Characterization of fission yeast meiotic mutants based on live observation of meiotic prophase nuclear movement

We characterized four meiotic mutants of the fission yeast Schizosaccharomyces pombe by live observation of nuclear movement. Nuclei were stained with either the DNA-specific fluorescent dye Hoechst 33342 or jellyfish green fluorescent protein (GFP) fused with the N-terminal portion of DNA polymerase α. We first followed nuclear dynamics in wild-type cells to determine the temporal sequence of meiotic events: nuclear fusion in the conjugated zygote is immediately followed by oscillatory nuclear movements that continue for 146 min; then, after coming to rest, the nucleus remains in the center of the cell for 26 min before the first meiotic division. Next we examined nuclear dynamics in four meiotic mutants: mei1 (also called mat2), mei4, dhc1, and taz1. Mei1 and mei4 both arrest during meiotic prophase; our observations, however, show that the timing of mei1 arrest is quite different from that of mei4: the mei1 mutant arrests after nuclear fusion but before starting the oscillatory nuclear movements, while the mei4 mutant arrests after the nucleus has completed the oscillatory movements but before the first meiotic division. We also show examples of the dynamic phenotypes of dhc1 and taz1, both of which complete meiosis but exhibit impaired nuclear movement and reduced frequencies of homologous recombination: the dhc1 mutant exhibits no nuclear movement after nuclear fusion, while the taz1 mutant exhibits severely impaired nuclear movement after nuclear fusion. Received: 28 October 1999; in revised form: 10 December 1999 / Accepted: 13 December 1999     

Content of nonhistone protein in nuclei after hyperthermic treatment

When nuclei were isolated from Chinese hamster ovary cells after being heated, there was a large increase in the amount of ³H-tryptophan labeled nonhistone protein in the nucleus relative to the whole cell. After 15 min or 30 min of heating at 45.5°C, the nuclear nonhistone protein content increased by 1.6 or 1.8, respectively. In contrast, when the nuclear nonhistone protein content was determined in the intact cell by using autoradiography to quantify ³H-tryptophan labeled protein in the nucleus and cytoplasm in sections of fixed cells, the nuclear nonhistone protein content increased by only 1.14 or 1.28 for 15 or 30 min at 45.5°C, respectively. Therefore, heat does not induce a massive movement of cytoplasmic protein into the nucleus. © 1993 Wiley-Liss, Inc.     

Pulsation of nuclei in insect oocytes is reversibly inhibited by cytochalasin B

Oocyte nuclei of the dipteran insect Heteropeza pygmaea display swift pulsating movements during in vitro follicle formation in the ovaries. Low doses of cytochalasin B (CB) completely inhibit the nuclear movements within a few minutes and cause the nuclei to assume spherical shapes. If the drug is removed, nuclear pulsation is resumed within 5–10 min. Phalloidin and colchicine do not affect the nuclear movements. Actin is shown by indirect immunofluorescence microscopy to be present in considerable amounts all over the cytoplasm of the oocytes. It is concluded that microfilaments are responsible for pulsation of the oocyte nuclei, whereas microtubules are not involved.     

A Protein Kinase-Dependent Block to Reinitiation of DNA Replication in G2 Phase in Mammalian Cells

Eukaryotic cells normally replicate their DNA only once between mitoses. Unlike G1 nuclei, intact G2 nuclei do not replicate during incubation inXenopusegg extract. However, artificial permeabilization of the nuclear membrane of G2 nuclei allows induction of new initiations byXenopusegg extract. This is consistent with the action of a replication licensing factor which is believed to enter the nucleus when the nuclear membrane breaks down at mitosis. Here, we show that G2 nuclei will initiate a new round of replication in the absence of nuclear membrane permeabilization, if they are preexposed to protein kinase inhibitorsin vivo.Competence to rereplicate is generated within 30 min of drug treatment, well before the scheduled onset of mitosis. This demonstrates that a protein kinase-dependent mechanism is continually active in G2 phase to actively prevent regeneration of replication capacity in mammalian cells. Kinase inhibition in G2 cells causes nuclear accumulation of replication protein A. Rereplication of kinase-inhibited G2 nuclei also depends on factors supplied byXenopusegg extract, which are distinct from those required for replication licensing.     

Tissue stretch induces nuclear remodeling in connective tissue fibroblasts

Studies in cultured cells have shown that nuclear shape is an important factor influencing nuclear function, and that mechanical forces applied to the cell can directly affect nuclear shape. In a previous study, we demonstrated that stretching of whole mouse subcutaneous tissue causes dynamic cytoskeletal remodeling with perinuclear redistribution of α-actin in fibroblasts within the tissue. We have further shown that the nuclei of these fibroblasts have deep invaginations containing α-actin. In the current study, we hypothesized that tissue stretch would cause nuclear remodeling with a reduced amount of nuclear invagination, measurable as a change in nuclear concavity. Subcutaneous areolar connective tissue samples were excised from 28 mice and randomized to either tissue stretch or no stretch for 30 min, then examined with histochemistry and confocal microscopy. In stretched tissue (vs. non-stretched), fibroblast nuclei had a larger cross-sectional area (P < 0.001), smaller thickness (P < 0.03) in the plane of the tissue, and smaller relative concavity (P < 0.005) indicating an increase in nuclear convexity. The stretch-induced loss of invaginations may have important influences on gene expression, RNA trafficking and/or cell differentiation.     

A Cytofluorometric Assay of Nuclear Apoptosis Induced in a Cell-Free System: Application to Ceramide-Induced Apoptosis

Purified nuclei exposed to apoptogenic factorsin vitroundergo morphological and biochemical changes in chromatin organization. Most cell-free models of nuclear apoptosis are based on the quantitation of endonuclease-mediated DNA fragmentation on agarose gels or on the changes of nuclear morphology revealed by the DNA-intercalating fluorochrome 4′-6-diamidino-2-phenylindole dihydrochloride. In this work we develop a cytofluorometric system for the accurate quantitation of nuclear DNA loss. This system has been used to determine the conditions of nuclear apoptosis induced by apoptosis-inducing factor (AIF) contained in the supernatant of mitochondria induced to undergo permeability transition. AIF can provoke significant nuclear DNA loss in ≤ 5 min, acts over a wide pH range (pH 6 to 9), and resists cysteine protease inhibitors such as iodoacetamide andN-ethylmaleimide. Moreover, we applied this system to the question of how the proapoptotic second messenger ceramide would induce apoptosisin vitro:via a direct effect on nuclei, a direct effect on mitochondria, or via indirect mechanisms? Our data indicate that ceramide has to activate yet unknown cytosolic effectors that, in the presence of mitochondria, can induce nuclear apoptosisin vitro.     

The timing of synthesis of proteins required for mitosis in the cell cycle of the sea urchin embryo

The protein synthesis inhibitor emetine was used to establish the times of synthesis of mitotic proteins, whose presence in the cell are essential in the mitotic processes of chromosome condensation, nuclear membrane breakdown, and possibly, chromosome alignment at metaphase. In embryos of the purple sea urchin, Strongylocentrotus purpuratus, protein synthesis required for chromosome condensation and nuclear membrane breakdown occurs between 20 and 35 min after fertilization. In Lytechinus variegatus embryos the time of synthesis of the mitotic proteins is more variable, occurring between 4 and 15 min after fertilization. Furthermore, in both species the mitosis of each cell cycle requires new synthesis of these proteins with the synthesis occurring at the beginning of each cycle. This observation indicates that the mitotic proteins, which are active at prophase and metaphase, lose their activity at late ana- and telophase.     

3H-URIDINE INCORPORATION IN THE PREMITOTIC STAGE OF RHIZOID CELL DIFFERENTIATION IN PTERIS VITTATA L.

The premitotic rhizoid stage (corona stage) of P. vittata gametophytes was pulsed in radioactive uridine for 5, 15, or 30 min and the data analyzed quantitatively by autoradiography. After 5 min, only the nucleoplasmic compartment is labelled significantly, suggesting that this short pulse is insufficient time for labelled precursor to be fixed in the nucleolus or to be transported from the nucleus to the cytoplasm. Since after 15 and 30 min, all compartments are labelled, with the greatest proportional increase over the nucleolus, it is concluded that cytoplasmic labelling is nuclear in origin and that nucleolar RNA activity is relatively high in this stage.     

1α,25-Dihydroxyvitamin D3 rapidly increases nuclear calcium levels in rat osteosarcoma cells

1α,25-Dihydroxyvitamin D₃ increases intracellular calcium in rat osteoblast-like cells that possess the classic receptor (ROS 17/2.8) as well as those that lack the classic receptor (ROS 24/1), indicating that a separate signalling system mediates this rapid nongenomic action. To determine the intracellular sites of this calcium increase, cytosolic and nuclear fluorescence (340 nm/380 nm ratio) were measured in Fura 2AM loaded ROS 17/2.8 cells using digital microscopy. Within 5 min, cytosolic fluorescence increased by 29% (P < 0.05) and nuclear fluorescence by 30% (P < 0.01) after exposure to 1α,25-dihydroxyvitamin D₃ (20 nM). This effect was blocked by the inactive epimer 1β,25-dihydroxyvitamin D₃. In an individual cell, cytosolic and nuclear fluorescence increased gradually after 1, 3, and 5 min exposure to vitamin D. Nuclei were then isolated from ROS 17/2.8 cells to directly measure the hormone's effect on nuclear calcium. The calcium content of Fura 2AM loaded nuclei was not affected by increasing the calcium concentration in the incubation buffer from 50 nM to 200 nM. After 5 min, 1α,25-dihydroxyvitamin D₃, 20 nM, increased the calcium of isolated nuclei in medium containing 50 nM calcium and 200 nM calcium. 1β,25-dihydroxyvitamin D₃, 20 nM, had no effect on nuclear calcium but blocked the 1α,25-dihydroxyvitamin D₃ induced rise in the isolated nuclei. The results indicate that the nuclear membrane of the ROS 17/2.8 cells contain calcium permeability barriers and transport systems that are sensitive to and specific for 1α,25-dihydroxyvitamin D₃. 1α,25-Dihydroxyvitamin D₃ rapidly increases nuclear calcium levels in both intact cells and isolated nuclei suggesting that rapid nongenomic activation of nuclear calcium may play a functional role in osteoblastic activity.     

Interactions between endoplasmic reticulum and nuclear membranes of different types of cells during repair of damaged Amoeba nuclei

Repair of amoeba nuclear envelopes that have been damaged microsurgically involves the association of pieces of endoplasmic reticulum with the damaged nuclear membranes. The capacity of endoplasmic reticulum of one type of cell to interact with the nuclear membranes of a different type was tested by placing the damaged nucleus of one kind of amoeba into the cytoplasm of another. Damaged nuclei from Amoeba proteus underwent repair in the cytoplasm of A. discoides or A. indica, as was the case in the reciprocal combinations of these nuclei and cytoplasms. In samples prepared 30 min after operation, heterologous endoplasmic reticulum was associated with holes in the nuclear membranes and appeared to fuse with the nuclear membranes at the margins of the holes. By 5 h after operation, almost all of the cells survived, and the nuclear membranes were largely intact, indicating that repair had occurred. In contrast, when an Amoeba dubia nucleus was damaged and placed in A. proteus cytoplasm there was no evidence of repair and many cells died within a few hours. The results indicate that endoplasmic reticulum and nuclear membranes from different types of cells can interact during repair of damaged nuclear membranes. There appears to be a specificity to this interaction, however, since in a combination of relatively dissimilar cells no association of endoplasmic reticulum with damaged nuclear envelopes was observed and repair did not occur.     

Sperm nuclear chromatin transformations in somatic cell-free extracts

HeLa cell extracts induced decondensation of lysolecithin permeabilized Xenopus, pig, and human sperm chromatin; decondensation began almost immediately on incubation in the extract and was completed within 10–20 min. The average enlargements of human and pig sperm nuclei were 15-fold and 3-fold, respectively. The structural organization of pig and human sperm chromatin was significantly differnt. Decondensation was differentially inhibited by Mg⁺⁺ and polyamines; inhibition was least for Xenopus and most for pig sperm nuclei. The nuclear membrane was disintegrated on chromatin dispersion, whereas the nuclei which failed to decondense exhibited distinct nuclear envelopes. The decondensing factors were stable at 65°C for 15 min. The dispersed chromatin was remodelled to somatic nucleosomal structures within 60 min. The remodelled chromatin could be recondensed to chromosome-like structures, when incubated further in extracts from mitosis arrested HeLa cells. © 1994 Wiley-Liss, Inc.     

The use of colchicine in investigation of the life cycle of Chlorella

Summary A 0.5% colchicine solution prevents cell division and spore formation in synchronous cultures of Chlorella completely if applied 14 hours after onset of illumination or earlier. DNA-synthesis is only slightly delayed by the same colchicine treatment, while RNA and protein synthesis are not inhibited.The target of the irreversible action of colchicine most probably are short developmental stages during successive nuclear duplication steps. The divisional phase lies between 14 1/2 and 18 1/2 hours after the begin-ning of the light period and comprises 3–5 cycles of alternating nuclear and protoplast duplications, with individual cycle lengths of about 35 min. The time elapsing between a nuclear division and the protoplast division belonging to it could not be determined exactly but lies in the range of 10–25 min. DNA synthesis seems to be completed at the time when nuclear divisions set in.It could be proved that induction of cell division and the event of nuclear division are two completely different processes and can be separated by a time interval of up to 5 hours. The existence of a G₂-phase could not be found in the development cycle of Chlorella.Evidence is presented that the S-phase, besides its function in DNA-synthesis may play a special role in the control of nuclear division.

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Zusammenfassung Die Zellteilung und Sporenausbildung in synchronen Kulturen von Chlorella wird vollständig gehemmt, wenn bis spätestens 14 Std nach dem Lichtbeginn 0,5% Colchicin zugegeben werden. Die DNS-Synthese wird dabei nur leicht verzögert, während RNS- und Proteinsynthese nicht gehemmt werden.Angriffspunkt für die irreversible Colchicinwirkung sind sehr wahrscheinlich kurze Entwicklungsabschnitte in den aufeinanderfolgenden Kernverdoppelungen. Die Teilungsphase liegt zwischen 14 1/2 und 18 1/2 Std nach dem Beginn der Lichtzeit und besteht aus 3–5 Cyclen alternierender Kern- und Protoplastenteilungen mit einer Cyclusdauer von etwa 35 min. Der zeitliche Abstand, mit dem eine Protoplastenteilung der zugehörigen Kernteilung folgt, kann vorläufig nur ungenau mit 10–25 min angegeben werden. Die DNS-Synthese scheint zu dem Zeitpunkt, in dem die Kernteilungen einsetzen, bereits beendet zu sein.Es hat sich ergeben, daß die Auslösung der Zellteilung und der Vorgang der Kernteilung zwei vollständig verschiedene Prozesse sind, die durch ein Zeitintervall von 5 Std voneinander getrennt sein können. Das Vorhandensein einer G₂-Phase wurde in der Entwicklung der Chlorella-Zelle nicht beobachtet.Es sind Anzeichen dafür vorhanden, daß der S-Phase neben ihrer Funktion in der DNS-Synthese auch eine besondere Rolle in der Steuerung der Kernteilung zukommt.

     

Immunonucleochemistry: a new method for in situ detection of antigens in the nucleus of cells in culture

The advancement of immunocytochemistry (ICC) allows one to observe detailed spatial distribution of cellular antigens, but, with some limitations. Using conventional ICC, it is difficult to distinguish the nuclear localization from cytoplasm, as two large subcellular compartments overlap on the z-axis. In this study, we have investigated whether in situ immunostaining of ‘naked’ nuclei could provide an unambiguous method for detection of nuclear antigens. We have designed a protocol that efficiently lyses plasmalemma, while keeping the nuclear envelope intact. The optimal condition for lysing the plasmalemma was 0.5% Nonidet P-40 for 5 min in both neuronal and non-neuronal cultured cells. Using this protocol, we could unambiguously isolate nuclear from cytoplasmic ICC signals. Since the present protocol has been designed for immunostaining of ‘naked’ nuclei from cultured or isolated cells, we have coined a new term to refer to this procedure as ‘immunonucleochemistry’ (‘INC’ for abbreviation).     

Chromosomal RNA synthesis in polytene chromosomes of Chironomus tentans

The presence of heterogeneous RNA of high molecular weight has been demonstrated on the giant chromosomes, in the nuclear sap and in the cytoplasm of the salivary glands in Chironomus tentans. The kinetic properties of this heterogeneous RNA have also been outlined in some detail. — Salivary glands were incubated for different time intervals (20, 45 and 180 min) in haemolymph, supplemented with tritiated cytidine and uridine. The different cellular components were isolated by micromanipulation and RNA extracted with an SDS-pronase solution and analysed with electrophoresis in agarose. — Heterogeneous, high molecular weight RNA with a peak around 35 S was saturated with label on chromosome I, II and III in 45 min, although the synthetic capacity was unchanged during at least 180 min incubation. This indicated a complete turnover of heterogeneous RNA on the chromosomes in less than 45 min. The turnover time in the giant puffs (the so called Balbiani rings) on the fourth chromosome, was even shorter and estimated to less than 30 min. No shift in the electrophoretic pattern of this heterogeneous RNA was found to occur on the chromosomes during long incubation times or during actinomycin D experiments. These labelling characteristics of heterogeneous RNA on the chromosomes indicate that all the different molecules in the heterogeneous RNA have a similar and rapid turnover. A conversion to smaller, stable molecules was excluded. — Heterogeneous RNA of a distribution corresponding to that on the chromosomes was found in the nuclear sap and also in the cytoplasm. The activity in both these cellular compartments increased between 45 and 180 min incubation. The distribution pattern for high molecular weight RNA was in all experiments similar on the chromosomes, in the nuclear sap and in the cytoplasm. It appears that at least a considerable part of the high molecular weight RNA leaves the chromosomes to enter the nuclear sap and lateron to some extent the cytoplasm in this high molecular form. Stable molecules of smaller size (6–15 S) did not appear during 180 min incubation. The data indicate, however, also a substantial breakdown of heterogeneous RNA to acid soluble products during this time.     

Ras-associated nuclear structural change appears functionally significant and independent of the mitotic signaling pathway

An altered nuclear morphology has been previously noted in association with Ras activation, but little is known about the structural basis, functional significance, signaling pathway, or reproducibility of any such change. We first tested the reproducibility of Ras-associated nuclear change in a series of rodent fibroblast cell lines. After independently developing criteria for recognizing Ras-associated nuclear change in a Papanicolaou stained test cell line with an inducible H(T24)-Ras oncogene, two cytopathologists blindly and independently assessed 17 other cell lines. If the cell lines showed Ras-associated nuclear change, a rank order of increasing nuclear change was independently scored. Ras-associated nuclear changes were identified in v-Fes, v-Src, v-Mos, v-Raf, and five of five H(T24)-Ras transfectants consisting of a change from a flattened, occasionally undulating nuclear shape to a more rigid spherical shape and a change from a finely textured to a coarse heterochromatic appearance. Absent or minimal changes were scored in six control cell lines. The two cytopathologists' independent morphologic rank orders were similar (P< .0002). The mitogen signaling pathway per se does not appear to transduce the change since no morphologic alterations were identified in cell lines with activations of downstream components of this pathway—MAPKK or c-Myc—and the rank orders did not correlate with markers of mitotic rate (P > .11). The rank order correlated closely with metastatic potential (P < .0014 and P < .0003) but not with histone H1 composition or global nuclease sensitivity. Based on published studies of five of the cell lines, there may be a correlation between increases in certain nuclear matrix proteins and the Ras-associated nuclear change. J. Cell. Biochem. 70:130–140, 1998. © 1998 Wiley-Liss, Inc.     

Patterns of oscillation during mitosis in plasmodia ofPhysarum polycephalum

Summary The rhythmic contraction pattern in plasmodia ofPhysarum polycephalum was studied to determine whether characteristic changes occur during the synchronized nuclear division. An electrical method that measures the contraction rhythm in situ during several cell cycles was used. Biopsies of the plasmodia were taken at 17 min intervals for precise determination of the cell cycle stages and were correlated with the simultaneously measured contraction rhythm. All measurements were performed in a temperature controlled environment (27 °C) at 100% relative humidity with the plasmodia (less than 24 h old) growing on a semi-defined agar medium. A total of 14 different plasmodia have been examined, and on one occasion the plasmodium was followed through 3 subsequent mitoses. The mitotic stages were identified with aceto-orcein coloring techniques and by fluorescence methods. Except for a few cases where a mitotic asynchrony of 2–3 min was observed, the mitotic events occurred simultaneously in the nuclei within a single plasmodium. Both the occurrence of the first mitosis after inoculation and the intermitotic times were highly variable. Our study indicates that the contraction rhythm in plasmodia ofPhysarum is unperturbed during the synchronized nuclear division. However, in 5 of the 17 examined mitoses an amplitude decay was observed. We discuss possible explanations for the obtained results with emphasis on the applied techniques, interpretation of the oscillation patterns, and possible restrictions in the cell itself.     

MICROTUBULE-MICROFILAMENT-CONTROLLED NUCLEAR MIGRATION IN THE DESMID EUASTRUM OBLONGUM1

Postmitotic nuclear migration in Euastrum oblongnum Ralfs ex Ralfs starts about 80 min after septum formation with the nucleus leaving its central position in the isthmus and moving into the growing semicell. Nuclear migration is influenced by the chloroplast, which expands into the growing half-cell and pushes the nucleus toward one side of the cell. The nucleus occupies its farthest position from the isthmus when located in the middle of the growing semicell directly under the central depression of the cell surface. It remains in this position during the subsequent stages of cell development and moves back toward the isthmus within a chloroplast groove about 12 h after completion of cell shape formation. Bundles of microtubules (MTs) emanating from a microtubule center surround the nucleus during its motion. They reach far into the growing half-cell as long as the nucleus is moving but vanish when the nucleus stays in the growing semicell. MT-disrupting agents inhibit the backward movement of the nucleus toward the isthmus indicating that MTs are involved in this motion too. Because both MT inhibitors and cytochalasin B influence nuclear motion in Euastrum, an interaction of MTs and microfilaments is thought to function as the motive force for nuclear migration.     

COMPARISON OF NUCLEIC ACIDS IN MAIZE SHOOTS AND PEA EPICOTYLS

A nucleic acid component (x-RNA) has been found in high concentration in maize shoots. It is eluted from a MAK (methylated albumin kieselguhr) column at about the same position as messenger RNA. The amount of x-RNA in pea epicotyls is absent or very low. It is suggested that x-RNA is long-lived messenger RNA and is found in high concentration in monocotyledonous plants, especially in the case of plants of the Gramineae family. Dicotyledonous plants, typically, contain little or no detectable x-RNA as observed by ultraviolet absorbancy. In the case of corn shoots, x-RNA is in highest concentration in the ribosomal fraction (78,500 × g, 70 min). In both maize shoots and pea epicotyls the newly synthesized nucleic acids were confined to the nuclear fraction (10,000 × g, 10 min).     

Properties of RNA fractions from nuclei of brain cells which stimulate incorporation of amino acids by brain ribosomes

Abstract— The properties of RNA fractions from nuclei of brain cells which were capable of stimulating amino acid incorporation into proteins of an homologous ribosomal system were investigated. RNA was routinely prepared from crude nuclear preparations of rat brain by a method which involved treatment with sodium dodecyl sulphate and phenol at 65°. The capacity of this preparation to stimulate incorporation of radioactivity from a mixture of 15 l -[¹⁴C]amino acids was greatly enhanced by preliminary incubation of the ribosomal system from brain for 5–20 min. The response was markedly dependent upon the concentrations of ribosomes and of the pH 5 fraction. The optimal level of Mg²⁺ for basal incorporation of amino acids into protein was 8 mm ; however, incorporation in the presence of nuclear RNA was greater at higher concentrations of Mg²⁺. The response to nuclear RNA was also enhanced as the K⁺ concentration was increased from 25 to 100 mm . The stimulatory effect of nuclear RNA on incorporation of l -[¹²C]eucine was either unaltered or depressed by addition of a mixture of 19 l -[¹²C]amino acids each at concentrations, of 10^?8, 10^?2, or 10^?1 mm . Under appropriate conditions of incubation, basal rates of incorporation and rates of incorporation stimulated by nuclear RNA were linear for 30 min. The response was proportional to the concentration of nuclear RNA between 34 and 136 μg. RNA prepared from ribosomes of rat brain essentially failed to stimulate incorporation of amino acids over this range of concentrations. Fractionation of nuclear RNA by centrifugation in sucrose density gradients revealed that 75 per cent of the stimulatory activity was in the fraction which sedimented below 12 S and contained about 25 per cent of the total RNA. Most of the remaining activity was in the 18 S region. Less than 5 per cent of the RNA in the lightest fraction (< 12 S) exhibited amino acid-acceptor activity, The stimulatory action of nuclear RNA on incorporation of amino acids was readily destroyed by mild treatment with pancreatic ribonuclease, whereas amino acid-acceptor activity was relatively resistant to this treatment. The results suggest that the brain may contain low molecular weight RNA with properties of messenger RNA.     

Cell division and the production of cells lacking nuclear bodies in a mutant of Salmonella typhimurium

Summary There are two distinct division phases when the temperature-sensitive DNA synthesis initiation mutant Salmonella typhimurium strain 11G is shifted from 25° to 38°. The first phase appears to represent segregation of the nuclear bodies formed at 38°. Division in this phase takes place at the normal size and produces mainly organisms with one nuclear body. It is dependent on the termination of the rounds of replication in operation at the time of the temperature shift and sensitive to low doses of penicillin. This division phase continues for 60–75 min and then after a short lag division restarts. At first the cells undergoing the second division phase are only slightly larger than normal but they soon grow into short filaments which bud off cells at both ends even if only one nuclear body is present. The cells budded off in this division phase are about 3 long on both broth and M M. They lack nuclear bodies but have a small amount of DNA which may be exclusively in the form of a large plasmid. This second division phase is also dependent on rounds of replication being allowed to terminate at 38° and is sensitive to low levels of penicillin. It is 80–90 min after the temperature shift before the second division phase starts and this lag is maintained even if rounds of replication have been completed prior to the temperature shift by amino acid starvation at 25°. The occurrence of this lag and the demonstration (using penicillin) of potential division sites at regular intervals along 11G filaments suggest that division is initiated some time before the actual division event.