation at room temperature. The spectra of 5-doxylstearic acid in the nuclei were those of a strongly immobilized label. A difference in the membrane fluidity was detected in a series of experiments comparing labeled irradiated and nonirradiated nuclei. The change in fluidity was measured by comparing the changes in the order parameter, S, of the spin label in irradiated nuclei with those in control nuclei. The change in the S ratio is dependent on radiation dose, increasing with doses up to 15 Gy. The maximum change of the order parameter with time after irradiation occurs 16-20 h after radiation exposure. These observations are correlated with changes in cell viabilities.

A radiation-induced inhibitor of chromosome condensation and nuclear envelope breakdown in HeLa cells.

An in vitro microscopic assay for mitosis-inducing activity in mitotic HeLa cells was developed and used to demonstrate that cells irradiated and arrested in G2 phase of the cell cycle contain an inhibitor of mitosis. This assay system has a number of advantages over other assays including the use of autologous components (HeLa nuclei and mitotic cell extracts) in contrast to the microinjection method with Xenopus oocytes and without the requirements for microinjection expertise and Xenopus oocytes. The radiation-inducible inhibitor was detected at the lowest radiation dose tested (2 Gy) with maximal activity achieved within 30 min after radiation. Inhibitor activity decayed with time after radiation (2 Gy) with no activity detected at 6 h even though the cells remained in G2 phase, suggesting that either synthesis or activation of additional components is necessary for recovery from G2 arrest. The inhibitor activity was not detected in irradiated cells treated with caffeine to induce premature recovery from G2 arrest.

Competition between photobleaching and fluorescence increase of photosensitizing porphyrins and tetrasulphonated chloroaluminiumphthalocyanine.

The time-dependent fluorescence changes of photosensitizing porphyrins and tetrasulphonated chloroaluminiumphthalocyanine (A1C1SPc) were measured at different intracellular sites using video-enhanced microscopy and image processing. To obtain variations in intracellular fluorescence intensity, different radiant exposures of a Kr+ laser-pumped dye laser were delivered via a 600 microns plastic-clad silica fibre connected to the microscope. During irradiation, competition between photobleaching and fluorescence increase of the different dyes was observed. The porphyrins normally showed photobleaching, which was dependent on the sensitizer and its specific accumulation within the cell. Photobleaching was less pronounced for hydrophilic uroporphyrin than for more hydrophobic dyes. In contrast with an almost exponential decrease in porphyrin fluorescence with increasing light dose, the fluorescence intensity of A1C1SPc significantly increased at the beginning of irradiation, and could be correlated with intracellular deaggregation.

The effect of lethal doses of radiation in vivo on the lipid microviscosity of tumor nuclear membranes.

The changes in the microviscosity of the nuclear membranes of tumor and liver cells of tumor hosts with developing Erlich ascites carcinoma at different times after irradiation of lethal dose has been studied by spin probe method. Using two iminoxyl radicals localized in various lipid regions, it was shown that the character and degree of changes in microviscosity, estimated from rotational correlation time for spin probes, indicate the different response to irradiation of liver and tumor cells.

[Nuclear pore density in rat liver cells during regeneration and x-ray irradiation of the animals]. / Plotnost' iadernykh por v kletkakh pecheni krysy pri regeneratsii i rentgenovskom obluchenii zhivotnykh.

Cytoplasmic as well as nucleoplasmic surfaces of the pore complexes (PC) could be observed using freeze-etching method. The density of PCs per 1 micron2 of nuclear envelope (NE) surface in regenerating liver (9.9) is twice as that in resting liver (5.3). 1 hour after 1200 R X-ray irradiation the pore density in regenerating liver decreases 5.8-fold, consisting only of 1.7 PCs per 1 micron2 of the NE. The structure of the PC after irradiation undergoes degradation and normal PCs practically disappear; only their "ghosts" remain. Peripheral and possibly central granules of the PC appear to consist of some subunits with their diameter of 4--5 nm. The central granule forms a channel through which RNA containing material may be transported from the nucleus to the cytoplasm. The non-uniform state of the PC, observed on platinum-carbon replicas of cleaved nuclei, and the non-altered PC associate with the dense lamina of the NE, after detergent treatment of isolated nuclei indicate that the PC could be formed inside the nuclei and to be "inserted" into the NE membranes in the course of their processing.

[Action of x-ray irradiation on the nuclear envelope of rat liver cells]. / Deitsvie rentgenovskogo oblucheniia na iadernuiu obolochku kletok pecheni krysy.

X-irradiation of isolated nuclear envelopes (NE) has revealed their high radiosensitivity, while irradiation of isolated intact nuclei in vitro, in the doses up to 5000 r 18--20 hours after partial hepatectomy, produced no morphological changes in NE. The damaging effect of irradiation on both nuclei and mitochondria (Mt) was revealed only with a decrease in cytochrome-c-oxidase (CO) activity in parallel with an increase in the radiation dose. One hour after the whole body irradiation of rats in the beginning of S-period, the damaging effect was recorded in both NE and Mt at the doses of 50 and 150 t, and was enhanced with the increase of irradiation dose. Morphological changes were observed mostly in the outer nuclear membrane, which lost its distinct outline and disappeared from some nuclear regions. Lethal radiation doses produced a decrease in the number of pore complexes (PC) with their evident segregation from the membranes. After irradiation in a dose of 1200 r, only the residue or "ghosts" of the PCs remained. After irradiation in doses up to 400 r, the CO-activity recovered during the first hour in Mt and during first two hours in the nuclei.

[Effect of irradiation on microviscosity of the cellular nuclear membrane of tumor and liver of tumor-carriers]. / Vliianie oblucheniia na mikroviazkost' iadernoi membrany kletok opukholi i pecheni opukholenositelei.

Spin probe analysis was carried out of changes in microviscosity of the nuclear membranes of the cells of tumor and liver of tumor-carriers with developing Ehrlich ascite carcinoma (EAC) different time after irradiation with lethal doses (650 r). Two iminoxyl radicals mainly localized in a lipid bilayer and in the membrane lipid layers adjacent to protein were applied. The pattern and level of changes in microviscosity of different nuclear membrane regions point to different response to irradiation of the cells of the tumor-carrier organ and of the tumor, both in viscosity properties and in the changes in lipid-protein relationships. A significant contribution to the total changes of the nuclear membrane microviscosity was made by the lipid layers adjacent to proteins. It is responsible for different reactions of the nuclear membranes of liver cells in tumor-carriers and in healthy animals, and also for a significant (3-fold) dilution of the nuclear membrane of EAC cells after irradiation. It is shown that temperature relationship of the times of rotative correlation of both probes is more pronounced in EAC cells of irradiated tumor-carriers than in the liver.

Direct observation of nanoparticle-cancer cell nucleus interactions.

We report the direct visualization of interactions between drug-loaded nanoparticles and the cancer cell nucleus. Nanoconstructs composed of nucleolin-specific aptamers and gold nanostars were actively transported to the nucleus and induced major changes to the nuclear phenotype via nuclear envelope invaginations near the site of the construct. The number of local deformations could be increased by ultrafast, light-triggered release of the aptamers from the surface of the gold nanostars. Cancer cells with more nuclear envelope folding showed increased caspase 3 and 7 activity (apoptosis) as well as decreased cell viability. This newly revealed correlation between drug-induced changes in nuclear phenotype and increased therapeutic efficacy could provide new insight for nuclear-targeted cancer therapy.