Inhibition by α-amanitin of messenger RNA formation in cultured fibroblasts: Potentiation by amphotericin B

α-Amanitin, a potent inhibitor of RNA polymerase II, is found inert against transformed fibroblasts in tissue culture. However, when α-amanitin is synergistically used with amphotericin B, RNA and protein synthesis are strongly blocked. Our data suggest that messenger RNA formation is preferentially inhibited since (1) the total inhibition by α-amanitin was greatly magnified when rRNA synthesis was first blocked with 0.03 μg/ml actinomycin D; (2) mRNA in polysomes was greatly reduced and the size of polysomes diminished after cells were exposed to 2 μg/ml α-amanitin plus 20 μg/ml amphotericin B for 5 h.     

Differential Subcellular Localization of Protein Phosphatase-1 α, γ1, and δ Isoforms during Both Interphase and Mitosis in Mammalian Cells

Protein phosphatase-1 (PP-1) is involved in the regulation of numerous metabolic processes in mammalian cells. The major isoforms of PP-1, α, γ1, and δ, have nearly identical catalytic domains, but they vary in sequence at their extreme NH₂ and COOH termini. With specific antibodies raised against the unique COOH-terminal sequence of each isoform, we find that the three PP-1 isoforms are each expressed in all mammalian cells tested, but that they localize within these cells in a strikingly distinct and characteristic manner. Each isoform is present both within the cytoplasm and in the nucleus during interphase. Within the nucleus, PP-1 α associates with the nuclear matrix, PP-1 γ1 concentrates in nucleoli in association with RNA, and PP-1 δ localizes to nonnucleolar whole chromatin. During mitosis, PP-1 α is localized to the centrosome, PP-1 γ1 is associated with microtubules of the mitotic spindle, and PP-1 δ strongly associates with chromosomes. We conclude that PP-1 isoforms are targeted to strikingly distinct and independent sites in the cell, permitting unique and independent roles for each of the isoforms in regulating discrete cellular processes.     

THE ACTION OF α-AMANITIN ON RNA SYNTHESIS IN CHINESE HAMSTER OVARY CELLS : Ultrastructural and Biochemical Studies

α-Amanitin acts in vitro as a selective inhibitor of the nucleoplasmic form B RNA polymerases. Treatment of Chinese hamster ovary (CHO) cells with this drug leads principally to a severe fragmentation of the nucleoli. While the ultrastructural lesions induced by α-amanitin in CHO cells and in rat or mouse liver are quite similar, the results diverge concerning the effect on RNA synthesis. It has been shown that in rat or mouse liver α-amanitin blocks both extranucleolar and nucleolar RNA synthesis. Our autoradiographic and biochemical evidence indicates that in CHO cells high molecular weight extranucleolar RNA synthesis (HnRNA) is blocked by the α-amanitin treatment, whereas nucleolar RNA (preribosomal RNA) synthesis remains unaffected even several hours after the inhibition of extranucleolar RNA synthesis. Furthermore, the processing of this RNA as well as its transport to the cytoplasm seem only slightly affected by the treatment. Finally, under these conditions, the synthesis of the low molecular RNA species (4–5S) still occurs, though less actively. The results are interpreted as evidence for a selective impairment of HnRNA synthesis by α-amanitin in CHO cells.     

Purification and Characterization of DNA-dependent RNA Polymerases from Cauliflower Nuclei

DNA-dependent RNA polymerases were solubilized from nuclei of cauliflower inflorescences and purified by agarose A-1.5m, DEAE-cellulose, DEAE-Sephadex, and phosphocellulose chromatography and sucrose density gradient centrifugation. RNA polymerases I + III were separated from II by DEAE-cellulose chromatography. Subsequent chromatography on DEAE-Sephadex resolved RNA polymerase I from III. RNA polymerases I and II were further purified to high specific activity by phosphocellulose chromatography and sucrose density gradient centrifugation. RNA polymerase I was refractory to α-amanitin at 2 mg/ml. RNA polymerase II was 50% inhibited at 0.05 μg/ml, and RNA polymerase III was 50% inhibited at 1 to 2 mg/ml of α-amanitin. The enzymes were characterized with respect to divalent cation optima, ionic strength optima, and abilities to transcribe cauliflower, synthetic, and cauliflower mosaic virus DNA templates.     

MITOSIS IN THE AQUATIC FUNGUS RHIZOPHYDIUM SPHEROTHECA (CHYTRIDIALES)

The structure of centric, intranuclear mitosis and of organelles associated with nuclei are described in developing zoosporangia of the chytrid Rhizophydium spherotheca. Frequently dictyosomes partially encompass the sides of diplosomes (paired centrioles). A single, incomplete layer of endoplasmic reticulum with tubular connections to the nuclear envelope is found around dividing nuclei. The nuclear envelope remains intact during mitosis except for polar fenestrae which appear during spindle incursion. During prophase, when diplosomes first define the nuclear poles, secondary centrioles occur adjacent and at right angles to the sides of primary centrioles. By late metaphase the centrioles in a diplosome are positioned at a 40° angle to each other and are joined by an electron-dense band; by telophase the centrioles lie almost parallel to each other. Astral microtubules radiate into the cytoplasm from centrioles during interphase, but by metaphase few cytoplasmic microtubules are found. Cytoplasmic microtubules increase during late anaphase and telophase as spindle microtubules gradually disappear. The mitotic spindle, which contains chromosomal and interzonal microtubules, converges at the base of the primary centriole. Throughout mitosis the semipersistent nucleolus is adjacent to the nuclear envelope and remains in the interzonal region of the nucleus as chromosomes separate and the nucleus elongates. During telophase the nuclear envelope constricts around the chromosomal mass, and the daughter nuclei separate from each end of the interzonal region of the nucleus. The envelope of the interzonal region is relatively intact and encircles the nucleolus, but later the membranes of the interzonal region scatter and the nucleolus disperses. The structure of the mitotic apparatus is similar to that of the chytrid Phlyctochytrium irregulare.     

Lectin-mediated uptake of lysosomal hydrolases by genetically deficient human fibroblasts.

A protein factor named S-II that stimulates RNA polymerase II was previously purified from Ehrlich ascites tumor cells [1]. In this work using an antibody prepared against purified S-II, the localization of S-II in the cell was investigated by an indirect immunofluorescence technique. In 3T3 cells, specific immunofluorescence was detected only in the nucleoplasm where RNA polymerase II is located, and not in the nucleoli where RNA polymerase I is present. In Ehrlich ascites tumor cells fluorescence was detected mainly in the nucleoplasm, although some fluorescence was also detectable in the cytoplasm, possibly due to leak of S-II from the nuclei during preparation of the immunofluorescent samples. In metaphase cells fluorescent was not found on chromosomes but throughout the cytoplasm. These findings suggest that S-II is a nuclear protein and that it spreads into the cytoplasm without being attached to chromosomes in metaphase, but is reassembled into the nucleoplasm in the interphase. Specific immunofluorescence was also detected in the nuclei of HeLa cells and salivary glands cells of flesh-fly larvae, suggesting that the nucleoplasm of these heterologous cells contains proteins immunologically cross-reactive with the antibody against S-II.     

Centriole inheritance

Early cell biologists perceived centrosomes to be permanent cellular structures. Centrosomes were observed to reproduce once each cycle and to orchestrate assembly a transient mitotic apparatus that segregated chromosomes and a centrosome to each daughter at the completion of cell division. Centrosomes are composed of a pair of centrioles buried in a complex pericentriolar matrix. The bulk of microtubules in cells lie with one end buried in the pericentriolar matrix and the other extending outward into the cytoplasm. Centrioles recruit and organize pericentriolar material. As a result, centrioles dominate microtubule organization and spindle assembly in cells born with centrosomes. Centrioles duplicate in concert with chromosomes during the cell cycle. At the onset of mitosis, sibling centrosomes separate and establish a bipolar spindle that partitions a set of chromosomes and a centrosome to each daughter cell at the completion of mitosis and cell division. Centriole inheritance has historically been ascribed to a template mechanism in which the parental centriole contributed to, if not directed, assembly of a single new centriole once each cell cycle. It is now clear that neither centrioles nor centrosomes are essential to cell proliferation. This review examines the recent literature on inheritance of centrioles in animal cells.Key words: centrosome, centriol, spindle, mitosis, microtubule, cell cycle, checkpoints     

SPINDLES, SPINDLE PLAQUES, AND MEIOSIS IN THE YEAST SACCHAROMYCES CEREVISIAE (HANSEN)

The intranuclear spindle of yeast has an electron-opaque body at each pole. These spindle plaques lie on the nuclear envelope. During mitosis the spindle elongates while the nuclear membranes remain intact. After equatorial constriction there are two daughted nuclei, each with one spindle plaque. The spindle plaque then duplicates so that two side-by-side plaques are produced. These move rapidly apart and rotate so that they bracket a stable 0.8 µm spindle. Later, during mitosis, this spindle elongates, etc. Yeast cells placed on sporulation medium soon enter meiosis. After 4 hr the spindle plaques of the more mature cells duplicate, producing a stable side-by-side arrangement. Subsequently the plaques move apart to bracket a 0.8 µm spindle which immediately starts to elongate. When this meiosis I spindle reaches its maximum length of 3–5 µm, each of the plaques at the poles of the spindle duplicates and the resulting side-by-side plaques increase in size. The nucleus does not divide. The large side-by-side plaques separate and bracket a short spindle of about 1 µm which elongates gradually to 2 or 3 µm. Thus there are two spindles within one nucleus at meiosis II. To the side of each of the four plaques a bulge forms on the nucleus. The four bulges enlarge while the original nucleus shrinks. These four developing ascospore nuclei are partially surrounded by cytoplasm and by a prospore wall which originates from the cytoplasmic side of the spindle plaque. Eventually the spore nuclei pinch off and the spore wall closes. In some of the larger yeast cells this development is completed after 8 hr on sporulation medium.     

Human mutant cell lines with altered RNA polymerase II

A human fibrosarcoma cell line, HT-1080-6TG-9AM, resistant to α-amanitin at concentrations up to 10 μg/ml, was isolated after ethylmethanesulfonate mutagenesis and stepwise selection. The mutation is stable and dominant. RNA polymerase II purified from the mutant cells showed an altered affinity for labeled α-amanitin and the sensitivity of the enzyme to the fungal toxin was decreased 50-to 100-fold. This functional test demonstrated that the biochemical basis for the resistance of the cells to α-amanitin is due to an alteration of RNA polymerase II.     

Sensitivity of Carrot Cell Cultures and RNA Polymerase II to Amatoxins : Evidence for the Inactivation of 6'-Hydroxyamatoxins

Protoplast and cell suspension cultures of Daucus carota L. were evaluated for their sensitivity toward the three amatoxin derivatives, α-amanitin, 6′-deoxy-α-amanitin, and 6′-O-methyl-α-amanitin using inhibition of DNA synthesis to measure cell viability. Protoplasts appeared approximately 10-fold more refractory than suspension cells and α-amanitin was much less effective than the other two amatoxins, even though K_i values for isolated RNA polymerase II were similar (4-5 nanomolar). Additional studies evaluating the recoveries of all three amatoxins from cell suspension supernates indicate one basis for these differences to be the selective degradation of α-amanitin. A mechanism involving the activation of the hydroxyindole moiety of the α-amanitin is thus invoked to explain these differences and we postulate the involvement of plant oxidases in this role.     

Selective activation of RNA polymerase I in fat body nuclei of Sarcophaga peregrina larvae by β-ecdysone

RNA synthesis in fat body nuclei of Sarcophaga peregrina larvae was temporarily activated after injection of β-ecdysone: increased synthesis was detectable 2 hr after injecting the hormone and lasted for at least 2 hr. This increased RNA synthesis was insensitive to α-amanitin and was observed in KCl-free reaction mixture, indicating that β-ecdysone activated RNA polymerase I but not RNA polymerase II. No activation was observed when protein synthesis was inhibited by cycloheximide, suggesting that protein synthesis was essential for the activation of the nuclei.     

Cell Death Associated with Abnormal Mitosis Observed by Confocal Imaging in Live Cancer Cells

Phenanthrene derivatives acting as potent PARP1 inhibitors prevented the bi-focal clustering of supernumerary centrosomes in multi-centrosomal human cancer cells in mitosis. The phenanthridine PJ-34 was the most potent molecule. Declustering of extra-centrosomes causes mitotic failure and cell death in multi-centrosomal cells. Most solid human cancers have high occurrence of extra-centrosomes. The activity of PJ-34 was documented in real-time by confocal imaging of live human breast cancer MDA-MB-231 cells transfected with vectors encoding for fluorescent γ-tubulin, which is highly abundant in the centrosomes and for fluorescent histone H2b present in the chromosomes. Aberrant chromosomes arrangements and de-clustered γ-tubulin foci representing declustered centrosomes were detected in the transfected MDA-MB-231 cells after treatment with PJ-34. Un-clustered extra-centrosomes in the two spindle poles preceded their cell death. These results linked for the first time the recently detected exclusive cytotoxic activity of PJ-34 in human cancer cells with extra-centrosomes de-clustering in mitosis, and mitotic failure leading to cell death. According to previous findings observed by confocal imaging of fixed cells, PJ-34 exclusively eradicated cancer cells with multi-centrosomes without impairing normal cells undergoing mitosis with two centrosomes and bi-focal spindles. This cytotoxic activity of PJ-34 was not shared by other potent PARP1 inhibitors, and was observed in PARP1 deficient MEF harboring extracentrosomes, suggesting its independency of PARP1 inhibition. Live confocal imaging offered a useful tool for identifying new molecules eradicating cells during mitosis.     

Deciphering protein function during mitosis in PtK cells using RNAi

Background  

Studying mitosis requires a system in which the dramatic movements of chromosomes and spindle microtubules can be visualized. PtK cells, due to their flat morphology and their small number of large chromosomes, allow microscopic visualizations to be readily performed.     

Effects of griseofulvin on mitosis in PtK1 cells

The concentration dependent effects of griseofulvin (GF) on mitosis in PtK₁ cells were studied using a combination of time lapse cinematography and polarization and electron microscopy. Low concentrations of GF (4×10^–5 M) allowed a substantial number of cells to enter and complete an apparently normal mitosis. At higher concentrations of GF (1×10^–4 M and 2.5×10^–4 M) all cells entering mitosis were arrested. Typical c-mitotic chromosome arrays were observed at 1×10^–4 M GF with microtubules present but no spindle formed. At 2.5×10^–4 M GF chromosomes did not orient toward a common center to form a c-mitotic figure, but instead remained in a loosely clustered grouping at the center of the cell. Electron microscopy showed microtubules to be absent but revealed an irregularly shaped electron dense cloud around the centrioles. Quantitative polarization microscopy of metaphase cells perfused with GF showed rapid loss of spindle birefringence after exposure to the drug. Coinciding with loss of birefringence the spindle shrank rapidly with a pronounced shortening of pole to pole distance.     

In situ analysis of normal and abnormal patterns of the mitotic apparatus in cultured rat-kangaroo cells

Dividing cells in monolayers of the rat-kangaroo (Potorous tridactylis) cell line Pt-K₁ have large spindles and are flat, thus making possible studies of interactions between the achromatic and chromatic parts of the mitotic apparatus during the cell cycle. At prophase, asters and centrioles seem to exert pressure on the nuclear membrane leading to its rupture and penetrance of the centrioles. Apparently, the long axis of the spindle is shorter than the nuclear diameter. What appears as persistent, large portions of the nuclear membrane were observed in some metaphase and anaphase cells. Such a condition might also indicate an arrested mitosis. The midbody, which was often bipartite, was found to be of a ribonucleoprotein nature. — Three-group metaphases were of common occurrence and might represent early stages of chromosome orientation preceding the final alignment of the chromosomes on the equatorial plate. They could also be an expression of an anomalous condition as a result of mitotic arrest during prometaphase owing to spindle inactivation or breakage, errors in centromere-spindle attachments, interference with chromosome movement, or a duplicated centriolar constitution. Most of these aberrations could be attributed to the flatness of dividing cells, which might also bring about the failure of centriole separation and spindle organization in prometaphase stages, as well as multipolar mitosis.De novo organization of half spindles might take place in cells with ruptured spindles. Anaphase cells showing signs of a previous three-group orientation were rare. — Multipolar mitoses were prevalent mainly in cells with high chromosome numbers. They were often star-shaped with the chromosomes oriented between opposite and adjacent poles, and rarely as end-to-end associations of spindles. Apparently, one or more centrioles might share a common polar region. Multipolar configurations have either a mono- or multinuclear origin. Nuclei usually enter division synchronously in binucleate cells and the spindles become organized between centrioles associated with individual or different nuclei.     

Huntingtin-interacting protein 1-related is required for accurate congression and segregation of chromosomes

Huntingtin-interacting protein 1-related (HIP1r) is known to function in clathrin-mediated endocytosis and regulation of the actin cytoskeleton, which occurs continuously in non-dividing cells. This study reports a new function for HIP1r in mitosis. Green fluorescent protein-fused HIP1r localizes to the mitotic spindles. Depletion of HIP1r by RNA interference induces misalignment of chromosomes and prolonged mitosis, which is associated with decreased proliferation of HIP1r-deficeint cells. Chromosome misalignment leads to missegregation and ultimately production of multinucleated cells. Depletion of HIP1r causes persistent activation of the spindle checkpoint in misaligned chromosomes. These findings suggest that HIP1r plays an important role in regulating the attachment of spindle microtubules to chromosomes during mitosis, an event that is required for accurate congression and segregation of chromosomes. This finding may provide new insights that improve the understanding of various human diseases involving HIP1r as well as its fusion genes.     

Effects of -amanitin on in vitro labeling of RNA from defined nuclear components in salivary gland cells from Chironomus tentans

The effect of α-amanitin on nucleoside labeling of RNA in nucleoli, chromosomes, nuclear sap, and cytoplasm from Chironomus tentans salivary gland cells was investigated by radioautography and gel electrophoresis. Preribosomal RNA formation and processing in the nucleolus was not measurably influenced by the drug, and both 28 S and 18 S ribosomal RNA were transferred to the cytoplasm. In the chromosomes the heterogeneous RNA labeling was completely inhibited for the large size range (above 45–50 S) and partially for the low range. The labeling of 4–5 S chromosomal RNA was only moderately reduced. Most of the chromosomes showed radioautographically a disappearance of the normal band pattern, but some retained a pattern of weakly labeled bands. The electrophoretic results for the nuclear sap paralleled those for the chromosomes. The effect of α-amanitin on RNA labeling in these cells is similar but not identical to that of the substituted benzimidazole 5,6-dichloro-1(β-D-ribofuranosyl) benzimidazole (DRB).     

Influence of centriole behavior on the first spindle formation in zygotes of the brown alga Fucus distichus (Fucales, Phaeophyceae)

The influence of centrioles, derived from the sperm flagellar basal bodies, and the centrosomal material (MTOCs) on spindle formation in the brown alga Fucus distichus (oogamous) was studied by immunofluorescence microscopy using anti-centrin and anti-beta-tubulin antibodies. In contrast to a bipolar spindle, which is formed after normal fertilization, a multipolar spindle was formed in polyspermic zygote. The number of mitotic poles in polyspermic zygotes was double the number of sperm involved in fertilization. As an anti-centrin staining spot (centrioles) was located at these poles, the multipolar spindles in polyspermic zygotes were produced by the supplementary centrioles. When anucleate egg fragments were fertilized, chromosome condensation and mitosis did not occur in the sperm nucleus. Two anti-centrin staining spots could be detected, microtubules (MTs) radiated from nearby, but the mitotic spindle was never produced. When a single sperm fertilized multinucleate eggs (polygyny), abnormal spindles were also observed. In addition to two mitotic poles containing anti-centrin staining spots, extra mitotic poles without anti-centrin staining spots were also formed, and as a result multipolar spindles were formed. When karyogamy was blocked with colchicine, it became clear that the egg nucleus proceeded independently into mitosis accompanying chromosome condensation. A monoastral spindle could be frequently observed, and in rare cases a barrel-shaped spindle was formed. However, when a sperm nucleus was located near an egg nucleus, the two anti-centrin staining spots shifted to the egg nucleus from the sperm nucleus. In this case, a normal spindle was formed, the egg chromosomes arranged at the equator, and the associated MTs elongated from one pole of the egg spindle toward the sperm chromosomes which were scattered. From these results, it became clear that paternal centrioles derived from the sperm have a crucial role in spindle formation in the brown algae, such as they do during animal fertilization. However, paternal centrioles were not adequate for the functional centrosome during spindle formation. We speculated that centrosomal materials from the egg cytoplasm aggregate around the sperm centrioles and are needed for centrosomal activation.     

CENTRIOLE REPLICATION : II. Sperm Formation in the Fern, Marsilea, and the Cycad, Zamia

Sperm formation was studied in the fern, Marsilea, and the cycad, Zamia, with particular emphasis on the centrioles. In Marsilea, the mature sperm possesses over 100 flagella, the basal bodies of which have the typical cylindrical structure of centrioles. Earlier observations by light microscopy suggested that these centrioles arise by fragmentation of a body known as the blepharoplast. In the youngest spermatids the blepharoplast is a hollow sphere approximately 0.8 µ in diameter. Its wall consists of closely packed immature centrioles, or procentrioles. The procentrioles are short cylinders which progressively lengthen during differentiation of the spermatid. At the same time they migrate to the surface of the cell, where each of them puts out a flagellum. A blepharoplast is found at each pole of the spindle during the last antheridial mitosis, and two blepharoplasts are found in the cytoplasm before this mitosis. Blepharoplasts are also found in the preceding cell generation, but their ultimate origin is obscure. Before the last mitosis the blepharoplasts are solid, consisting of a cluster of radially arranged tubules which bear some structural similarity to centrioles. In Zamia, similar stages are found during sperm formation, although here the number of flagella on each sperm is close to 20,000 and the blepharoplast measures about 10 µ in diameter. These observations are discussed in relation to theories of centriole replication.