All Stories

  1. Nutritional compensation of the circadian clock is a conserved process influenced by gene expression regulation and mRNA stability
  2. PRD-2 mediates clock-regulated perinuclear localization of clock gene RNAs within the circadian cycle of Neurospora
  3. Circadian Clearance of a Fungal Pathogen from the Lung Is Not Based on Cell-intrinsic Macrophage Rhythms
  4. Aspergillus fumigatusPhotobiology Illuminates the Marked Heterogeneity between Isolates
  5. Alternative Use of DNA Binding Domains by the Neurospora White Collar Complex Dictates Circadian Regulation and Light Responses
  6. Development of the CRISPR/Cas9 System for Targeted Gene Disruption in Aspergillus fumigatus
  7. Circadian Control Sheds Light on Fungal Bioluminescence
  8. Dissecting the Mechanisms of the Clock in Neurospora
  9. Analysis of clock-regulated genes in Neurospora reveals widespread posttranscriptional control of metabolic potential
  10. Fungal photobiology: visible light as a signal for stress, space and time
  11. Neurospora WC-1 Recruits SWI/SNF to Remodel frequency and Initiate a Circadian Cycle
  12. Editorial overview: Host–microbe interactions: fungi
  13. Circadian Rhythms
  14. 6 Photobiology and Circadian Clocks in Neurospora
  15. Conserved RNA Helicase FRH Acts Nonenzymatically to Support the Intrinsically Disordered Neurospora Clock Protein FRQ
  16. Aging Well with a Little Wine and a Good Clock
  17. The Fungal Pathogen Aspergillus fumigatus Regulates Growth, Metabolism, and Stress Resistance in Response to Light
  18. Functional Analysis of the Aspergillus nidulans Kinome
  19. A fable of too much too fast
  20. High-resolution spatiotemporal analysis of gene expression in real time: In vivo analysis of circadian rhythms in Neurospora crassa using a FREQUENCY-luciferase translational reporter
  21. The circadian clock ofNeurospora crassa
  22. CHD1 Remodels Chromatin and Influences Transient DNA Methylation at the Clock Gene frequency
  23. High-Throughput Production of Gene Replacement Mutants in Neurospora crassa
  24. Neurospora illuminates fungal photoreception
  25. Circadian rhythms: Phosphorylating the CLOCK
  26. High-Throughput Construction of Gene Deletion Cassettes for Generation of Neurospora crassa Knockout Strains
  27. New Directions at Eukaryotic Cell
  28. Retinoic Acid Mediates Long-Paced Oscillations in Retinoid Receptor Activity: Evidence for a Potential Role for RIP140
  29. Post-translational modifications in circadian rhythms
  30. CK2 and temperature compensation inNeurospora
  31. A Role for Casein Kinase 2 in the Mechanism Underlying Circadian Temperature Compensation
  32. Quantitative Proteomics Reveals a Dynamic Interactome and Phase-Specific Phosphorylation in the Neurospora Circadian Clock
  33. Genome-wide analysis of light-inducible responses reveals hierarchical light signalling in Neurospora
  34. A Role for Id2 in Regulating Photic Entrainment of the Mammalian Circadian System
  35. SIRT1 Is a Circadian Deacetylase for Core Clock Components
  36. Simulating Dark Expressions and Interactions of frq and wc-1 in the Neurospora Circadian Clock
  37. Salad Days in the Rhythms Trade
  38. Long and short isoforms ofNeurosporaclock protein FRQ support temperature-compensated circadian rhythms
  39. The Genetic Basis of the Circadian Clock: Identification of frq and FRQ as Clock Components in Neurospora
  40. The novel ER membrane protein PRO41 is essential for sexual development in the filamentous fungus Sordaria macrospora
  41. Execution of the Circadian Negative Feedback Loop in Neurospora Requires the ATP-Dependent Chromatin-Remodeling Enzyme CLOCKSWITCH
  42. Enabling a Community to Dissect an Organism: Overview of the Neurospora Functional Genomics Project
  43. Preface
  44. How fungi keep time: circadian system in Neurospora and other fungi
  45. CLOCK leaves its mark on histones
  46. Proteins in the Neurospora Circadian Clockworks
  47. Circadian Rhythmicity by Autocatalysis
  48. PHYSIOLOGY: Enhanced: Running a Clock Requires Quality Time Together
  49. Neurospora Photoreceptors
  50. Cross-species microarray hybridization to identify developmentally regulated genes in the filamentous fungus Sordaria macrospora
  51. Circadian rhythmicity by autocatalysis
  52. Analysis of Circadian Rhythms in Neurospora: Overview of Assays and Genetic and Molecular Biological Manipulation
  53. Analysis of Circadian Output Rhythms of Gene Expression in Neurospora and Mammalian Cells in Culture
  54. The Neurospora Circadian System
  55. Kinases and Circadian Clocks
  56. Functional Genomics in Fungi
  57. The genome sequence of the filamentous fungus Neurospora crassa
  58. Role for antisense RNA in regulating circadian clock function in Neurospora crassa
  59. Circadian Programs of Transcriptional Activation, Signaling, and Protein Turnover Revealed by Microarray Analysis of Mammalian Cells
  60. The Neurospora circadian clock regulates a transcription factor that controls rhythmic expression of the output eas(ccg-2) gene
  61. Homology effects: the difference between 1 and 2
  62. Circadian Rhythms in Neurospora
  63. Genetic and Molecular Analysis of Circadian Rhythms inNeurospora
  64. The PAS Protein VIVID Defines a Clock-Associated Feedback Loop that Represses Light Input, Modulates Gating, and Regulates Clock Resetting
  65. Molecular Genetics of Circadian Rhythms inNeurosporaa Prototypic Circadian System
  66. Review and Renaissance in the Kingdom Next Door
  67. Application of microarray technology to identify novel components of the mammalian circadian clock
  68. Circadian biology: Clocks for the real world
  69. Molecular Bases for Circadian Clocks
  70. Eukaryotic circadian systems: cycles in common
  71. Common threads in eukaryotic circadian systems
  72. CIRCADIAN RHYTHMS: An End in the Beginning
  73. Clock genes and temperature effects
  74. Light-Induced Resetting of a Mammalian Circadian Clock Is Associated with Rapid Induction of the mPer1 Transcript
  75. Alternative Initiation of Translation and Time-Specific Phosphorylation Yield Multiple Forms of the Essential Clock Protein FREQUENCY
  76. Thermally Regulated Translational Control of FRQ Mediates Aspects of Temperature Responses in the Neurospora Circadian Clock
  77. GENETIC AND MOLECULAR ANALYSIS OF CIRCADIAN RHYTHMS
  78. Chapter 2 The genetic and molecular dissection of a prototypic circadian system
  79. Light-induced resetting of a circadian clock is mediated by a rapid increase in frequency transcript
  80. Preface
  81. Negative feedback defining a circadian clock: autoregulation of the clock gene frequency
  82. Preface
  83. Genetic Analysis of Circadian Clocks
  84. Genetic Analysis of Circadian Clocks
  85. Molecular Analysis of the Neurospora Clock: Cloning and Characterization of the frequency and period-4 Genes
  86. Closely watched clocks: molecular analysis of circadian rhythms in Neurospora and Drosophila
  87. New cloning vectors using benomyl resistance as a dominant marker for selection inNeurospora crassa and in other filamentous fungi
  88. Cellular and Molecular Bases of Biological Clocks. Models and Mechanisms for Circadian Timekeeping Leland N. Edmunds, Jr.
  89. The Neurospora clock gene frequency shares a sequence element with the Drosophila clock gene period
  90. Molecular cloning of genes under control of the circadian clock in Neurospora
  91. [28] Cell-free components in dinoflagellate bioluminescence. The particulate activity: Scintillons; the soluble components: Luciferase, luciferin, and luciferin-binding protein
  92. Neurospora crassa: A Unique System for Studying Circadian Rhythms
  93. Critical pulses of anisomycin drive the circadian oscillator inGonyaulax towards its singularity
  94. Dinoflagellate luciferin is structurally related to chlorophyll
  95. Corrections -Biochemistry of Dinoflagellate Bioluminescence: Purification and Characterization of Dinoflagellate Luciferin from Pyrocystis Iunula
  96. Biochemistry of dinoflagellate bioluminescence: the purification and characterization of dinoflagellate luciferin from Pyrocystis lunula
  97. The effects of protein synthesis inhibitors on theGonyaulax clock
  98. Circadian spontaneous bioluminescent glow and flashing ofGonyaulax polyedra
  99. Comparison of the biosynthetic and biodegradative ornithine decarboxylases of Escherichia coli
  100. BLUE LIGHT PHOTORECEPTORS -BEYOND PHOTOTROPINS AND CRYPTOCHROMES
  101. The Molecular Workings of theNeurospora Biological Clock
  102. Circadian Rhythms, Photobiology and Functional Genomics in Neurospora