We describe a new minichromosome maintenance factor, Mcm10, and show that this essential protein is involved in the initiation of DNA replication in Saccharomyces cerevisiae. The mcm10 mutant has an autonomously replicating sequence-specific minichromosome maintenance defect and arrests at the nonpermissive temperature with dumbbell morphology and 2C DNA content. Mcm10 is a nuclear protein that physically interacts with several members of the MCM2-7 family of DNA replication initiation factors. Cloning and sequencing of the MCM10 gene show that it is identical to DNA43, a gene identified independently for its putative role in replicating DNA. Two-dimensional DNA gel analysis reveals that the mcm10-1 lesion causes a dramatic reduction in DNA replication initiation at chromosomal origins, including ORI1 and ORI121. Interestingly, the mcm10-1 lesion also causes replication forks to pause during elongation through these same loci. This novel phenotype suggests a unique role for the Mcm10 protein in the initiation of DNA synthesis at replication origins.DNA replication is a fundamental process of all dividing cells. During the eukaryotic cell cycle, DNA replication occurs exactly once and is initiated only upon the completion of mitosis. Strict regulation of timing appears to be mediated through the coordinated activities of numerous proteins. Due in large part to studies of viral DNA replication, the enzymatic activities at the replication fork were elucidated many years ago (33). In contrast, trans-acting factors which regulate the initiation of DNA replication have been described only recently. In an effort to gain a comprehensive understanding of the factors involved in this essential process, we have sought to identify gene products that influence the initiation of DNA replication.Saccharomyces cerevisiae provides an excellent eukaryotic model for identifying proteins involved in DNA replication. Many replication initiation factors currently under investigation are conserved in mammalian cells and were found initially in yeast. Members of the origin recognition complex (ORC) (20,22) were originally identified biochemically through their binding to the consensus sequence of autonomously replicating sequences (ARSs), which function as DNA replication origins (2). Our screen for yeast minichromosome maintenance (mcm) mutants (39) has also been fruitful in identifying replication initiation factors, such as those of the MCM2-7 family (9, 29, 52). The MCM2-7 proteins are a family of six conserved proteins that are ubiquitous in eukaryotes. Their essential role in the initiation of DNA synthesis not only has been demonstrated by in vivo studies in a number of organisms, including S. cerevisiae (55), Schizosaccharomyces pombe (40), and Drosophila melanogaster (51), but also is supported by in vitro studies in Xenopus laevis (8,34,38). The MCM2-7 proteins interact with one another, and possibly other proteins, to form large complexes (35). Despite their structural similarity, each of these proteins is indispensable for ...
SummaryVitamin A serves as a prohormone from which three classes of active metabolites are derived: the aldehydes, the carboxylic acids, and the retro-retinoids. Although these three classes are united under the rubric of signal transduction, they act by different molecular mechanisms: the 11-cis-refinaldehydes combine with opsin to form the universal visual pigments and the retinoic acids form ligands for transcription factors, whereas the retro-retinoids, as shown here, intersect with signal transduction at a cytoplasmic or membrane site. The retro-retinoid, anhydroretinol (AR), has long been known to act as a growth inhibitor in lymphocytes, whereas 14-hydroxy-4,14-retro-retinol (14-HRR) is required for normal lymphocyte proliferation. A mutually reversible relationship exists between these two retro-retinoids as one can reverse the effects of the other when given in pharmacological doses. The common explanation for reversible inhibition is competition for a shared receptor. We now provide evidence that when AR is given to T cells unmitigated by 14-HRR, rapid cell death can occur. The circumstances are closely related to nonclassical forms of apoptosis: within 2 h of AR administration the T cells undergo widespread morphological changes, notably surface blebbing and ballooning and, inevitably, bursting. In contrast, nuclear changes are comparatively mild, as indicated by absence of chromatin condensation and overt DNA cleavage to discrete nucleosomal fragments, although DNA nicks are readily discernible by terminal deoxynucleotidyl transferase assay. What further distinguishes the AR-induced form of apoptosis from classical ones is a lack of requirements of messenger RNA and protein synthesis, suggesting that the events leading to cell death are primarily initiated and play themselves out in the cytoplasm. This view is further reinforced by the finding that herbimycin A can prevent the onset of programmed cell death. The importance of our findings is that they strongly suggest a second messenger role for vitamin A metabolites in the cytoplasmic realm that has not been seen previously. These findings are entirely compatible with a general notion that in a cell requiring multiple coordinated signals for survival, the provision of an unbalanced signal can initiate programmed cell death. Collectively, our data also challenge the paradigm that retinoids (outside vision) solely mediate their function via the steroid/retinoic acid receptor family of nuclear transcription factors. Instead, a mode of action in the cytoplasmic realm akin to one attributed to other small lipophilic second messenger molecules, such as diacyl glycerol or ceramide, may apply to retro-retinoids.
The G protein-coupled receptor (GPCR) cysteinyl-leukotriene receptor 2 (CysLTR2) with a single amino acid mutation at position 3.43 (Leu replaced with Gln at position 129 in transmembrane helix 3) causes uveal melanoma in humans. The ability of CysLTR2-L129Q to cause malignant transformation has been hypothesized to result from constitutive activity. We show that CysLTR2-L129Q is a constitutively active mutant (CAM) that strongly drives Gq/11 signaling pathways in melan-a melanocytes and in HEK293T cells in culture. However, the mutant receptor only very weakly recruits beta-arrestins 1 and 2. The mutant receptor displays profound signaling bias while avoiding arrestin-mediated downregulation. The mechanism of the signaling bias results from the creation of a hydrogen-bond network that stabilizes the active G protein signaling state through novel interactions with the highly-conserved NPxxY motif on helix 7. Furthermore, the mutation destabilizes a putative allosteric sodium-binding site that usually stabilizes the inactive state of GPCRs. Thus, the mutation has a dual role of promoting the active state while destabilizing inactivating allosteric networks. The high degree of constitutive activity renders existing orthosteric antagonist ligands of CysLTR2 ineffective as inverse agonists of the mutant. CysLTR2 is the first example of a GPCR oncogene that encodes a GPCR with constitutive highly biased signaling that can escape cellular downregulation mechanisms.
The purinergic transmitter ATP (adenosine 5'-triphosphate) plays an essential role in both the central and peripheral nervous systems, and the ability to directly measure extracellular ATP in real time will increase our understanding of its physiological functions. We developed an ultrasensitive GPCR Activation‒Based ATP sensor called GRABATP1.0, with a robust fluorescence response to extracellular ATP when expressed in several cell types. This sensor has sub-second kinetics, ATP affinity in the range of tens of nanomolar, and can be used to localize ATP release with subcellular resolution. Using this sensor, we monitored ATP release under a variety of in vitro and in vivo conditions, including primary hippocampal neurons, a zebrafish model of injury-induced ATP release, and LPS-induced ATP-release events in individual astrocytes in the mouse cortex measured using in vivo two-photon imaging. Thus, the GRABATP1.0 sensor is a sensitive, versatile tool for monitoring ATP release and dynamics under both physiological and pathophysiological conditions.
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