Multiple forms of H4 histone mRNA in human cells.

Two species of H4 histone mRNA were isolated from the polysomes of S phase HeLa S3 cells. Electrophoresis under denaturing and nondenaturing conditions indicates that the two H4 mRNAs differ in size. Both mRNAs translate H4 histones in vitro, lack poly(A) at their 3' termini, and are capped at their 5' termini. Polyacrylamide gel electrophoresis and tryptic peptide analysis suggest that the polypeptides synthesized by the two mRNAs are indistinguishable.     

Cell cycle regulation of dihydrofolate reductase mRNA metabolism in mouse fibroblasts.

We have used the technique of DNA-excess filter hybridization to measure directly the content and metabolism of the mRNA for dihydrofolate reductase (DHFR; 5,6,7,8-tetrahydrofolate:NADP+ oxidoreductase, EC 1.5.1.3). The studies were conducted with a methotrexate-resistant derivative of mouse 3T6 fibroblasts (M50L3) that overproduces the enzyme and its mRNA by a factor of 300 but regulates the level of the enzyme during the cell cycle in the same manner as normal 3T6 cells. We found that, when resting (G0) M50L3 cells were serum-stimulated to reenter the cell cycle, the 10-fold increase in the rate of synthesis of DHFR that occurs at the beginning of S phase was the result of a corresponding increase in DHFR mRNA content. In pulse-labeling experiments, we found that there was a similar increase in the rate of production of the mRNA just prior to S phase. However, the half-life of the mRNA was the same (7.5 hr) in resting and exponentially growing cells. Therefore, the increase in DHFR mRNA content was due to an increase in the rate of production rather than an increase in the stability of the message. The delay between addition of [3H]-uridine to the culture medium and the emergence of DHFR mRNA from the nucleus was 15-20 min for both resting and growing M50L3 cells. A similar delay was observed for total mRNA. Therefore, the time required for the processing of newly synthesized DHFR heterogeneous nuclear RNA into DHFR mRNA is about the same as that for the average mRNA.     

Cell cycle regulation of metallothionein in human colonic cancer cells.

Elevated levels of metallothionein (MT) found in rapidly growing tissues such as neonatal liver and various types of human tumors have suggested a role for MT in cell proliferation. To further explore this possibility we investigated the concentration of MT in human colonic cancer (HT-29) cells at different stages of proliferation by means of immunocytochemistry and competitive binding. MT is increased in subconfluent proliferating cells relative to growth-inhibited confluent cells, much as it is in growing tissues. Cycling cells synchronized with compactin, an inhibitor of 3-hydroxy-3-methylglutaryl-coenzyme A reductase, revealed an oscillation of cytoplasmic MT that reached a maximum in successive late G1 phases and at the G1/S transition. Individual phase of the cell cycle were assessed by [3H]thymidine incorporation and by immunofluorescence employing an antibody that detects a nuclear antigen associated with proliferation. An enzyme-linked immunosorbent assay was used to quantify the relative amounts of MT in homogenate supernatants of HT-29 cells. A 2- to 3-fold increase in MT in actively proliferating cells and the regulation of the protein during the mitotic cell cycle point to a physiological role for MT in cellular proliferation and suggest that it may also serve as a proliferation marker.     

Reassessment of histone gene expression during cell cycle in human cells by using homologous H4 histone cDNA.

The representation of H4 histone mRNA sequences in RNAs isolated from G1 and S phase HeLa cells was assessed by use of a homologous H4 histone cDNA. S phase cells were obtained by double thymidine block, and G1 cells were obtained by double thymidine block or mitotic selective detachment. Nuclear and cytoplasmic RNAs from S phase cells hybridized with H4 histone cDNA as did nuclear and cytoplasmic RNAs from G1 cells synchronized by double thymidine block. In contrast, significant levels of hybridization were not observed between H4 histone cDNA and nuclear, polysomal, or postpolysomal cytoplasmic RNAs of G1 cells synchronized by mitotic selective detachment. Double thymidine block yields a G1 cell population containing 20-25% S phase cells whereas the G1 population obtained by mitotic detachment contains less than 0.1% S phase cells. The ability of H4 histone cDNA to hybridize with the RNAs from G1 cells obtained after release from double thymidine block can therefore be explained by the presence of S phase cells in such a G1 population--an artifact of the synchronization procedure. We interpret these results to be consistent with the presence of H4 histone mRNA sequences during the S but not G1 phase of the cell cycle in continuously dividing HeLa S3 cells.     

Nucleotide-stimulated proteolysis of histone H1.

We have identified a proteolytic system that selectively degrades histone H1 in normal human lymphocytes. Treatment of permeabilized human lymphocytes with a series of nucleotides produced a marked decrease in their histone H1 content compared to untreated cells. The nucleotide-stimulated process was selective for histone H1 because gel electrophoresis showed that almost all other lymphocyte protein bands remained constant while histone H1 disappeared. The elimination of histone H1 appears to be the result of proteolysis by a trypsin-like enzyme because it was inhibited by phenylmethylsulfonyl fluoride, antipain, soybean trypsin inhibitor, and diisopropyl fluorophosphate. Proteolysis was stimulated by P1,P4-di(adenosine-5') tetraphosphate, P1,P3-di(adenosine-5') triphosphate, P1,P5-di(adenosine-5') pentaphosphate, adenosine 5'-tetraphosphate, ATP, adenosine 5'-[alpha, beta-methylene]triphosphate, adenosine 5'-[beta, gamma-methylene]triphosphate, ADP, CTP, GTP, UTP, dATP, or pyrophosphate, whereas AMP, adenosine, adenosine diphosphoribose, NAD+, cAMP, or sodium phosphate did not show this stimulation of proteolysis. ATP, [alpha, beta-methylene]ATP, [beta, gamma-methylene]ATP, and pyrophosphate all stimulated proteolysis, suggesting that a pyrophosphate linkage was necessary for this process. Thus, resting human lymphocytes contain a trypsin-like protease that is stimulated by nucleotides or pyrophosphate to selectively degrade histone H1.     

Cell cycle regulation by glucosamine in human pulmonary epithelial cells

Airway epithelial cells play an important role against intruding pathogens. Glucosamine, a commonly used supplemental compound, has recently begun to be regarded as a potential anti-inflammatory molecule. This study aimed to uncover how glucosamine impacts on cellular proliferation in human alveolar epithelial cells (A549) and bronchial epithelial cells (HBECs). With trypan blue-exclusion assay, we observed that glucosamine (10, 20, 50 mM) caused a decrease in cell number at 24 and 48 h; with a flow cytometric analysis, we also noted an enhanced cell accumulation within the G₀/G₁ phase at 24 h and induction of late apoptosis at 24 and 48 h by glucosamine (10, 20, 50 mM) in A549 cells and HBECs. Examination of phosphorylation in retinoblastoma (Rb) protein, we found an inhibitory effect by glucosamine at 20 and 50 mM. Glucosamine at 50 mM was demonstrated to elevate both the mRNA and protein expression of p53 and heme oxygenase-1 (HO-1), but also caused a reduction in p21 protein expression. In addition, glucosamine attenuated p21 protein stability via the proteasomal proteolytic pathway, as well as inducing p21 nuclear accumulation. Altogether, our results suggest that a high dose of glucosamine may inhibit cell proliferation through apoptosis and disturb cell cycle progression with a halt at G₀/G₁ phase, and that this occurs, at least in part, by a reduction in Rb phosphorylation together with modulation of p21, p53 and HO-1 expression, and nuclear p21 accumulation.     

Cell cycle restriction by histone H2AX limits proliferation of adult neural stem cells

Adult neural stem cell proliferation is dynamic and has the potential for massive self-renewal yet undergoes limited cell division in vivo. Here, we report an epigenetic mechanism regulating proliferation and self-renewal. The recruitment of the PI3K-related kinase signaling pathway and histone H2AX phosphorylation following GABA(A) receptor activation limits subventricular zone proliferation. As a result, NSC self-renewal and niche size is dynamic and can be directly modulated in both directions pharmacologically or by genetically targeting H2AX activation. Surprisingly, changes in proliferation have long-lasting consequences on stem cell numbers, niche size, and neuronal output. These results establish a mechanism that continuously limits proliferation and demonstrates its impact on adult neurogenesis. Such homeostatic suppression of NSC proliferation may contribute to the limited self-repair capacity of the damaged brain.     

Points of contact between histone H1 and the histone octamer.

The topography of the interaction between histone H1 and the histone octamer has been investigated. Bovine thymus nuclei or enzymatically fragmented chromatin were treated 1-ethyl-3(3-dimethylaminopropyl)carbodiimide, which catalyzes the formation of covalent bonds between residues of proteins in electrostatic contact. Histone H1-core histone dimers were identified and the segments of molecules participating in crosslinking were elucidated. The results demonstrate that the major histone H1-core histone dimer generated upon carbodiimide crosslinking of intact nuclei, chromatin, or mononucleosomes consists of the segment of histone H1 containing amino acids 74-106 crosslinked to the segment of histone H2A containing amino acids 58-129. Thus, the central globular region of histone H1 intimately contacts the histone octamer. Besides histone H1-H2 dimers, two other histone H1-containing crosslinked products were detected. In these instances, the segments of histone H1 molecules containing amino acids 1-72 were shown to participate in crosslinking. The histone H1 contact points defined here all occur within mononucleosomes and not between nucleosomes. These results permit the formulation of a testable model for the arrangement of histone H1 along polynucleosome chains.     

Species-specific suppression of histone H1 and H2B production in human/mouse hybrids.

Ten human/mouse hybrid cell lines that segregate either human or mouse chromosomes were examined for the expression of human- and mouse-specific histones H1 and H2B. Results of this study indicate that the human and mouse chromosomes in hybrid cells that segregate human chromosomes (M greater than H hybrids) contain only mouse histone H1 and H2B. Chromosomes in hybrid cells that segregate mouse chromosomes (H greater than M hybrids) contain only human H1 and H2B histones. Loss of the ability to produce either human or mouse histones does not seem to be due to the loss of specific human or mouse chromosomes because M greater than H hybrids retaining at least one copy of each human chromosome contain only mouse H1 and H2B and H greater than M hybrids retaining at least one copy of each mouse chromosome contain only human H1 and H2B histones. These results, together with those concerning histone H4 acetylation levels and ratios of variants of histones H3 and H2A that are like those in the dominant parent cell type, indicate that the control mechanisms affecting H1 and H2B expression in H greater than M and in M greater than H hybrid cells affect expression of histones H2A, H3, and H4 genes as well. The present data thus support the hypothesis that none of the histone genes that are active in the recessive parent cell type is expressed in hybrid lines that segregate recessive cell chromosomes.     

Structure of histone H1-DNA complex: Effect of histone H1 on DNA condensation

Large doughnut-shaped complexes were formed when histone H1 was mixed with DNA in amounts that extensively neutralized it. The doughnut shape is the most prevalent from observed by electron microscopy for linear double-stranded DNA independent of the molecular weight of the DNA in the range 1.2 x 10(6) to 25 x 10(6) at an H1/DNA input weight ratio of 1.3, at ionic strength 0.17. Doughnuts were not observed for single-stranded DNA-H1 complexes; instead, the complexes were globular. The circumference of the doughnutshaped particles indicates that much of the rigidity of duplex DNA in the complex has remained. Evidently, the condensation of the nucleohistone is constrained by the rigidity of duplex DNA and, under this constraint, surface contact with water is minimized by adopting a doughnut shape. Histone H5 causes a type of DNA condensation similar to that of H1 at comparable charge ratios. Core histones H2A-H2b, H3, and H4 complex with DNA to form globular aggregates of such small diameter that the duplex DNA in them must be much more tightly folded than is the case with the doughnut-shaped complexes. Because these histones are designed to fold DNA into nucleosomes 100 A wide, they must destroy the rigidity of free duplex DNA, perhaps by forming kinks in the chain.     

Cell cycle regulation during early mouse embryogenesis

Elaboration of a multicellular organism requires highly efficient coordination between proliferation and developmental processes. Accordingly, the embryonic cell cycle exhibits a high degree of plasticity; however, the mechanisms underlying its regulation in vivo remain largely unknown. The purpose of this review is to summarize the data on cell cycle regulation during the early mouse embryonic development, a period characterized by major variations in cell cycle parameters which correlate with important developmental transitions. In particular, we analyse the contribution of mutant mice to the study of in vivo cell cycle regulation during early development and discuss possible contributions of cell cycle regulators to developmental programs.     

mRNA levels of the differentiation-associated linker histone variant H1 zero in mitotically active and postmitotic senescent human diploid fibroblast cell populations

The mRNA levels of the linker histone variant H1o, which is tightly associated with differentiation, have been studied in the present investigation in an in vitro model ageing human diploid fibroblast (HDF) cell system as a function of cumulative population doublings (CPDs) in mitotically active and senescent cell populations. According to our previous findings the synthesis rate of the H1o protein does not change as a function of CPDs as long as the cells are proliferating. However, when cells reach senescence, the synthesis rate of H1o increases in both naturally aged as well as in cell populations artificially aged by treatment with sodium butyrate. In the present investigation, it is shown that the H1o mRNA levels remain relatively constant in mitotic cells with a slight decrease in cell cultures of late CPDs, i.e. in populations which still retain a mitotic potential, but are toward the end of their proliferative lifespan. However, when cells senesce and are no longer capable of synthesizing DNA, the H1o mRNA levels increase in naturally aged cells while artificially aged cells still maintain mRNA levels comparable to those of mitotic cells.     

Coordinate replication of members of the multigene family of core and H1 human histone genes.

Cells of the K562 human erythroleukemia cell line were obtained in different stages of the cell cycle by centrifugal elutriation. The cells had been previously labeled for 2 hr with BrdUrd so that BrdUrd-DNA synthesized during four different selected intervals of the S phase could be isolated. This DNA was used to determine the temporal replication during S phase of EcoRI segments containing histone genes. Cloned human genomic segments containing the core histone genes (H2A, H2B, H3, and H4), H2A and H2B pseudogenes, and the H1 gene were prepared. The genomic inserts were excised from these plasmids, nick-translated, and used as hybridization probes. The results with different probes compared on the same and on independently prepared DBM-paper transfers indicate that all of these histone genes replicate during the first half of the S phase. These genes were not among the earliest to replicate in the K562 cell line. Similar studies were carried out with HeLa cells in which EcoRI segments containing the H4 histone and H2A and H2B pseudogenes were found to replicate during the first half of the S phase. These histone genes replicate during the interval of the S phase when histone mRNA appears in the cytoplasm at the maximal rate. The possible relationship between these events is discussed.     

Cell cycle regulation to repair the infarcted myocardium

Lower vertebrates such as newt and zebrafish are able to reactivate high levels of cardiomyocyte cell cycle activity in response to experimental injury resulting in apparent regeneration. In contrast, damaged myocardium is replaced by fibrotic scar tissue in higher vertebrates. This process compromises the contractile function of the surviving myocardium, ultimately leading to heart failure. Various strategies are being pursued to augment myocyte number in the diseased hearts. One approach entails the reactivation of cell cycle in surviving cardiomyocytes. Here, we provide a summary of methods to monitor cell cycle activity, and interventions demonstrating positive cell cycle effects in cardiomyocytes as well as discuss the potential utility of cell cycle regulation to augment myocyte number in diseased hearts.