Modulation of urokinase plasminogen activator gene expression during the transition from quiescent to proliferative state in normal mouse cells.

We have investigated the regulation of urokinase (u-PA) mRNA in quiescent mouse fibroblasts and keratinocytes stimulated to divide by the addition of serum or epidermal growth factor (EGF), respectively. Serum stimulation of quiescent fibroblasts (BALB/c 3T3 or Swiss 3T3) results in an early and transient increase of u-PA mRNA level, which precedes by several hours the onset of DNA synthesis. A similar response is elicited by EGF stimulation of quiescent keratinocytes. The increase of u-PA mRNA parallels that of c-myc mRNA, does not require protein synthesis and is at least in part due to increase in template activity of the u-PA gene. Induction of terminal differentiation of mouse keratinocytes results in a decrease of u-PA mRNA which parallels the decrease of thymidine incorporation. In conclusion, variation in the level of u-PA mRNA is seen during G0/G1 transition and correlates with the proliferative state of these normal mouse cells.     

Changes in RNA metabolism and accumulation of presumptive messenger RNA during transition from the growing to the quiescent state of cultured mouse fibroblasts.

Mouse fibroblasts maintained in tissue culture regulate total protein and ribosomal RNA synthesis co-ordinately with changes in the cellular growth state. Here we show that changes in the rate of synthesis of nuclear non-polyadenylic acid-containing RNA and the rate of accumulation and breakdown of cytoplasmic ribosomal RNA also accompany the transition from the resting to the growing cellular growth state, while the rate of synthesis of nuclear poly (A)-containing RNA and the rates of accumulation and breakdown of cytoplasmic poly(A) containing RNA (presumptive messenger RNA) are, however, only marginally changed. The small net increase (20% to 30%) in the amount of presumptive mRNA is considerably less than the observed increase in protein synthesis (two to threefold) during this transition. We also isolated and characterized extra-polysomal poly(A)-containing ribonucleoprotein particles from quiescent cultures that were similar to those particles obtained by treatment of polyribosomes with EDTA. These experiments suggest that the early increase in protein synthetic activity when quiescent, cultured cells are induced to grow is partially caused by an increased attachment of pre-existing mRNA molecules to free ribosomes.     

Changes in heparan sulfate structure during transition from the proliferating to the non-dividing state of cultured arterial smooth muscle cells

Cultured arterial smooth muscle cells synthesize a cell-associated heparan sulfate proteoglycan which consists of a 92 kDa core protein with 3 to 4 heparan sulfate side chains covalently attached. Biosynthesis of the cell-associated heparan sulfate proteoglycan was compared in proliferating and in non-dividing vascular smooth muscle cells which are preincubated in the presence of [35]sulfate or a combination of [35S]methionine and [3H]glucosamine. The Mr of the core protein was identical in either growth state, but changes in the structure of the heparan sulfate side chains were observed. Non-dividing (postconfluent) arterial smooth muscle cells form longer heparan sulfate chains with a higher proportion of hydrophobic (N-acetyl) groups than proliferating (preconfluent) cells as judged from gel filtration experiments, hydrophobic interaction chromatography and heparitinase degradation. An enzyme preparation from proliferating cells catalyzes deacetylation and N-sulfation of heparan sulfate at a 5-fold higher activity than from non-dividing cells. Cell density-dependent structural differences of heparan sulfate are related to the finding that heparan sulfate isolated from non-dividing cells has a 10-fold higher antiproliferative potency than heparan sulfate from proliferating (preconfluent) cells.     

Biochemical investigations of the nuclear proteins during the transition of root meristems from quiescent to proliferating state in Pisum sativum

Abstract

The electrophoretic analysis of nuclear proteins extracted from root meristems at different times of germination puts in evidence the variations of content of specific proteins. Several nuclear proteins are phosphorylated by endogenous protein kinase and often the maximum rate of phosphorylation it has been observed in proteins present in the nucleus at low concentrations. Moreover also the phosphorylation rate of specific proteins changes at different times of germination. It is interesting the fact that both variations of concentration and phosphorylation in nuclear proteins occurr at the time when root meristems leave the quiescence to enter a proliferating state. We suggest that these variations play a role in this physiological event.     

Developmentally regulated chromosome fragmentation linked to imprecise elimination of repeated sequences in paramecia

The chromosomes of ciliates are fragmented at reproducible sites during the development of the polyploid somatic macronucleus, but the mechanisms involved appear to be quite diverse in different species. In Paramecium aurelia, the process is imprecise and results in de novo telomere addition at locally heterogeneous positions. To search for possible determinants of chromosome fragmentation, we have studied an ~21-kb fragmentation region from the germ line genome of P. primaurelia. The mapping and sequencing of alternative macronuclear versions of the region show that two distinct multicopy elements, a minisatellite and a degenerate transposon copy, are eliminated by an imprecise mechanism leading either to chromosome fragmentation and the formation of new telomeres or to the rejoining of flanking sequences. Heterogeneous internal deletions occur between short direct repeats containing TA dinucleotides. The complex rearrangement patterns produced vary slightly among genetically identical cell lines, show non-Mendelian inheritance during sexual reproduction, and can be experimentally modified by transformation of the maternal macronucleus with homologous sequences. These results suggest that chromosome fragmentation in Paramecium is the consequence of imprecise DNA elimination events that are distinct from the precise excision of single-copy internal eliminated sequences and that target multicopy germ line sequences by homology-dependent epigenetic mechanisms.     

Activation of quiescent infections by postharvest pathogens during transition from the biotrophic to the necrotrophic stage

The evolution of bacterial pathogens from nonpathogenic ancestors is marked principally by the acquisition of virulence gene clusters on plasmids and pathogenicity islands via horizontal gene transfer. The flip side of this evolutionary force is the equally important adaptation of the newly minted pathogen to its new host niche. Pathoadaptive mutations take the form of modification of gene expression such that the pathogen is better fit to survive within the new niche. This mini-review describes the concept of pathoadaptation by loss of gene function. In this process, genes that are no longer compatible with the novel lifestyle of the pathogen are selectively inactivated either by point mutation, insertion, or deletion. These genes are called 'antivirulence genes'. Selective pressure sometimes leads to the deletion of large regions of the genome that contain antivirulence genes generating 'black holes' in the pathogen genome. Inactivation of antivirulence genes leads to a pathogen that is highly adapted to its host niche. Identification of antivirulence genes for a particular pathogen can lead to a better understanding of how it became a pathogen and the types of genetic traits that need to be silenced in order for the pathogen to colonize its new host niche successfully.     

Generation of H2O2 is regulated by cytoplasmic free calcium in cultured porcine thyroid cells

Effects of calcium ionophore A23187 and BAY-K-8644, a calcium channel agonist, on cytoplasmic free calcium ([Ca2+]i) and H2O2 generation were studied in cultured porcine thyroid cells. We monitored continuously the effects of A23187 and BAY-K-8644 on [Ca2+]i and H2O2 generation, using the intracellularly trapped fluorescent Ca2+ indicator, fura-2, and homovanillic acid, respectively. A23187 and BAY-K-8644 induce an immediate increase in [Ca2+]i and H2O2 generation. The A23187- and BAY-K-8644-induced [Ca2+]i responses and H2O2 generation occur immediately, reach a maximum within several seconds, and then slowly decline. The minimum doses of A23187 or BAY-K-8644 to increase [Ca2+]i stimulate H2O2 generation. H2O2 generation is regulated by [Ca2+]i.     

The slow S to M fluorescence rise in cyanobacteria is due to a state 2 to state 1 transition

In dark-adapted plants and algae, chlorophyll a fluorescence induction peaks within 1s after irradiation due to well documented photochemical and non-photochemical processes. Here we show that the much slower fluorescence rise in cyanobacteria (the so-called "S to M rise" in tens of seconds) is due to state 2 to state 1 transition. This has been demonstrated in particular for Synechocystis PCC6803, using its RpaC(-) mutant (locked in state 1) and its wild-type cells kept in hyperosmotic suspension (locked in state 2). In both cases, the inhibition of state changes correlates with the disappearance of the S to M fluorescence rise, confirming its assignment to the state 2 to state 1 transition. The general physiological relevance of the SM rise is supported by its occurrence in several cyanobacterial strains: Synechococcus (PCC 7942, WH 5701) and diazotrophic single cell cyanobacterium (Cyanothece sp. ATCC 51142). We also show here that the SM fluorescence rise, and also the state transition changes are less prominent in filamentous diazotrophic cyanobacterium Nostoc sp. (PCC 7120) and absent in phycobilisome-less cyanobacterium Prochlorococcus marinus PCC 9511. Surprisingly, it is also absent in the phycobiliprotein rod containing Acaryochloris marina (MBIC 11017). All these results show that the S to M fluorescence rise reflects state 2 to state 1 transition in cyanobacteria with phycobilisomes formed by rods and core parts. We show that the pronounced SM fluorescence rise may reflect a protective mechanism for excess energy dissipation in those cyanobacteria (e.g. in Synechococcus PCC 7942) that are less efficient in other protective mechanisms, such as blue light induced non-photochemical quenching. This article is part of a Special Issue entitled: Photosynthesis Research for Sustainability: from Natural to Artificial.     

The anaphase-promoting complex is required in both dividing and quiescent cells during zebrafish development

The anaphase-promoting complex/cyclosome (APC/C) regulates multiple stages of the cell cycle, most prominently mitosis. We describe zebrafish with mutations in two APC/C subunits, Cdc16 and Cdc26, whose phenotypes reveal a multifaceted set of defects resulting from the gradual depletion of the APC/C. First, loss of the APC/C in dividing cells results in mitotic arrest, followed by apoptosis. This defect becomes detectable in different organs at different larval ages, because the subunits of the APC/C are maternally deposited, are unusually stable, and are depleted at uneven rates in different tissues. Second, loss of the APC/C in quiescent or differentiated cells results in improper re-entry into the cell cycle, again in an apparently tissue-specific manner. This study is the first demonstration of both functions of the APC/C in a vertebrate organism and also provides an illustration of the surprisingly complex effects that essential, maternally supplied factors can have on the growing animal over a period of 10 days or longer.     

Uncoupling protein 3 transcription is regulated by peroxisome proliferator-activated receptor (alpha) in the adult rodent heart.

Relatively little is known concerning the regulation of uncoupling proteins (UCPs) in the heart. We investigated in the adult rodent heart 1) whether changes in workload, substrate supply, or cytokine (TNF-alpha) administration affect UCP-2 and UCP-3 expression, and 2) whether peroxisome proliferator-activated receptor alpha (PPARalpha) regulates the expression of either UCP-2 or UCP-3. Direct comparisons were made between cardiac and skeletal muscle. UCP-2, UCP-3, and PPARalpha expression were reduced when cardiac workload was either increased (pressure overload by aortic constriction) or decreased (mechanical unloading by heterotopic transplantation). Similar results were observed during cytokine administration. Reduced dietary fatty acid availability resulted in decreased expression of both cardiac UCP-2 and UCP-3. However, when fatty acid (the natural ligand for PPARalpha) supply was increased (high-fat feeding, fasting, and STZ-induced diabetes), cardiac UCP-3 but not UCP-2 expression increased. Comparable results were observed in rats treated with the specific PPARalpha agonist WY-14,643. The level of cardiac UCP-3 but not UCP-2 expression was severely reduced (20-fold) in PPARalpha-/- mice compared to wild-type mice. These results suggest that in the adult rodent heart, UCP-3 expression is regulated by PPARalpha. In contrast, cardiac UCP-2 expression is regulated in part by a fatty acid-dependent, PPARalpha-independent mechanism.