Regulation of accumulation of ammonium-inducible glutamate dehydrogenase catalytic activity and antigen during the cell cycle of fully induced, synchronous Chlorella sorokiniana cells.

By use of a rocket immunoelectrophoresis-activity stain procedure, it was shown that catalytic activity of an ammonium-inducible nicotinamide adenine dinucleotide phosphate-specific glutamate dehydrogenase (NADP-GDH) was accompanied by a coincident increase in enzyme antigen during the cell cycle of preinduced synchronous Chlorella sorokiniana cells growing in the continuous presence of ammonia. Between the fourth and fifth hours of the G-1 phase of the cell cycle, a three- to fourfold increase in linear accumulation of enzyme antigen was observed. Pulse-chase studies with [35S]sulfate, coupled with a specific indirect immunoadsorption procedure for enzyme antigen, showed that NADP-GDH antigen undergoes continuous degradation (i.e., a half-life of 88 to 110 min) during its linear pattern of accumulation during the cell cycle. The apparent half-life of the enzyme increased by approximately 23% of the 4.5-h positive rate change in antigen accumulation during the cell cycle. This increase in half-life is insufficient in itself to account for the large change in rate of NADP-GDH antigen accumulation. The data from immunoelectrophoresis, pulse-chase, and initial 35S incorporation rate experiments taken together support the inference that changes in the rate of NADP-GDH synthesis are primarily responsible for the accumulation patterns of NADP-GDH activity during the C. sorokiniana cell cycle.     

Cell Cycle Timing of Replication of the Nuclear Gene Encoding Chloroplastic NADP-Specific Glutamate Dehydrogenase Isoenzymes in Chlorella sorokiniana

In synchronized Chlorella sorokiniana cells, the NH₄⁺ inducibleNADP-specific glutamate dehydrogenase enzyme (NADP-GDH) accumulatedin a linear manner throughout the first cell cycle. Early inthe following second cell cycle, an increase in its rate ofaccumulation occurred that was proportional to the increasein total cellular DNA in the previous cell cycle. In synchronizedbacterial cells, increases in rate of linear accumulation ofinducible enzymes coincide with the time of replication of theirstructural genes. To determine whether the rate change in NADPGDHaccumulation resulted from a delay in replication of its nuclearstructural gene (gdhN) in fully induced C. sorokiniana cells,the cell cycle timing of replication of this gene was comparedto that of another nuclear gene, nitrate reductase (nia), andof a chloroplast gene, ribulose bisphosphate carboxylase large-subunit(rbcL), in synchronized cells cultured in NH₄⁺ or NO₃^–(uninduced) medium. The gdhN and nia genes replicated withinthe period of nDNA synthesis and rbcL within the period of ctDNAsynthesis in cells growing in either nitrogen source. Therefore,the delayed rate change in enzyme accumulation results froma process that regulates expression of the gdhN gene after itsreplication. (Received July 16, 1994; Accepted November 28, 1994)     

Relationship between cellular autolytic activity, peptidoglycan synthesis, septation, and the cell cycle in synchronized populations of Streptococcus faecium.

Synchronized, slowly growing (TD = 70 to 80 min) cultures were used to study several wall-associated parameters during the cell cycle: rate of peptidoglycan synthesis, septation, and cellular autolytic activity. The rate of peptidoglycan synthesis per cell declined during most of the period of chromosome replication (C), but increased during the latter part of C and into the period between chromosome termination and cell division (D). An increase in cellular septation was correlated with the increased rate of peptidoglycan synthesis. Cellular autolytic capacity increased during the early portion of C, reached a maximum late in C or early in D, and declined during D. Inhibition of DNA synthesis during C prevented the decline in autolytic capacity at the end of the cell cycle, caused a slight reduction in the rate of peptidoglycan synthesis, delayed but did not prevent septation, and prevented the impending cell division by inhibiting cell separation. Inhibition of DNA synthesis during D did not prevent the increase in autolytic capacity during the next C phase, but, once again, prevented the decline at the end of the subsequent cycle. Thus, increased autolytic capacity at the beginning of the cell cycle did not seem to be related to chromosome initiation, whereas decreased autolytic capacity at the end of the cell cycle seemed to be related to chromosome termination. The data presented are consistent with the role of autolytic enzyme activity in the previously proposed model for cell division of S. faecium (G.D. Shockman et al., Ann. N.Y Acad. Sci. 235:161-197, 1974).     

Does capacity of DNA replication change during in vitro ageing?

We described elsewhere how a lack of change in the rate of DNA chain elongation occurred during in vitro ageing of human diploid fibroblasts. Here we further examined the rate of actual incorporation of tritiated thymidine, the center-to-center distance of replicons and the length of each phase of the cell cycle in order to extend our previous results to the other aspects of DNA replication. The results obtained showed that the rate of net DNA synthesis, the replicon size and the duration of S phase did not change during in vitro ageing. Our findings indicated that the reason why the greater part of the cell population at high population doubling levels becomes incapable of proliferating might not be the gradual decline in the ability of DNA replication. The regulation system(s) of DNA replication may alter during the period of culturing without any change in the capacities of the DNA replication machinery and, consequently, the non-cycling cells increase.     

顺铂靶向食管癌细胞周期Cx43表达的研究

目的:为研究顺铂治疗食管鳞癌细胞的靶向作用。方法:本研究使用流式细胞技术双变量分析检测顺铂对食管癌细胞周期进程和癌细胞周期的连接蛋白43(connexin 43,Cx43)表达的影响。结果:顺铂对食管鳞癌细胞周期的影响主要作用于S期的DNA复制,细胞阻滞于S期,G2/M期减少。顺铂诱导食管鳞癌细胞周期S和G2/M期的Cx43表达的大幅度改变。低浓度顺铂(由0~2μmol/L),Cx43表达增强;顺铂渐高浓度(2~12μmol/L),细胞Cx43表达由强逐渐变弱,特别是G2/M期细胞的Cx43表达活跃,易受顺铂影响。结论:我们的研究表明以顺铂处理食管鳞癌细胞,癌细胞周期的S期和G2/M期的Cx43表达与S期的DNA复制一样可作为的潜在治疗靶标。顺铂靶向作用细胞周期S和/或G2/M期细胞的特性可能减少或避免对非分裂细胞的影响。     

Regulation of proliferating cell nuclear antigen during the cell cycle

The proliferating cell nuclear antigen (PCNA), also known as cyclin and DNA polymerase delta auxiliary factor, is present in reduced amounts in nongrowing cells and is synthesized at a greater rate in the S phase of growing cells. The recently discovered involvement of PCNA in DNA replication suggested that this pattern of expression functions to regulate DNA synthesis. We have investigated this possibility further by examining the synthesis, stability, and accumulation of PCNA in HeLa cells fractionated by centrifugal elutriation into nearly synchronous populations of cells at various positions in the cell cycle. In these fractionated cells we found that there is an increase in the rate of PCNA synthesis with a peak in early S phase of the cell cycle, but the magnitude of the increase is only 2-3-fold. This change reflects similar changes in the amount of PCNA mRNA. The fluctuating synthesis of PCNA maintains this protein at a roughly constant proportion of the total cell protein, although the amount doubles/cell in the cell cycle. Consistent with this observation, the stability of PCNA does not differ significantly from that of total cellular protein in synchronized HeLa cells. We also observed that a maximum of one-third of the total PCNA is tightly associated with the nucleus, presumably in replication complexes, at the peak of S phase. We conclude that the cyclic synthesis of PCNA in cycling HeLa cells maintains PCNA in excess of the amount involved directly in DNA replication and the amount of the protein neither fluctuates significantly with the cell cycle nor is limiting for DNA synthesis.     

The cell cycle-coupled expression of topoisomerase IIalpha during S phase is regulated by mRNA stability and is disrupted by heat shock or ionizing radiation.

Topoisomerase II is a multifunctional protein required during DNA replication, chromosome disjunction at mitosis, and other DNA-related activities by virtue of its ability to alter DNA supercoiling. The enzyme is encoded by two similar but nonidentical genes: the topoisomerase IIalpha and IIbeta genes. In HeLa cells synchronized by mitotic shake-off, topoisomeraseII alpha mRNA levels were found to vary as a function of cell cycle position, being 15-fold higher in late S phase (14 to 18 h postmitosis) than during G1 phase. Also detected was a corresponding increase in topoisomerase IIalpha protein synthesis at 14 to 18 h postmitosis which resulted in significantly higher accumulation of the protein during S and G2 phases. Topoisomerase IIalpha expression was not dependent on DNA synthesis during S phase, which could be inhibited without effect on the timing or level of mRNA expression. Mechanistically, topoisomerase IIalpha expression appears to be coupled to cell cycle position mainly through associated changes in mRNA stability. When cells are in S phase and mRNA levels are maximal, the half-life of topoisomerase IIalpha mRNA was determined to be approximately 30 min. A similar decrease in mRNA stability was also induced by two external factors known to delay cell cycle progression. Treatment of S-phase cells, at the time of maximum topoisomerase IIalpha mRNA stability, with either ionizing radiation (5 Gy) or heat shock (45 degrees C for 15 min) caused the accumulated topoisomerase IIalpha mRNA to decay. This finding suggests a potential relationship between stress-induced decreases in topoisomerase IIalpha expression and cell cycle progression delays in late S/G2.     

In vivo accumulation of cyclin A and cellular replication factors in autonomous parvovirus minute virus of mice-associated replication bodies

Autonomous parvovirus minute virus of mice (MVM) DNA replication is strictly dependent on cellular factors expressed during the S phase of the cell cycle. Here we report that MVM DNA replication proceeds in specific nuclear structures termed autonomous parvovirus-associated replication bodies, where components of the basic cellular replication machinery accumulate. The presence of DNA polymerases alpha and delta in these bodies suggests that MVM utilizes partially preformed cellular replication complexes for its replication. The recruitment of cyclin A points to a role for this cell cycle factor in MVM DNA replication beyond its involvement in activating the conversion of virion single-stranded DNA to the duplex replicative form.     

Electron microscopic analysis of chromatin replication in the cellular blastoderm drosophila melanogaster embryo

Transmission electron microscopic techniques were used to study the spatial distribution of replicons and the ultrastructure of chromatin in the S phase genome of cellular blastoderm Drosophila melanogaster embryos. We observed chromatin exhibiting distinct bifurcations along each fiber during the initial 20 min of the first cell cycle of blastulation. We interpreted the “bubble-like” configurations produced by adjacent bifurcations as intermediate structures in chromatin replication (that is, replicons). We observed homologous ribonucleoprotein (RNP) fiber arrays on both chromatid arms within some replicons, implying DNA sequence homology and reinforcing the identification of such arms as daughter chromatid fibers. We did not observe replicon configurations on chromatin obtained from embryos staged at more than 20 min into cellular blastulation. Daughter chromatid fibers, however, were identified by the presence of identical RNP fiber arrays on chromatid strands arranged in parallel on the electron microscope grid.We examined the distribution of replicon structures on the cellular blastoderm genome and compared it with electron microscopic data on DNA replication in cleavage embryos (Blumenthal, Kriegstein and Hogness, 1973). S phase is completed in slightly < 4 min during cleavage, or approximately one fifth the time required for DNA synthesis in cellular blastoderm embryos. The mean distance separating adjacent replication origins at cellularization was estimated to be 10.6 kilobases (kb), a value 35% greater than the 7.9 kb inter-origin average determined for cleavage embryos. In contrast to the near-simultaneous activation of replication origins during cleavage replication, we observed that replication origins are not activated synchronously at cellular blastulation. We concluded that the marked increase in the duration of S phase is effected by a reduction in the frequency of replication activation events which occur asynchronously during genome replication at cellularization.We found that the ultrastructure of newly replicated chromatin exhibited a morphology indistinguishable from nucleosomal chromatin. Unreplicated chromatin fibers separating adjacent replicons also exhibit spherical subunits. We inferred that the spherical structures on replicating chromatin are nucleosomes and concluded that histones are not disassociated from the DNA significantly prior to DNA replication, and that a very rapid reassociation of nucleosomes occurs on both daughter DNA molecules following replication.     

Safeguarding genome integrity: the checkpoint kinases ATR, CHK1 and WEE1 restrain CDK activity during normal DNA replication

Mechanisms that preserve genome integrity are highly important during the normal life cycle of human cells. Loss of genome protective mechanisms can lead to the development of diseases such as cancer. Checkpoint kinases function in the cellular surveillance pathways that help cells to cope with DNA damage. Importantly, the checkpoint kinases ATR, CHK1 and WEE1 are not only activated in response to exogenous DNA damaging agents, but are active during normal S phase progression. Here, we review recent evidence that these checkpoint kinases are critical to avoid deleterious DNA breakage during DNA replication in normal, unperturbed cell cycle. Possible mechanisms how loss of these checkpoint kinases may cause DNA damage in S phase are discussed. We propose that the majority of DNA damage is induced as a consequence of deregulated CDK activity that forces unscheduled initiation of DNA replication. This could generate structures that are cleaved by DNA endonucleases leading to the formation of DNA double-strand breaks. Finally, we discuss how these S phase effects may impact on our understanding of cancer development following disruption of these checkpoint kinases, as well as on the potential of these kinases as targets for cancer treatment.     

Replication of Simian Virus 40 Deoxyribonucleic Acid: Analysis of the One-Step Growth Cycle

The time course of replication of simian virus 40 deoxyribonucleic acid (DNA) was investigated in growing monolayer cultures of subcloned CV1 cells. At multiplicities of infection of 30 to 60 plaque-forming units (PFU)/cell, first progeny DNA molecules (component 1) were detected by 10 hr after infection. During the following 10 to 12 hr, accumulation of virus DNA proceeded at ever increasing rates, albeit in a non-exponential fashion. The rate of synthesis then remained constant, until approximately the 40th hour postinfection, when DNA replication stopped. Under these conditions, the duration of the virus growth cycle was approximately 50 hr. The time needed for the synthesis of one DNA molecule was found to be approximately 15 min. At multiplicities of infection of 1 or less than 1 PFU/cell, the onset of the linear phase of DNA accumulation was delayed, but the final rate of DNA synthesis was the same, independent of the input multiplicity. This was taken as a proof that templates for the synthesis of viral DNA multiply in the cell during the early phase of replication. However, the probability for every replicated DNA molecule to become in turn replicative decreased constantly during that phase. This could be accounted for by assuming a limited number of replication sites in the infected cell.     

Simian virus 40 induces multiple S phases with the majority of viral DNA replication in the G2 and second S phase in CV-1 cells

The infection of permissive monkey kidney cells (CV-1) with simian virus 40 induces G1 growth-arrested cells into the cell cycle. After completion of the first S phase and movement into G2, mitosis was blocked and the cells entered another DNA synthesis cycle (second S phase). Growth-arrested CV-1 cells replicated significant amounts of viral DNA in the G2 phase with the majority of synthesis occurring during the second S phase. When mimosine-blocked (G1/S) infected cells were released into the cell cycle, a major portion of the viral DNA was detected in G2 with the largest accumulation in the second S phase. The total DNA produced per infected cell was 10-12C with approximately 0.5-2C of viral DNA replicated per cell. Therefore the majority of the DNA per cell was cellular, 4C from the first S phase and approximately 4-6C from the second cellular synthesis phase.     

Cell-cycle-specific F plasmid replication: regulation by cell size control of initiation.

F plasmid replication during the Escherichia coli division cycle was investigated by using the membrane-elution technique to produce cells labeled at different times during the division cycle and scintillation counting for quantitative analysis of radioactive plasmid DNA. The F plasmid replicated, like the minichromosome, during a restricted portion of the bacterial division cycle; i.e., F plasmid replication is cell-cycle specific. The F plasmid replicated at a different time during the division cycle than a minichromosome present in the same cell. F plasmid replication coincided with doubling in the rate of enzyme synthesis from a plasmid-encoded gene. When the cell cycle age of replication of the F plasmid was determined over a range of growth rates, the cell size at which the F plasmid replicated followed the same rules as did replication of the bacterial chromosome--initiation occurred when a constant mass per origin was achieved--except that the initiation mass per origin for the F plasmid was different from that for the chromosome origin. In contrast, the high-copy mini-R6K plasmid replicated throughout the division cycle.     

Human Parvovirus B19 Infection Causes Cell Cycle Arrest of Human Erythroid Progenitors at Late S Phase That Favors Viral DNA Replication

Human parvovirus B19 (B19V) infection has a unique tropism to human erythroid progenitor cells (EPCs) in human bone marrow and the fetal liver. It has been reported that both B19V infection and expression of the large nonstructural protein NS1 arrested EPCs at a cell cycle status with a 4 N DNA content, which was previously claimed to be “G₂/M arrest.” However, a B19V mutant infectious DNA (M20^mTAD2) replicated well in B19V-semipermissive UT7/Epo-S1 cells but did not induce G₂/M arrest (S. Lou, Y. Luo, F. Cheng, Q. Huang, W. Shen, S. Kleiboeker, J. F. Tisdale, Z. Liu, and J. Qiu, J. Virol. 86:10748–10758, 2012). To further characterize cell cycle arrest during B19V infection of EPCs, we analyzed the cell cycle change using 5-bromo-2′-deoxyuridine (BrdU) pulse-labeling and DAPI (4′,6-diamidino-2-phenylindole) staining, which precisely establishes the cell cycle pattern based on both cellular DNA replication and nuclear DNA content. We found that although both B19V NS1 transduction and infection immediately arrested cells at a status of 4 N DNA content, B19V-infected 4 N cells still incorporated BrdU, indicating active DNA synthesis. Notably, the BrdU incorporation was caused neither by viral DNA replication nor by cellular DNA repair that could be initiated by B19V infection-induced cellular DNA damage. Moreover, several S phase regulators were abundantly expressed and colocalized within the B19V replication centers. More importantly, replication of the B19V wild-type infectious DNA, as well as the M20^mTAD2 mutant, arrested cells at S phase. Taken together, our results confirmed that B19V infection triggers late S phase arrest, which presumably provides cellular S phase factors for viral DNA replication.     

TIME SEQUENCE OF NUCLEAR PORE FORMATION IN PHYTOHEMAGGLUTININ-STIMULATED LYMPHOCYTES AND IN HELA CELLS DURING THE CELL CYCLE

The time sequence of nuclear pore frequency changes was determined for phytohemagglutinin (PHA)-stimulated human lymphocytes and for HeLa S-3 cells during the cell cycle. The number of nuclear pores/nucleus was calculated from the experimentally determined values of nuclear pores/µ² and the nuclear surface. In the lymphocyte system the number of pores/nucleus approximately doubles during the 48 hr after PHA stimulation. The increase in pore frequency is biphasic and the first increase seems to be related to an increase in the rate of protein synthesis. The second increase in pores/nucleus appears to be correlated with the onset of DNA synthesis. In the HeLa cell system, we could also observe a biphasic change in pore formation. Nuclear pores are formed at the highest rate during the first hour after mitosis. A second increase in the rate of pore formation corresponds in time with an increase in the rate of nuclear acidic protein synthesis shortly before S phase. The total number of nuclear pores in HeLa cells doubles from ~2000 in G₁ to ~4000 at the end of the cell cycle. The doubling of the nuclear volume and the number of nuclear pores might be correlated to the doubling of DNA content. Another correspondence with the nuclear pore number in S phase is found in the number of simultaneously replicating replication sites. This number may be fortuitous but leads to the rather speculative possibility that the nuclear pore might be the site of initiation and/or replication of DNA as well as the site of nucleocytoplasmic exchange. That is, the nuclear pore complex may have multiple functions.     

Nucleic Acid Profile of the Emt6 Cell Cycle In Vitro

Simultaneous RNA and DNA estimations were carried out during the cell cycle of EMT6/M/CC cells growing in vitro following synchronization by mitotic selection. the determinations were performed with a flow cytofluorimeter on individual cells stained with acridine orange. It was found that the RNA content increased during G₁ then remained virtually constant between early and mid S phase, but a second increase occurred during late S. the rate of uptake of tritiated uridine paralleled these changes in RNA levels, and it was also found that the rate of uptake in metaphase and anaphase was virtually zero, but a rapid increase occurred in telophase. the increase in DNA during S was approximately linear, and the intermitotic phase and cycle durations were very similar to previously reported results.