Your search keyword '"Cigdem Sancar"' showing total 14 results

1. MNase Digestion for Nucleosome Mapping in Neurospora

Author

Cigdem Sancar, Gencer Sancar, and Michael Brunner

Subjects

Biology (General), QH301-705.5

Abstract

Digestion of chromatin by micrococcal nuclease MNase followed by high throughput sequencing allows us to determine the location and occupancy of nucleosomes on the genome. Here in this protocol we have described optimized conditions of MNase digestion of filamentous fungus Neurospora crassa chromatin without a requirement of a nuclear fractionation step.

Published

2016

2. Combinatorial control of light induced chromatin remodeling and gene activation in Neurospora.

Author

Cigdem Sancar, Nati Ha, Rüstem Yilmaz, Rafael Tesorero, Tamas Fisher, Michael Brunner, and Gencer Sancar

Subjects

Genetics, QH426-470

Abstract

Light is an important environmental cue that affects physiology and development of Neurospora crassa. The light-sensing transcription factor (TF) WCC, which consists of the GATA-family TFs WC1 and WC2, is required for light-dependent transcription. SUB1, another GATA-family TF, is not a photoreceptor but has also been implicated in light-inducible gene expression. To assess regulation and organization of the network of light-inducible genes, we analyzed the roles of WCC and SUB1 in light-induced transcription and nucleosome remodeling. We show that SUB1 co-regulates a fraction of light-inducible genes together with the WCC. WCC induces nucleosome eviction at its binding sites. Chromatin remodeling is facilitated by SUB1 but SUB1 cannot activate light-inducible genes in the absence of WCC. We identified FF7, a TF with a putative O-acetyl transferase domain, as an interaction partner of SUB1 and show their cooperation in regulation of a fraction of light-inducible and a much larger number of non light-inducible genes. Our data suggest that WCC acts as a general switch for light-induced chromatin remodeling and gene expression. SUB1 and FF7 synergistically determine the extent of light-induction of target genes in common with WCC but have in addition a role in transcription regulation beyond light-induced gene expression.

Published

2015

3. Reconstitution of an intact clock reveals mechanisms of circadian timekeeping

Author

Jeffrey A. Swan, Sarvind Tripathi, Joel Heisler, Clive R. Bagshaw, Susan S. Golden, Priya Crosby, Andy LiWang, Archana G. Chavan, Cigdem Sancar, Joseph G. Palacios, Carrie L. Partch, Rebecca K. Spangler, Mingxu Fang, and Dustin C. Ernst

Subjects

Synechococcus, Protein Folding, Multidisciplinary, Transcription, Genetic, Circadian Rhythm Signaling Peptides and Proteins, Circadian clock, Molecular Mimicry, Phosphotransferases, Representation (systemics), Gene Expression Regulation, Bacterial, Biology, Circadian Rhythm, Bacterial Proteins, Protein Domains, Mutation, Circadian rhythm, Protein Multimerization, Promoter Regions, Genetic, Neuroscience, Protein Kinases

Abstract

Circadian clocks control gene expression to provide an internal representation of local time. We report reconstitution of a complete cyanobacterial circadian clock in vitro, including the central oscillator, signal transduction pathways, downstream transcription factor, and promoter DNA. The entire system oscillates autonomously and remains phase coherent for many days with a fluorescence-based readout that enables real-time observation of each component simultaneously without user intervention. We identified the molecular basis for loss of cycling in an arrhythmic mutant and explored fundamental mechanisms of timekeeping in the cyanobacterial clock. We find that SasA, a circadian sensor histidine kinase associated with clock output, engages directly with KaiB on the KaiC hexamer to regulate period and amplitude of the central oscillator. SasA uses structural mimicry to cooperatively recruit the rare, fold-switched conformation of KaiB to the KaiC hexamer to form the nighttime repressive complex and enhance rhythmicity of the oscillator, particularly under limiting concentrations of KaiB. Thus, the expanded in vitro clock reveals previously unknown mechanisms by which the circadian system of cyanobacteria maintains the pace and rhythmicity under variable protein concentrations.

Published

2021

4. Structural mimicry confers robustness in the cyanobacterial circadian clock

Author

Sarvind Tripathi, Jeffrey A. Swan, Dustin C. Ernst, Joel Heisler, Cigdem Sancar, Andy LiWang, Susan S. Golden, Clive R. Bagshaw, Rebecca K. Spangler, Carrie L. Partch, Priya Crosby, and Joseph G. Palacios

Subjects

biology, Chemistry, Sasa, KaiC, Circadian clock, Histidine kinase, Robustness (evolution), Cooperativity, Kinase activity, Random hexamer, biology.organism_classification, Cell biology

Abstract

The histidine kinase SasA enhances robustness of circadian rhythms in the cyanobacterium S. elongatus by temporally controlling expression of the core clock components, kaiB and kaiC. Here we show that SasA also engages directly with KaiB and KaiC proteins to regulate the period and enhance robustness of the reconstituted circadian oscillator in vitro, particularly under limiting concentrations of KaiB. In contrast to its role regulating gene expression, oscillator function does not require SasA kinase activity; rather, SasA uses structural mimicry to cooperatively recruit the rare, fold-switched conformation of KaiB to the KaiC hexamer to form the nighttime repressive complex. Cooperativity gives way to competition with increasing concentrations of SasA to define a dynamic window by which SasA directly modulates clock robustness.One Sentence SummarySasA controls the assembly of clock protein complexes through a balance of cooperative and competitive interactions.

Published

2020

5. Reconstitution of an intact clock that generates circadian DNA binding in vitro

Author

Archana G. Chavan, Mingxu Fang, Cigdem Sancar, Susan S. Golden, Andy LiWang, Dustin C. Ernst, and Carrie L. Partch

Subjects

Period (gene), Circadian clock, Promoter, Biology, Biochemistry, Cell biology, Synthetic biology, Gene expression, Genetics, Circadian rhythm, Molecular Biology, Gene, Transcription factor, Biotechnology

Abstract

Circadian clocks control gene expression in the complex milieu of cells. Here, we reconstituted under defined conditions in vitro the cyanobacterial circadian clock system which includes an oscillator, signal-transduction pathways, transcription factor, and promoter DNA. The system oscillates autonomously with a near 24 h period, remains phase coherent for many days, and allows real-time observation of each component simultaneously without user intervention. This reassembled clock system provides new insights into how a circadian clock exerts control over gene expression and can serve in the area of synthetic biology as a new platform upon which to build even more complexity.One Sentence SummaryAn autonomously oscillating circadian clock-controlled gene regulatory circuit is studied in vitro using a real-time high-throughput assay.

Published

2020

6. Reconstitution of an intact clock reveals mechanisms of circadian timekeeping

Author

Andy LiWang, Archana G. Chavan, Jeffrey A. Swan, Joel C. Heisler, Cigdem Sancar, Dustin Ernst, Mingxu Fang, Clive R. Bagshaw, Sarvind Tripathi, Priya Crosby, Susan S. Golden, and Carrie L. Partch

Subjects

Physical Sciences, Chemical Sciences, Biophysics, Biological Sciences

Published

2022

7. Closing the negative feedback loop: a tandem ATPase keeps circadian time by coupling distant enzymatic activities

Author

Jeffrey A. Swan, Colby R. Sandate, Alfred M. Freeberg, Joel C. Heisler, Diana L. Etwaru, Cigdem Sancar, Dustin C. Ernst, Joseph G. Palacios, Clive R. Bagshaw, Archana G. Chavan, Susan S. Golden, Andy LiWang, Gabriel C. Lander, and Carrie L. Partch

Subjects

Biophysics

Published

2022

8. A Combined Computational and Genetic Approach Uncovers Network Interactions of the Cyanobacterial Circadian Clock

Author

Faruck Morcos, Mark L. Paddock, Susan S. Golden, Joseph S. Boyd, Cigdem Sancar, Ryan R. Cheng, and Christie, PJ

Subjects

0301 basic medicine, Cell signaling, Evolution, 1.1 Normal biological development and functioning, 030106 microbiology, Circadian clock, Computational biology, Biology, Medical and Health Sciences, Microbiology, Evolution, Molecular, 03 medical and health sciences, Bacterial Proteins, Underpinning research, Circadian Clocks, Sasa, Genetics, Computer Simulation, Interactor, Molecular Biology, Gene, Synechococcus, Agricultural and Veterinary Sciences, Bacterial, Molecular, Gene Expression Regulation, Bacterial, Articles, Biological Sciences, biology.organism_classification, Clock network, Response regulator, 030104 developmental biology, Gene Expression Regulation, Mutation, Signal transduction, Sleep Research, Signal Transduction

Abstract

Two-component systems (TCS) that employ histidine kinases (HK) and response regulators (RR) are critical mediators of cellular signaling in bacteria. In the model cyanobacterium Synechococcus elongatus PCC 7942, TCSs control global rhythms of transcription that reflect an integration of time information from the circadian clock with a variety of cellular and environmental inputs. The HK CikA and the SasA/RpaA TCS transduce time information from the circadian oscillator to modulate downstream cellular processes. Despite immense progress in understanding of the circadian clock itself, many of the connections between the clock and other cellular signaling systems have remained enigmatic. To narrow the search for additional TCS components that connect to the clock, we utilized direct-coupling analysis (DCA), a statistical analysis of covariant residues among related amino acid sequences, to infer coevolution of new and known clock TCS components. DCA revealed a high degree of interaction specificity between SasA and CikA with RpaA, as expected, but also with the phosphate-responsive response regulator SphR. Coevolutionary analysis also predicted strong specificity between RpaA and a previously undescribed kinase, HK0480 (herein CikB). A knockout of the gene for CikB ( cikB ) in a sasA cikA null background eliminated the RpaA phosphorylation and RpaA-controlled transcription that is otherwise present in that background and suppressed cell elongation, supporting the notion that CikB is an interactor with RpaA and the clock network. This study demonstrates the power of DCA to identify subnetworks and key interactions in signaling pathways and of combinatorial mutagenesis to explore the phenotypic consequences. Such a combined strategy is broadly applicable to other prokaryotic systems. IMPORTANCE Signaling networks are complex and extensive, comprising multiple integrated pathways that respond to cellular and environmental cues. A TCS interaction model, based on DCA, independently confirmed known interactions and revealed a core set of subnetworks within the larger HK-RR set. We validated high-scoring candidate proteins via combinatorial genetics, demonstrating that DCA can be utilized to reduce the search space of complex protein networks and to infer undiscovered specific interactions for signaling proteins in vivo . Significantly, new interactions that link circadian response to cell division and fitness in a light/dark cycle were uncovered. The combined analysis also uncovered a more basic core clock, illustrating the synergy and applicability of a combined computational and genetic approach for investigating prokaryotic signaling networks.

Published

2016

9. Transcription Factors in Light and Circadian Clock Signaling Networks Revealed by Genomewide Mapping of Direct Targets for Neurospora White Collar Complex

Author

Gencer Sancar, James C. Carrington, Rigzin Dekhang, Deborah Bell-Pedersen, Cigdem Sancar, Shaojie Li, Terry L. Thomas, Henry D. Priest, Jason E. Stajich, Kristina M. Smith, Andrew G. Tag, Michael Freitag, Michael Brunner, Ryan F. McCormick, Erin L. Bredeweg, and Christopher M. Sullivan

Subjects

Chromatin Immunoprecipitation, Light, Circadian clock, Biology, Polymerase Chain Reaction, Microbiology, Neurospora crassa, Fungal Proteins, Circadian Clocks, Gene Expression Regulation, Fungal, Gene Regulatory Networks, Circadian rhythm, Molecular Biology, Transcription factor, Genetics, Fungal genetics, High-Throughput Nucleotide Sequencing, Promoter, Articles, General Medicine, biology.organism_classification, Circadian Rhythm, Genome, Fungal, Transcription Factor Gene, Chromatin immunoprecipitation, Signal Transduction, Transcription Factors

Abstract

Light signaling pathways and circadian clocks are inextricably linked and have profound effects on behavior in most organisms. Here, we used chromatin immunoprecipitation (ChIP) sequencing to uncover direct targets of the Neurospora crassa circadian regulator White Collar Complex (WCC). The WCC is a blue-light receptor and the key transcription factor of the circadian oscillator. It controls a transcriptional network that regulates ∼20% of all genes, generating daily rhythms and responses to light. We found that in response to light, WCC binds to hundreds of genomic regions, including the promoters of previously identified clock- and light-regulated genes. We show that WCC directly controls the expression of 24 transcription factor genes, including the clock-controlled adv-1 gene, which controls a circadian output pathway required for daily rhythms in development. Our findings provide links between the key circadian activator and effectors in downstream regulatory pathways.

Published

2010

10. Activity of the circadian transcription factor White Collar Complex is modulated by phosphorylation of SP-motifs

Author

Cigdem Sancar, Tobias Schafmeier, Gencer Sancar, and Michael Brunner

Subjects

Amino Acid Motifs, Molecular Sequence Data, Circadian clock, Biophysics, Biochemistry, Neurospora, Mass Spectrometry, Neurospora crassa, Fungal Proteins, Serine, Structural Biology, Transcription (biology), Genetics, Amino Acid Sequence, White Collar Complex, Circadian rhythm, Phosphorylation, DNA, Fungal, Molecular Biology, Transcription factor, DNA Primers, Base Sequence, biology, Cell Biology, biology.organism_classification, Circadian Rhythm, DNA-Binding Proteins, Amino Acid Substitution, Mutagenesis, Site-Directed, Transcription Factors

Abstract

Posttranslational modifications, particularly phosphorylation, regulate activity, stability and localization of proteins in circadian clocks, thereby contributing to a stable oscillation with a period of approximately 24h. The White Collar Complex (WCC) is the central transcription factor of the circadian clock of Neurospora crassa. Its activity is regulated in a circadian manner by rhythmic phosphorylation, mediated by the clock protein Frequency (FRQ). Here we present purification of TAP-tagged WCC and identification of novel phosphorylation sites of WC-1 and WC-2, all of which appear to be proline directed. Exchange of a single WC-2 serine residue (S433) to alanine or aspartate affects WCC-dependent transcription and circadian period, suggesting an important role of WC-2 S433 phosphorylation for WCC activity and circadian timing.Structured summaryMINT-7033869: WC-2 (uniprotkb:P78714) physically interacts (MI:0218) with WC-1 (uniprotkb:Q01371) by tandem-affinity purification (MI:0676)MINT-7033885: WC-2 (uniprotkb:P78714) physically interacts (MI:0218) with FRQ (uniprotkb:P19970) and WC-1 (uniprotkb:Q01371) by cross-linking studies (MI:0030)

Published

2009

11. Combinatorial control of light induced chromatin remodeling and gene activation in Neurospora

Author

Michael Brunner, Rafael Tesorero, Rüstem Yilmaz, Gencer Sancar, Tamas Fisher, Nati Ha, and Cigdem Sancar

Subjects

Transcriptional Activation, Cancer Research, lcsh:QH426-470, Light, Biology, DNA-binding protein, Chromatin remodeling, Fungal Proteins, Transcription (biology), Gene Expression Regulation, Fungal, Gene expression, Genetics, Transcriptional regulation, Nucleosome, Molecular Biology, Transcription factor, Genetics (clinical), Ecology, Evolution, Behavior and Systematics, Regulation of gene expression, Neurospora crassa, Chromatin Assembly and Disassembly, DNA-Binding Proteins, lcsh:Genetics, Transcription Factors, Research Article

Abstract

Light is an important environmental cue that affects physiology and development of Neurospora crassa. The light-sensing transcription factor (TF) WCC, which consists of the GATA-family TFs WC1 and WC2, is required for light-dependent transcription. SUB1, another GATA-family TF, is not a photoreceptor but has also been implicated in light-inducible gene expression. To assess regulation and organization of the network of light-inducible genes, we analyzed the roles of WCC and SUB1 in light-induced transcription and nucleosome remodeling. We show that SUB1 co-regulates a fraction of light-inducible genes together with the WCC. WCC induces nucleosome eviction at its binding sites. Chromatin remodeling is facilitated by SUB1 but SUB1 cannot activate light-inducible genes in the absence of WCC. We identified FF7, a TF with a putative O-acetyl transferase domain, as an interaction partner of SUB1 and show their cooperation in regulation of a fraction of light-inducible and a much larger number of non light-inducible genes. Our data suggest that WCC acts as a general switch for light-induced chromatin remodeling and gene expression. SUB1 and FF7 synergistically determine the extent of light-induction of target genes in common with WCC but have in addition a role in transcription regulation beyond light-induced gene expression., Author Summary In this study we have investigated the roles of the Neurospora transcription factors (TFs) WCC and SUB1 in light-activation of transcription. In principle TFs could exert identical functions for transcriptional activation and the extent of transcription will be determined by the sum of activity of the TFs. In this case however, we found that the activity of the main blue-light photoreceptor WCC is essential for the activation of light-inducible genes. SUB1 cooperates synergistically with the WCC to enhance expression of a subset of genes controlled directly by the light-activated WCC but cannot activate its light-inducible target genes in the absence of WCC. WCC evicts nucleosomes at its binding sites. This process is supported by SUB1 at a subset of common target genes. Light-dependent nucleosome loss generally correlates with but is not dependent on induction of transcription. Light-induced nucleosome eviction by the WCC/SUB1 could sensitize promoters for activation via endogenous and exogenous cues other than light, which may modulate the plasticity of the light-responsive transcriptome.

Published

2014

12. Dawn- and dusk-phased circadian transcription rhythms coordinate anabolic and catabolic functions in Neurospora

Author

Cigdem, Sancar, Gencer, Sancar, Nati, Ha, François, Cesbron, and Michael, Brunner

Subjects

Time Factors, Neurospora crassa, Transcription, Genetic, Circadian, CLOCK Proteins, RNA, Fungal, WCC, CSP1, Models, Biological, Circadian Rhythm, Fungal Proteins, ChIP-seq, Metabolism, Cellulase, Gene Expression Regulation, Fungal, RNA Polymerase II, RNAPII, RNA-seq, Transcriptome, Research Article

Abstract

Background Circadian clocks control rhythmic expression of a large number of genes in coordination with the 24 hour day-night cycle. The mechanisms generating circadian rhythms, their amplitude and circadian phase are dependent on a transcriptional network of immense complexity. Moreover, the contribution of post-transcriptional mechanisms in generating rhythms in RNA abundance is not known. Results Here, we analyzed the clock-controlled transcriptome of Neurospora crassa together with temporal profiles of elongating RNA polymerase II. Our data indicate that transcription contributes to the rhythmic expression of the vast majority of clock-controlled genes (ccgs) in Neurospora. The ccgs accumulate in two main clusters with peak transcription and expression levels either at dawn or dusk. Dawn-phased genes are predominantly involved in catabolic and dusk-phased genes in anabolic processes, indicating a clock-controlled temporal separation of the physiology of Neurospora. Genes whose expression is strongly dependent on the core circadian activator WCC fall mainly into the dawn-phased cluster while rhythmic genes regulated by the glucose-dependent repressor CSP1 fall predominantly into the dusk-phased cluster. Surprisingly, the number of rhythmic transcripts increases about twofold in the absence of CSP1, indicating that rhythmic expression of many genes is attenuated by the activity of CSP1. Conclusions The data indicate that the vast majority of transcript rhythms in Neurospora are generated by dawn and dusk specific transcription. Our observations suggest a substantial plasticity of the circadian transcriptome with respect to the number of rhythmic genes as well as amplitude and phase of the expression rhythms and emphasize a major role of the circadian clock in the temporal organization of metabolism and physiology. Electronic supplementary material The online version of this article (doi:10.1186/s12915-015-0126-4) contains supplementary material, which is available to authorized users.

Published

2014

13. Metabolic compensation of the Neurospora clock by a glucose-dependent feedback of the circadian repressor CSP1 on the core oscillator

Author

Gencer Sancar, Cigdem Sancar, and Michael Brunner

Subjects

Feedback, Physiological, Fungal protein, White Collar-1, Circadian clock, Repressor, Biology, biology.organism_classification, Neurospora, Cell biology, CLOCK, Fungal Proteins, Glucose, Biochemistry, Circadian Clocks, Gene Expression Regulation, Fungal, Genetics, Circadian rhythm, Transcription factor, Developmental Biology, Research Paper, Transcription Factors

Abstract

Conidial separation 1 (CSP1) is a global transcription repressor. It is expressed under control of the white collar complex (WCC), the core transcription factor of the circadian clock of Neurospora. Here we report that the length of the circadian period decreases with increasing glucose concentrations in csp1 mutant strains, while the period is compensated for changes in glucose concentration in wild-type strains. Glucose stimulated CSP1 expression. Overexpression of CSP1 caused period lengthening and, eventually, complete dampening of the clock rhythm. We show that CSP1 inhibits expression of the WHITE COLLAR 1 (WC1) subunit of the WCC by repressing the wc1 promoter. Glucose-dependent repression of wc1 transcription by CSP1 compensated for the enhanced translation of WC1 at high glucose levels, resulting in glucose-independent expression of the WCC and, hence, metabolic compensation that maintained a constant circadian period. Thus, the negative feedback of CSP1 on WC1 expression constitutes a molecular pathway that coordinates energy metabolism and the circadian clock.

Published

2012

14. A global circadian repressor controls antiphasic expression of metabolic genes in Neurospora

Author

Thomas Höfer, Ingrid Lohmann, Timo Sachsenheimer, Nati Ha, Gencer Sancar, Britta Brügger, Felix T. Wieland, Cigdem Sancar, Elan Gin, Axel Diernfellner, Michael Brunner, and Simon Wdowik

Subjects

biology, Circadian clock, Genes, Fungal, Fungal genetics, Repressor, Cell Biology, biology.organism_classification, Neurospora, Article, Ubiquitin ligase, Circadian Rhythm, Fungal Proteins, Repressor Proteins, Biochemistry, Transcription (biology), Gene Expression Regulation, Fungal, biology.protein, Molecular Biology, Corepressor, Transcription factor

Abstract

The white-collar complex (WCC), the core transcription factor of the circadian clock of Neurospora, activates morning-specific expression of the transcription repressor CSP1. Newly synthesized CSP1 exists in a transient complex with the corepressor RCM1/RCO1 and the ubiquitin ligase UBR1. CSP1 is rapidly hyperphosphorylated and degraded via UBR1 and its ubiquitin conjugase RAD6. Genes controlled by CSP1 are rhythmically expressed and peak in the evening (i.e., in antiphase to morning-specific genes directly controlled by WCC). Rhythmic expression of these second-tier genes depends crucially on phosphorylation and rapid turnover of CSP1, which ensures tight coupling of CSP1 abundance and function to the circadian activity of WCC. Negative feedback of CSP1 on its own transcription buffers the amplitude of CSP1-dependent oscillations against fluctuations of WCC activity. CSP1 predominantly regulates genes involved in metabolism. It controls ergosterol synthesis and fatty acid desaturases and thereby modulates the lipid composition of membranes.

Published

2011