Absence of translational control of histone synthesis during the HeLa cell life cycle

The cell-free synthesis of histone-like polypeptides has been achieved using a selected class of small polyribosomes as the only particulate fraction. This synthesis is prevented if the deoxyribonucleic acid (DNA) inhibitor, cytosine arabinoside, is added to the cells prior to disruption, and it is not detected when the cytoplasm used is derived from postmitotic (G₁) cells. When the 100,000 g supernate from pure metaphase populations was compared with that from S phase cells, the cell-free synthesis of histone-like polypeptides in the presence of S phase polyribosomes remained unchanged. These data suggest that, except for the histone messenger RNA-ribosome complex, the cytoplasmic factors requisite for histone synthesis are present throughout the cycle, and that the shut-off of this synthesis is not under translational control.     

Chromatin changes during the cell cycle.

Considerable progress has recently been made in elucidating the biochemical mechanisms regulating changes in chromatin structure during all stages of the cell cycle. Although anticipated, the apparently ubiquitous role played by phosphorylation/dephosphorylation reactions in modulating these changes is, nonetheless, remarkable.     

Differential nuclear fluorescence during the cell cycle.

With a modified quinacrine dihydrochloride staining method interphase nuclei show differences in their fluorescent characteristics. In human embryonic fibroblasts and synchronized HeLa cells (S₃), it could be demonstrated that these patterns reflect their position within the cell cycle. This study provides further evidence for conformational changes of chromatin during interphase and offers a cytological method for distinguishing cell cycle stages.     

Lipid synthesis during the Escherichia coli cell cycle.

Lipid synthesis was examined in Escherichia coli cells at different stage of cell division. Exponentially growing cells were pulse-labeled with appropriate isotopes for 0.1 generation time, inactivated, and separated by size on a sucrose gradient. An abrupt increase in the rate of lipid synthesis occurred which was coincident with the initiation of cross walls. In contrast, the rate of protein synthesis during this same interval remained constant, resulting in an increased lipid/protein ratio in dividing cells. No changes in the composition of phospholipid head groups, fatty acids, or phospholipid molecular species were observed in cells at different stages of division. The observed increase in the rate of lipid synthesis may reflect a means by which the activities of membrane-associated enzymes are modulated during cross wall formation.     

Polysome Metabolism during Cold Acclimation in Wheat

The content, composition and biological activity of polysomesfrom three wheat genotypes were studied during cold acclimation.The structural integrity of the different polysome populationswas not affected by the hardening temperature. Polysomes werealso found to accumulate at higher level in cold hardened seedlingssuggesting a high protein synthesis capacity during the acclimationperiod. The in vitro translation of polysome-bound mRNAs inthe wheat germ cell-free system showed a high translation potentialof polysomes from cold hardened seedlings compared to that ofcontrol. The electrophoretic analysis of the translation productsby two-dimensional SDS-PAGE revealed the induction of severalnew mRNAs in cold hardened wheat seedlings. The presence ofthese new messengers in the polysomal fraction suggests thatnew messages have already been processed, transported and preferentiallyselected for translation by the ribosomes. The most importantchange was the induction and pronounced synthesis of four peptides[one high mol wt peptide of 200 kDa (pI 6.5) and three smallerones of 58 (pI 7.0), 48 (pI 7.1) and 48 (pI 7.2) kDa respectively]in the freezing tolerant cultivar Norstar. These specific polypeptideswere absent in the freezing sensitive cultivar Glenlea suggestingthat their induction and expression was associated with thefreezing tolerance capacity. (Received January 19, 1990; Accepted August 24, 1990)     

Ultrastructural labeling of cell surface lectin receptors during the cell cycle.

The distribution of specific surface receptors in the course of the cell cycle has been studied on two transformed cell lines by means of ultrastructural labelling techniques employing Concanavalin A (ConA) and wheat germ agglutinin (WGA). Synchronized cultures of Cl₂TSV₅, an SV40-transformed hamster cell line and of CHO cells were labelled as monolayers or in suspension in the different phases of the cell cycle. In cells labelled in monolayers, a moderately discontinuous pattern of surface labelling was present during G 1, S, and G 2. On cells in mitosis, however, this pattern changes strikingly and becomes very discontinuous. These results indicate that the degree of receptor clustering is greater in mitosis than in interphase. In cells labelled in suspension, the differences in pattern between mitosis and interphase were absent. Colcemid treatment did not modify the distribution of the label, either in interphase or in mitosis. Moreover, cells in mitosis collected by Colcemid treatment and labelled at a moment in which parallel unblocked cultures had completed mitosis and passed into G 1 showed an interphase-type labelling pattern; this indicates that a certain dissociation exists between surface events and nuclear events during mitosis. These results are discussed in terms of several factors that may contribute to the production of receptor clustering, namely, direct lectin action, surface movement and membrane flow, participation of cytoplasmic structures and, finally, attachment of cells to a substratum.     

The cell cycle during amphibian limb regeneration.

The duration of the cell cycle in the blastema of regenerating limbs of axolotls has been measured by means of [3H]thymidine pulse labelling and autoradiography. A chase was required to define the pulse period. An average cell cycle at 20 degrees C takes 53 h, S-phase takes 38 h; including parts of mitosis, G1 is 10 h and G2 is 5 h long. The protracted cycle and S-phase are consonant with the large genome in axolotis and other urodeles. The rapidly growing blastema probably contains a steady population of about 5000 proliferating cells, as there is a regular withdrawal of differentiating cells from the population. The kinds of determination which exist in this population of cells, or are exerted on it, are briefly considered.     

Intracellular localization of terminal transferase during the cell cycle.

Changes in the localization of terminal transferase during the cell cycle in random cultures of human pre-T leukemia line RPMI-8402 were examined by light and electron microscopy on immunoperoxidase-stained preparations. Paraformaldehyde-fixed and saponin-permeabilized human cells were used with a monoclonal anti-human terminal deoxynucleotidyl transferase (TdT) primary reagent to demonstrate changes in enzyme distribution occurring between interphase and mitosis. Nuclear localization is found uniformly during interphase. At metaphase, however, the majority of TdT staining appears randomly distributed in the cytoplasm and traces of TdT staining remain associated with mitotic chromatin. At later phases, when the daughter cells are forming, the enzyme again appears to be restricted to the new nuclear structure.     

Cytoplasmic and nuclear protein kinases during the cell cycle.

Nuclear and cytoplasmic protein kinases were measured during the traverse of synchronous CHO cultures through G1 into S phase. Cells were synchronized by selective detachment of cells blocked in metaphase using colcemid. Nuclei were isolated and the protein kinases extracted from the nuclear preparation with 0.6 M NaCl. This procedure solubilized greater than 90% of the total protein kinase activity present in the nuclear preparation. DEAE chromatography of this extract showed 5 apparently different ionic forms of nuclear protein kinases. The nuclear protein kinases preferred casein and phosvitin to histone as substrates and were cyclic AMP-independent. Nuclear protein kinase activities increased greater than two-fold, when expressed as units of activity per cell nucleus, during G1 phase traverse, concomitant with a 70% increase in nuclear non-histone proteins (those soluble in 0.6 M NaCl). This resulted in only a 40% increase in the specific activities (units/microgram protein in 0.6 M NaCl extractable nuclear fraction) of these enzymes as cells progressed through G1 into S phase. This was in contrast to cytoplasmic cyclic AMP-dependent protein kinase activities which also increased two-fold during progression through G1 phase while total cellular protein increased less than 20%. Activation of, as well as synthesis of, cyclic AMP-dependent cytoplasmic protein kinases during G1 phase suggests a regulatory mechanism for precise temporal phosphorylation, whereas the constant specific activity in nuclear kinases during cell cycle is more compatible with the maintenance of bulk phosphorylation processes in the nucleus.     

Actin dynamics during the cell cycle in Chlamydomonas reinhardtii.

We have used two monoclonal antibodies to demonstrate the presence and localization of actin in interphase and mitotic vegetative cells of the green alga Chlamydomonas reinhardtii. Commercially available monoclonal antibodies raised against smooth muscle actin (Lessard: Cell Motil. Cytoskeleton 10:349-362, 1988; Lin: Proc. Natl. Acad. Sci. USA 78:2335-2339, 1981) identify Chlamydomonas actin as a approximately 43,000-M(r) protein by Western immunoblot procedures. In an earlier study, Detmers and coworkers (Cell Motil. 5:415-430, 1985) first identified Chlamydomonas actin using NBD-phallacidin and an antibody raised against Dictyostelium actin; they demonstrated that F-actin is localized in the fertilization tubule of mating gametes. Here, we show by immunofluorescence that vegetative Chlamydomonas cells have an array of actin that surrounds the nucleus in interphase cells and undergoes dramatic reorganization during mitosis and cytokinesis. This includes the following: reorganization of actin to the anterior of the cell during preprophase; the formation of a cruciate actin band in prophase; reorganization to a single anterior actin band in metaphase; rearrangement forming a focus of actin anterior to the metaphase plate; reextension of the actin band in anaphase; presence of actin in the forming cleavage furrow during telophase and cytokinesis; and finally reestablishment of the interphase actin array. The studies presented here do not allow us to discriminate between G and F-actin. None the less, our observations, demonstrating dynamic reorganization of actin during the cell cycle, suggest a role for actin that may include the movement of basal bodies toward the spindle poles in mitosis and the formation of the cleavage furrow during cytokinesis.     

Intracellular pH changes during the cell cycle in Tetrahymena.

The equilibrium distribution of 5,5-dimethyloxazoladine 2,4-dione (DMO) between intra- and extracellular volume was used to estimate intracellular pH (pHi) in Tetrahymena pyiformis. In control experiments, DMO was found to equilibrate rapidly in response to a pH gradient. Under normal growth conditions, pHi was constant over a finite range of external pH, being maintained near pH 7.1 over the external pH range 5.2 to 7.3. This same range of external pH was also optimal for growth. pHi was monitored during the cell cycle of a synchronous population of T. pyriformis GL. The cells were synchronized either by starvation/refeeding or heat shock. Under both conditions, there were two alkaline shifts of approximately 0.4 pH units per cell cycle. These shifts in pH retained a constant remporal relationship to S phase and were not affected by changes in the time, duration, or magnitude of cytokinesis.     

Theory of distributed quiescent state in the cell cycle

A generalization of the familiar two-compartment or G₀ model of the cell cycle is described. Instead of reserving the quiescent state strictly to newly born cells, it is distributed throughout the cell cycle. A cell may cease its proliferative activities anywhere in the cycle with a probability depending on its maturity. The probability of returning to cycle is also a function of maturity. Analytical expressions for cycle time distributions, growth rates, wave frequency and relative damping rates are derived for certain cases. A stable, diffusion-free numerical algorithm is used to work out some examples.     

HeLa cell plasma membranes. Changes in membrane protein composition during the cell cycle.

HeLa cells grown in suspension culture were synchronized by amethopterin block and thymidine reversal. In some cases an additional Colcemid block was used to obtain mitotic cells. From the various phases of the cell cycle, cells were harvested and the plasma membranes isolated. The membrane proteins were solubilized in sodium dodecyl sulphate and separated by gel electrophoresis in the presence of sodium dodecyl sarcosinate. About 35 protein bands, five of which were stained with periodic acid-Schiff reagent, appeared. Most of the bands were identical in all membrane preparations, but a few minor bands seemed to be associated with limited periods of the cell cycle. In particular, the cells in mitosis apparently contained plasma membrane proteins which did not occur in other phases. Amino acid analyses of the plasma membranes revealed no significant cell cycle-dependent changes in the amino acid composition.     

Polysome disassembly in cell extracts of cricket male accessory gland during sucrose gradient centrifugation

The stability of polysomes in cell extracts of cricket (Acheta domesticus) male accessory gland has been examined by sedimentation through a variety of step and linear sucrose gradients. After prolonged centrifugation there is a considerable decline in polysome content with a concurrent increase in monosomes. The extent of the reduction is more severe in step gradients, although the polysomes that remain show a typical profile on linear gradients.Evidence is presented which indicates that the reduction in polysome content is not due to nuclease action. The presence of detergents can affect the extent of disassembly but is not the principal cause. Comparison of [³H]leucine pulse-labelled gluteraldehyde-fixed and unfixed polysomes subjected to extended centrifugation reveals a release of nascent label near the top of the gradients in unfixed preparations. At least part of this displaced material is present as peptidyl-tRNA, suggesting that forced dissociation of polysomes rather than premature termination of nascent chains occurs as a consequence of sedimentation pressures. Comparison of the distribution of polyadenylic acid (poly(A)) sequences in sucrose gradients following short- and long-term centrifugation shows a shift of poly(A) containing RNA out of the polysome and into the pre-monomer region. It is concluded that sucrose gradient sedimentation results in the disassembly of a portion of the polysome population in the tissue examined. The implications with regard to the study of nonpolysomal messenger ribonucleoprotein and monomeric ribosomes are discussed.