ABSTRACT
The Arabidopsis early flowering 3 (elf3) mutation causes arrhythmic circadian output in continuous light, but there is some evidence of clock function in darkness. Here, we show conclusively that normal circadian function occurs with no alteration of period length in elf3 mutants in dark conditions and that the light-dependent arrhythmia observed in elf3 mutants is pleiotropic on multiple outputs normally expressed at different times of day. Plants overexpressing ELF3 have an increased period length in both constant blue and red light; furthermore, etiolated ELF3-overexpressing seedlings exhibit a decreased acute CAB2 response after a red light pulse, whereas the null mutant is hypersensitive to acute induction. This finding suggests that ELF3 negatively regulates light input to both the clock and its outputs. To determine whether ELF3's action is phase dependent, we examined clock resetting by using light pulses and constructed phase response curves. Absence of ELF3 activity causes a significant alteration of the phase response curve during the subjective night, and constitutive overexpression of ELF3 results in decreased sensitivity to the resetting stimulus, suggesting that ELF3 antagonizes light input to the clock during the night. The phase of ELF3 function correlates with its peak expression levels in the subjective night. ELF3 action, therefore, represents a mechanism by which the oscillator modulates light resetting.
Subject(s)
Arabidopsis Proteins , Arabidopsis/physiology , Circadian Rhythm/physiology , Nuclear Proteins/physiology , Plant Proteins/physiology , Transcription Factors/physiology , Arabidopsis/radiation effects , Circadian Rhythm/radiation effects , Cloning, Molecular , Darkness , Gene Expression Profiling , Gene Expression Regulation, Plant , Light , Mutation , Plants, Genetically ModifiedABSTRACT
The circadian rhythms we observe originate from the circadian regulation of gene expression. Common control points, like transcription and protein phosphorylation, are used to effect this regulation, both within the clock and in output pathways. Recent work has advanced our understanding of these processes in plants and other models. Also, specific photoreceptors that mediate light entrainment of the clock have been identified in Arabidopsis.
Subject(s)
Arabidopsis/physiology , Circadian Rhythm/physiology , Gene Expression Regulation, Plant , Arabidopsis/genetics , Arabidopsis/radiation effects , Chloroplasts/genetics , Chloroplasts/radiation effects , Light , Phosphorylation , Plant Proteins/metabolism , Transcription Factors/geneticsABSTRACT
The cycling bioluminescence of Arabidopsis plants carrying a firefly luciferase fusion construct was used to identify mutant individuals with aberrant cycling patterns. Both long- and short-period mutants were recovered. A semidominant short-period mutation, timing of CAB expression (toc1), was mapped to chromosome 5. The toc1 mutation shortens the period of two distinct circadian rhythms, the expression of chlorophyll a/b-binding protein (CAB) genes and the movements of primary leaves, although toc1 mutants do not show extensive pleiotropy for other phenotypes.
Subject(s)
Arabidopsis Proteins , Arabidopsis/physiology , Biological Clocks/genetics , Carrier Proteins/genetics , Circadian Rhythm/genetics , Genes, Plant , Photosynthetic Reaction Center Complex Proteins , Photosystem II Protein Complex , Plant Proteins , Arabidopsis/genetics , Crosses, Genetic , Darkness , Gene Expression Regulation, Plant , Light , Light-Harvesting Protein Complexes , Luciferases/genetics , Luminescence , Movement , Mutation , Phenotype , Plant Leaves/physiology , Plants, Genetically Modified , Recombinant Fusion ProteinsABSTRACT
We developed a versatile, efficient genetic transfer method for Synechococcus sp. strains PCC 7942 and PCC 6301 that exceeds natural transformation efficiencies by orders of magnitude. As a test case, we complemented a histidine auxotroph and identified a hisS homolog of PCC 7942 as the complementing gene.
Subject(s)
Conjugation, Genetic , Cyanobacteria/genetics , Gene Transfer Techniques , Transformation, Genetic , Amino Acid Sequence , Base Sequence , Chromosomes, Bacterial , Escherichia coli/genetics , Genetic Complementation Test , Genetic Vectors , Histidine/biosynthesis , Molecular Sequence DataABSTRACT
We have used a luciferase reporter gene and continuous automated monitoring of bioluminescence to demonstrate unequivocally that cyanobacteria exhibit circadian behaviors that are fundamentally the same as circadian rhythms of eukaryotes. We also show that these rhythms can be studied by molecular methods in Synechococcus sp. PCC7942, a strain for which genetic transformation is well established. A promoterless segment of the Vibrio harveyi luciferase structural genes (luxAB) was introduced downstream of the promoter for the Synechococcus psbAI gene, which encodes a photosystem II protein. This reporter construction was recombined into the Synechococcus chromosome, and bioluminescence was monitored under conditions of constant illumination following entrainment to light and dark cycles. The reporter strain, AMC149, expressed a rhythm of bioluminescence which satisfies the criteria of circadian rhythms: persistence in constant conditions, phase resetting by light/dark signals, and temperature compensation of the period. Rhythmic changes in levels of the native psbAI message following light/dark entrainment supported the reporter data. The behavior of this prokaryote disproves the dogma that circadian mechanisms must be based on eukaryotic cellular organization. Moreover, the cyanobacterial strain described here provides an efficient experimental system for molecular analysis of the circadian clock.
