An impaired RNA polymerase II activity in Saccharomyces cerevisiae causes cell-cycle inhibition at START

Coupling Between Cell Cycle Progression and the Nuclear RNA Polymerases System

Eukaryotic life is possible due to the multitude of complex and precise phenomena that take place in the cell. Essential processes like gene transcription, mRNA translation, cell growth, and proliferation, or membrane traffic, among many others, are strictly regulated to ensure functional success. Such systems or vital processes do not work and adjusts independently of each other. It is required to ensure coordination among them which requires communication, or crosstalk, between their different elements through the establishment of complex regulatory networks. Distortion of this coordination affects, not only the specific processes involved, but also the whole cell fate. However, the connection between some systems and cell fate, is not yet very well understood and opens lots of interesting questions. In this review, we focus on the coordination between the function of the three nuclear RNA polymerases and cell cycle progression. Although we mainly focus on the model organism Saccharomyces cerevisiae, different aspects and similarities in higher eukaryotes are also addressed. We will first focus on how the different phases of the cell cycle affect the RNA polymerases activity and then how RNA polymerases status impacts on cell cycle. A good example of how RNA polymerases functions impact on cell cycle is the ribosome biogenesis process, which needs the coordinated and balanced production of mRNAs and rRNAs synthesized by the three eukaryotic RNA polymerases. Distortions of this balance generates ribosome biogenesis alterations that can impact cell cycle progression. We also pay attention to those cases where specific cell cycle defects generate in response to repressed synthesis of ribosomal proteins or RNA polymerases assembly defects.

Coupling of RNA polymerase III assembly to cell cycle progression in Saccharomyces cerevisiae

Assembly of the RNA polymerases in both yeast and humans is proposed to occur in the cytoplasm prior to their nuclear import. Our previous studies identified a cold-sensitive mutation, rpc128-1007, in the yeast gene encoding the second largest Pol III subunit, Rpc128. rpc128-1007 is associated with defective assembly of Pol III complex and, in consequence, decreased level of tRNA synthesis. Here, we show that rpc128-1007 mutant cells remain largely unbudded and larger than wild type cells. Flow cytometry revealed that most rpc128-1007 mutant cells have G1 DNA content, suggesting that this mutation causes pronounced cell cycle delay in the G1 phase. Increased expression of gene encoding Rbs1, the Pol III assembly/import factor, could counteract G1 arrest observed in the rpc128-1007 mutant and restore wild type morphology of mutant cells. Concomitantly, cells lacking Rbs1 show a mild delay in G1 phase exit, indicating that Rbs1 is required for timely cell cycle progression. Using the double rpc128-1007 maf1Δ mutant in which tRNA synthesis is recovered, we confirmed that the Pol III assembly defect associated with rpc128-1007 is a primary cause of cell cycle arrest. Together our results indicate that impairment of Pol III complex assembly is coupled to cell cycle inhibition in the G1 phase.

Yeast homolog of a cancer-testis antigen defines a new transcription complex

We have isolated a new yeast gene (PCC1) that codes for a factor homologous to human cancer-testis antigens. We provide evidence that Pcc1p is a new transcription factor and that its mutation affects expression of several genes, some of which are involved in cell cycle progression and polarized growth. Mutation of Pcc1p also affects the expression of GAL genes by impairing the recruitment of the SAGA and Mediator co-activators. We characterize a new complex that contains Pcc1p, a kinase, Bud32p, a putative endopeptidase, Kae1p and two additional proteins encoded by ORFs YJL184w and YMLO36w. Genetic and physical interactions among these proteins strongly suggest that this complex is a functional unit. Chromatin immunoprecipitation experiments and multiple genetic interactions of pcc1 mutants with mutants of the transcription apparatus and chromatin modifying enzymes underscore the direct role of the complex in transcription. Functional complementation experiments indicate that the transcriptional function of this set of genes is conserved throughout evolution.

Structural perspective on mutations affecting the function of multisubunit RNA polymerases

High-resolution crystallographic structures of multisubunit RNA polymerases (RNAPs) have increased our understanding of transcriptional mechanisms. Based on a thorough review of the literature, we have compiled the mutations affecting the function of multisubunit RNA polymerases, many of which having been generated and studied prior to the publication of the first high-resolution structure, and highlighted the positions of the altered amino acids in the structures of both the prokaryotic and eukaryotic enzymes. The observations support many previous hypotheses on the transcriptional process, including the implication of the bridge helix and the trigger loop in the processivity of RNAP, the importance of contacts between the RNAP jaw-lobe module and the downstream DNA in the establishment of a transcription bubble and selection of the transcription start site, the destabilizing effects of ppGpp on the open promoter complex, and the link between RNAP processivity and termination. This study also revealed novel, remarkable features of the RNA polymerase catalytic mechanisms that will require additional investigation, including the putative roles of fork loop 2 in the establishment of a transcription bubble, the trigger loop in start site selection, and the uncharacterized funnel domain in RNAP processivity.

The FACT chromatin modulator: genetic and structure/function relationships

The chromatin configuration of DNA inhibits access by enzymes such as RNA polymerase II. This inhibition is alleviated by FACT, a conserved transcription elongation factor that has been found to reconfigure nucleosomes to allow transit along the DNA by RNA polymerase II, thus facilitating transcription. FACT also reorganizes nucleosomes after the passage of RNA polymerase II, as indicated by the effects of certain FACT mutations. The larger of the two subunits of FACT is Spt16/Cdc68, while the smaller is termed SSRP1 (vertebrates) or Pob3 (budding yeast). The HMG-box domain at the C terminus of SSRP1 is absent from Pob3; the function of this domain for yeast FACT is supplied by the small HMG-box protein Nhp6. In yeast, this "detachable" HMG domain is a general chromatin component, unlike FACT, which is found only in transcribed regions and associated with RNA polymerase II. The several domains of the larger FACT subunit are also likely to have different functions. Genetic studies suggest that FACT mediates nucleosome reorganization along several pathways, and reinforce the notion that protein unfolding and (or) refolding is involved in FACT activity for transcription.

Saccharomyces cerevisiae RNA polymerase II is affected by Kluyveromyces lactis zymocin

The G(1) arrest imposed by Kluyveromyces lactis zymocin on Saccharomyces cerevisiae cells requires a functional RNA polymerase II (pol II) Elongator complex. In studying a link between zymocin and pol II, progressively truncating the carboxyl-terminal domain (CTD) of pol II was found to result in zymocin hypersensitivity as did mutations in four different CTD kinase genes. Consistent with the notion that Elongator preferentially associates with hyperphosphorylated (II0) rather than hypophosphorylated (IIA) pol II, the II0/IIA ratio was imbalanced toward II0 on zymocin treatment and suggests zymocin affects pol II function, presumably in an Elongator-dependent manner. As judged from chromatin immunoprecipitations, zymocin-arrested cells were affected with regards to pol II binding to the ADH1 promotor and pol II transcription of the ADH1 gene. Thus, zymocin may interfere with pol II recycling, a scenario assumed to lead to down-regulation of pol II transcription and eventually causing the observed G(1) arrest.

Using Bayesian networks to analyze expression data

DNA hybridization arrays simultaneously measure the expression level for thousands of genes. These measurements provide a "snapshot" of transcription levels within the cell. A major challenge in computational biology is to uncover, from such measurements, gene/protein interactions and key biological features of cellular systems. In this paper, we propose a new framework for discovering interactions between genes based on multiple expression measurements. This framework builds on the use of Bayesian networks for representing statistical dependencies. A Bayesian network is a graph-based model of joint multivariate probability distributions that captures properties of conditional independence between variables. Such models are attractive for their ability to describe complex stochastic processes and because they provide a clear methodology for learning from (noisy) observations. We start by showing how Bayesian networks can describe interactions between genes. We then describe a method for recovering gene interactions from microarray data using tools for learning Bayesian networks. Finally, we demonstrate this method on the S. cerevisiae cell-cycle measurements of Spellman et al. (1998).

The CLN gene family: central regulators of cell cycle Start in budding yeast

The Start transition in the budding yeast cell cycle is the point of most physiological regulation of cell cycle commitment. This transition is controlled by the CLN1,2,3 gene family. We review what is known about the regulation, inter-regulation and function of these genes in controlling the Start transition.

Starting the cell cycle: what's the point?

Early work on regulation of the budding yeast cell cycle defined a critical regulatory step called 'Start', considered to represent cell cycle commitment. Recent work has defined the probable molecular basis of Start to be activation of Cln-Cdc28 protein kinase complexes. Cln-Cdc28 kinases may directly regulate many cell cycle processes, including some classically considered to be 'post-Start'. Specialization of function among the three genetically redundant CLN genes is becoming apparent.

Synthetic lethality of sep1 (xrn1) ski2 and sep1 (xrn1) ski3 mutants of Saccharomyces cerevisiae is independent of killer virus and suggests a general role for these genes in translation control

Strand exchange protein 1 (Sep1) (also referred to as exoribonuclease I [Xrn1]) from Saccharomyces cerevisiae has been implicated in DNA recombination, RNA turnover, karyogamy, and G4 DNA pairing among other disparate cellular processes. Using a genetic approach to study the role of SEP1/XRN1 in mitotic yeast cells, we identified mutations in the genes superkiller 2 (SKI2) and superkiller 3 (SKI3) as synthetically lethal with an sep1 null mutation. The SKI genes are thought to comprise an intracellular antiviral system controlling the expression of killer toxin from double-stranded RNA virus found in many yeast strains. However, the lethality of sep1 ski2 and sep1 ski3 mutants was independent of the L-A and M viruses, suggesting that the SKI genes act in a general cellular process in addition to virus control. We propose that Sep1/Xrn1 and Ski2 both act to block translation on transcripts targeted for degradation. Using a temperature-sensitive allele of SEP1/XRN1, we show that double mutants display a synthetic cell cycle arrest in late G1 at Start.

Mutations sensitizing yeast cells to the start inhibitor nalidixic acid

The regulatory step Start in the cell cycle of the budding yeast Saccharomyces cerevisiae is inhibited by nalidixic acid (Nal). To study this inhibition, mutations were identified that alter the sensitivity of yeast cells to Nal. Nal-sensitive mutations were sought because the inhibitory effects of Nal on wild-type cells are only transient, and wild-type cells naturally become refractory to Nal. Three complementation groups of Nal-sensitive mutations were found. Mutations in the first complementation group were shown to reside in the ARO7 gene, encoding chorismate mutase; tyrosine and phenylalanine synthesis was inhibited by Nal in these aro7 mutants, whereas wild-type chorismate mutase was unaffected, These aro7 alleles demonstrate 'recruitment', by mutation, of an innately indifferent protein to an inhibitor-sensitive form. The Nal-sensitive aro7 mutant cells were used to show that the resumption of Nal-inhibited nuclear activity and cell proliferation takes place while cytoplasmic Nal persists at concentrations inhibitory for the mutant chorismate mutase. Mutations in the second complementation group, nss2 (Nal-supersensitive), increased intracellular Nal concentrations, and may simply alter the permeability of cells to Nal. The third complementation group was found to be the ERG6 gene, previously suggested to encode the ergosterol biosynthetic enzyme sterol methyltransferase. Mutation or deletion of the ERG6 gene had little effect on the inhibition of Start by Nal, but prevented recovery from this inhibition. Mutation of ERG3, encoding another ergosterol biosynthetic enzyme, also caused Nal sensitivity, suggesting that plasma membrane sterol composition, and plasma membrane function, mediates recovery from Nal-mediated inhibition of Start.