Your search keyword '"SX00 SystemsX.ch"' showing total 3 results

1. Regulating repression: roles for the sir4 N-terminus in linker DNA protection and stabilization of epigenetic states

Author

Susan M. Gasser, Ragna Sack, Chinyen Tsai, Mariano Oppikofer, Stephanie Kueng, Tim-Christoph Roloff, Monika Tsai-Pflugfelder, Helder Ferreira, Emma Roberts, University of St Andrews. School of Biology, University of St Andrews. Biomedical Sciences Research Complex, and University of Zurich

Subjects

Cancer Research, Transcription, Genetic, Saccharomyces-cerevisiae telomeres, Epigenesis, Genetic, In-vitro, Transcriptional activation, SX00 SystemsX.ch, Gene Expression Regulation, Fungal, 1306 Cancer Research, Phosphorylation, Genetics (clinical), Silent Information Regulator Proteins, Saccharomyces cerevisiae, Histone deacetylation, Genetics, Telomere, Chromatin, Cyclin-Dependent Kinases, DNA-Binding Proteins, G2 Phase Cell Cycle Checkpoints, Yeast silent chromatin, Histone, SX03 CINA, Research Article, Transcriptional Activation, 2716 Genetics (clinical), Saccharomyces cerevisiae Proteins, lcsh:QH426-470, Saccharomyces cerevisiae, Mitosis, QH426 Genetics, Biology, DNA-binding protein, Drosophila embryos, 1311 Genetics, Cyclin-dependent kinase, 1312 Molecular Biology, Gene Silencing, QH426, Molecular Biology, Psychological repression, Ecology, Evolution, Behavior and Systematics, Phosphorylation sites, biology.organism_classification, Genes, Mating Type, Fungal, Cell-cycle, Mediated repression, Linker DNA, lcsh:Genetics, 1105 Ecology, Evolution, Behavior and Systematics, Epigenetic Repression, biology.protein, 570 Life sciences, biology, Mating-type loci

Abstract

Silent information regulator proteins Sir2, Sir3, and Sir4 form a heterotrimeric complex that represses transcription at subtelomeric regions and homothallic mating type (HM) loci in budding yeast. We have performed a detailed biochemical and genetic analysis of the largest Sir protein, Sir4. The N-terminal half of Sir4 is dispensable for SIR–mediated repression of HM loci in vivo, except in strains that lack Yku70 or have weak silencer elements. For HM silencing in these cells, the C-terminal domain (Sir4C, residues 747–1,358) must be complemented with an N-terminal domain (Sir4N; residues 1–270), expressed either independently or as a fusion with Sir4C. Nonetheless, recombinant Sir4C can form a complex with Sir2 and Sir3 in vitro, is catalytically active, and has sedimentation properties similar to a full-length Sir4-containing SIR complex. Sir4C-containing SIR complexes bind nucleosomal arrays and protect linker DNA from nucleolytic digestion, but less effectively than wild-type SIR complexes. Consistently, full-length Sir4 is required for the complete repression of subtelomeric genes. Supporting the notion that the Sir4 N-terminus is a regulatory domain, we find it extensively phosphorylated on cyclin-dependent kinase consensus sites, some being hyperphosphorylated during mitosis. Mutation of two major phosphoacceptor sites (S63 and S84) derepresses natural subtelomeric genes when combined with a serendipitous mutation (P2A), which alone can enhance the stability of either the repressed or active state. The triple mutation confers resistance to rapamycin-induced stress and a loss of subtelomeric repression. We conclude that the Sir4 N-terminus plays two roles in SIR–mediated silencing: it contributes to epigenetic repression by stabilizing the SIR–mediated protection of linker DNA; and, as a target of phosphorylation, it can destabilize silencing in a regulated manner., Author Summary Three Silent Information Regulator (SIR) proteins Sir2, Sir3, and Sir4 are involved in the epigenetic gene silencing of the homothallic mating (HM) loci and of telomere-proximal genes in budding yeast. They bind as a heterotrimeric complex to chromatin, repressing the underlying genes. Sir2 has an essential histone deacetylase activity, and Sir3 binds nucleosomes, with a high specificity for unmodified histones. We explored Sir4, whose role had largely remained a mystery. We report here that Sir4 N- and C-terminal domains have distinct functions: The Sir4 C-terminus binds all proteins essential for SIR–mediated silencing and is sufficient to repress HM loci, but surprisingly it is not sufficient to efficiently repress at telomeres. The Sir4 N-terminus binds DNA, which strengthens the SIR–chromatin interaction and helps target Sir4 to telomeric loci. In addition the Sir4 N-terminus binds sequence-specific factors that recruit Sir4 to sites of repression. We find that the Sir4 N-terminus is a target of mitotic phosphorylation. Mutation of the phosphoacceptor sites indicates that they help fine-tune subtelomeric repression. We propose therefore that phosphorylation of the Sir4 N-terminal domain modulates epigenetic repression at telomeres in response to cell cycle and/or stress situations.

Published

2011

2. Genome-Wide Analysis of SREBP1 Activity around the Clock Reveals Its Combined Dependency on Nutrient and Circadian Signals

Author

Felix Naef, Bart Deplancke, Laura Symul, Dmitry Kuznetsov, Aurélien Naldi, Winship Herr, Ioannis Xenarios, Nouria Hernandez, Federica Gilardi, Nicolas GUEX, Beatrice Desvergne, Guillaume Rey, CycliX Consortium, Hernandez, N., Delorenzi, M., Deplancke, B., Desvergne, B., Guex, N., Herr, W., Naef, F., Rougemont, J., Schibler, U., Andersin, T., Cousin, P., Gilardi, F., Gos, P., Martelot, G., Lammers, F., Canella, D., Raghav, S., Fabbretti, R., Fortier, A., Long, L., Vlegel, V., Xenarios, I., Migliavacca, E., Praz, V., David, F., Jarosz, Y., Kuznetsov, D., Liechti, R., Martin, O., Delafontaine, J., Sinclair, L., Cajan, J., Krier, I., Leleu, M., Molina, N., Naldi, A., Rey, G., Symul, L., Bernasconi, D., Baruchet, M., University of Zurich, and Guex, Nicolas

Subjects

2716 Genetics (clinical), Cancer Research, lcsh:QH426-470, SX20 Research, Technology and Development Projects, Circadian clock, CLOCK Proteins, Biology, Mice, SX00 SystemsX.ch, 1311 Genetics, Circadian Clocks, 1312 Molecular Biology, Genetics, Transcriptional regulation, Animals, Homeostasis, 1306 Cancer Research, Circadian rhythm, SX04 CycliX, Molecular Biology, Transcription factor, Genetics (clinical), Ecology, Evolution, Behavior and Systematics, Regulation of gene expression, Binding Sites, Genome, Lipid Metabolism, Bacterial circadian rhythms, Circadian Rhythm, Sterol regulatory element-binding protein, Cell biology, lcsh:Genetics, 1105 Ecology, Evolution, Behavior and Systematics, Gene Expression Regulation, Hepatocyte Nuclear Factor 4, 570 Life sciences, biology, Sterol Regulatory Element Binding Protein 1, Protein Binding, Research Article

Abstract

In mammals, the circadian clock allows them to anticipate and adapt physiology around the 24 hours. Conversely, metabolism and food consumption regulate the internal clock, pointing the existence of an intricate relationship between nutrient state and circadian homeostasis that is far from being understood. The Sterol Regulatory Element Binding Protein 1 (SREBP1) is a key regulator of lipid homeostasis. Hepatic SREBP1 function is influenced by the nutrient-response cycle, but also by the circadian machinery. To systematically understand how the interplay of circadian clock and nutrient-driven rhythm regulates SREBP1 activity, we evaluated the genome-wide binding of SREBP1 to its targets throughout the day in C57BL/6 mice. The recruitment of SREBP1 to the DNA showed a highly circadian behaviour, with a maximum during the fed status. However, the temporal expression of SREBP1 targets was not always synchronized with its binding pattern. In particular, different expression phases were observed for SREBP1 target genes depending on their function, suggesting the involvement of other transcription factors in their regulation. Binding sites for Hepatocyte Nuclear Factor 4 (HNF4) were specifically enriched in the close proximity of SREBP1 peaks of genes, whose expression was shifted by about 8 hours with respect to SREBP1 binding. Thus, the cross-talk between hepatic HNF4 and SREBP1 may underlie the expression timing of this subgroup of SREBP1 targets. Interestingly, the proper temporal expression profile of these genes was dramatically changed in Bmal1 −/− mice upon time-restricted feeding, for which a rhythmic, but slightly delayed, binding of SREBP1 was maintained. Collectively, our results show that besides the nutrient-driven regulation of SREBP1 nuclear translocation, a second layer of modulation of SREBP1 transcriptional activity, strongly dependent from the circadian clock, exists. This system allows us to fine tune the expression timing of SREBP1 target genes, thus helping to temporally separate the different physiological processes in which these genes are involved., Author Summary Circadian rhythmicity is part of our innate behavior and controls many physiological processes, such as sleeping and waking, activity, neurotransmitter production and a number of metabolic pathways. In mammals, the central circadian pacemaker in the hypothalamus is entrained on a daily basis by environmental cues (i.e. light), thus setting the period length and synchronizing the rhythms of all cells in the body. In the last decades, numerous investigations have highlighted the importance of the internal timekeeping mechanism for maintenance of organism health and longevity. Indeed, the reciprocal regulation of circadian clock and metabolism is now commonly accepted, although still poorly understood at the molecular level. Our global analysis of DNA binding along the day of Sterol Regulatory Element Binding Protein 1 (SREBP1), a key regulator of lipid biosynthesis, represents the first tool to comprehensively explore how its activity is connected to circadian-driven regulatory events. We show that the regulation of SREBP1 action by nutrients relies mainly on the control of its subcellular localization, while the circadian clock influences the promoter specific activity of SREBP1 within the nucleus. Furthermore, we identify the Hepatocyte Nuclear Factor 4 (HNF4) as a putative player in the cross-talk between molecular clock and metabolic regulation.

Published

2014

3. Recent Loss of Self-Incompatibility by Degradation of the Male Component in Allotetraploid Arabidopsis kamchatica

Author

Julien B. Bachelier, Takashi Tsuchimatsu, Pascal Kaiser, Chow-Lih Yew, Kentaro Shimizu, and University of Zurich

Subjects

Evolutionary Genetics, 0106 biological sciences, Cancer Research, Arabidopsis, 580 Plants (Botany), Plant Genetics, 01 natural sciences, 10126 Department of Plant and Microbial Biology, SX00 SystemsX.ch, Ploidy, Arabidopsis thaliana, 1306 Cancer Research, Genetics (clinical), Plant Proteins, Genetics, 0303 health sciences, biology, Self-Incompatibility in Flowering Plants, food and beverages, 590 Animals (Zoology), SX23 Interdisciplinary PhD Projects, Research Article, Signal Transduction, 2716 Genetics (clinical), lcsh:QH426-470, Outcrossing, 010603 evolutionary biology, 10127 Institute of Evolutionary Biology and Environmental Studies, 03 medical and health sciences, 1311 Genetics, 1312 Molecular Biology, Biology, Molecular Biology, Gene, Crosses, Genetic, Ecology, Evolution, Behavior and Systematics, 030304 developmental biology, Evolutionary Biology, Polymorphism, Genetic, Human evolutionary genetics, Selfing, Brassicaceae, biology.organism_classification, Diploidy, Tetraploidy, lcsh:Genetics, 1105 Ecology, Evolution, Behavior and Systematics, Fertilization, Mutation, Genetic Polymorphism, 570 Life sciences, U7 Systems Biology / Functional Genomics, Gene Function, Protein Kinases, Population Genetics

Abstract

The evolutionary transition from outcrossing to self-fertilization (selfing) through the loss of self-incompatibility (SI) is one of the most prevalent events in flowering plants, and its genetic basis has been a major focus in evolutionary biology. In the Brassicaceae, the SI system consists of male and female specificity genes at the S-locus and of genes involved in the female downstream signaling pathway. During recent decades, much attention has been paid in particular to clarifying the genes responsible for the loss of SI. Here, we investigated the pattern of polymorphism and functionality of the female specificity gene, the S-locus receptor kinase (SRK), in allotetraploid Arabidopsis kamchatica. While its parental species, A. lyrata and A. halleri, are reported to be diploid and mainly self-incompatible, A. kamchatica is self-compatible. We identified five highly diverged SRK haplogroups, found their disomic inheritance and, for the first time in a wild allotetraploid species, surveyed the geographic distribution of SRK at the two homeologous S-loci across the species range. We found intact full-length SRK sequences in many accessions. Through interspecific crosses with the self-incompatible and diploid congener A. halleri, we found that the female components of the SI system, including SRK and the female downstream signaling pathway, are still functional in these accessions. Given the tight linkage and very rare recombination of the male and female components on the S-locus, this result suggests that the degradation of male components was responsible for the loss of SI in A. kamchatica. Recent extensive studies in multiple Brassicaceae species demonstrate that the loss of SI is often derived from mutations in the male component in wild populations, in contrast to cultivated populations. This is consistent with theoretical predictions that mutations disabling male specificity are expected to be more strongly selected than mutations disabling female specificity, or the female downstream signaling pathway., Author Summary Since Charles Darwin recognized the extraordinary diversity of plant mating systems, deciphering their origins has been a central theme for evolutionary biologists. Among various sexual systems, the evolution of self-fertilization (selfing) from cross-fertilization is one of the most frequent transitions in flowering plants, but the genetic basis responsible for these changes is still poorly understood. Here, we have focused on the evolution of selfing in the Brassicaceae, where cross-fertilization is usually enforced by a self-incompatibility (SI) system, determining specific recognition between the pistil (female component) and the pollen (male component). Through sequencing analysis and crossing experiments, we studied the genetic changes leading to the loss of SI in the selfing species Arabidopsis kamchatica. We found that the female components of the SI system remain functional in many accessions, suggesting that degradation of the male component was responsible for the loss of SI. Recent studies in the Brassicaceae suggest that such a male-driven loss of SI is more common in wild than in cultivated populations. Furthermore, this pattern is consistent with theories predicting that mutations disabling male specificity have a higher probability of leading to successful mating and are thus more likely to spread than those disabling female specificity.

Published

2012