Your search keyword '"Veleri S"' showing total 4 results

1. The neuropeptide pigment-dispersing factor adjusts period and phase of Drosophila's clock.

Author

Yoshii T, Wülbeck C, Sehadova H, Veleri S, Bichler D, Stanewsky R, and Helfrich-Förster C

Subjects

Adaptation, Physiological genetics, Analysis of Variance, Animals, Animals, Genetically Modified, Brain cytology, Drosophila, Drosophila Proteins genetics, Gene Expression Regulation genetics, Insect Proteins metabolism, Luciferases metabolism, Models, Biological, Neurons metabolism, Nuclear Proteins genetics, Period Circadian Proteins, Time Factors, Circadian Rhythm genetics, Drosophila Proteins metabolism, Gene Expression Regulation physiology, Neuropeptides metabolism, Nuclear Proteins metabolism

Abstract

The neuropeptide pigment-dispersing factor (PDF) is a key transmitter in the circadian clock of Drosophila melanogaster. PDF is necessary for robust activity rhythms and is thought to couple the circadian oscillations of the clock neurons. However, little is known about the action of PDF on individual clock neurons. Here, we combined the period-luciferase reporter system with immunolabeling of clock proteins in wild-type and Pdf(01) mutants to dissect the effects of PDF on specific subgroups of clock neurons. Additionally, PDF levels were elevated to higher than normal levels using specific neural mutants, and a correlation analysis of locomotor activity and clock protein staining served to determine the periods of specific clock cells. We found that PDF has multiple effects on the clock neurons: In some groups of clock neurons, PDF was required for maintaining the oscillations of individual cells, and in others, PDF was required for synchronous cycling of the individual members. Other clock neurons cycled with high amplitude in absence of PDF, but PDF affected their intrinsic clock speed. Sometimes PDF shortened and sometimes PDF lengthened period. Our observations indicate that PDF is crucial for adjusting cycling amplitude, period, and phase of the different players in the circadian clock. Under natural conditions PDF may be required for adapting Drosophila's clock to varying photoperiods. Indeed, we show here that Pdf(01) mutants are not able to adapt their activity to long photoperiods in a wild-type manner.

Published

2009

2. Hofbauer-Buchner eyelet affects circadian photosensitivity and coordinates TIM and PER expression in Drosophila clock neurons.

Author

Veleri S, Rieger D, Helfrich-Förster C, and Stanewsky R

Subjects

Animals, Circadian Rhythm physiology, Gene Expression, Light, Motor Activity physiology, Neurons metabolism, Period Circadian Proteins, Photoperiod, Synaptic Transmission physiology, Tetanus Toxin metabolism, Biological Clocks physiology, Drosophila Proteins metabolism, Drosophila melanogaster physiology, Nuclear Proteins metabolism, Photoreceptor Cells, Invertebrate physiology

Abstract

Extraretinal photoreception is a common input route for light resetting signals into the circadian clock of animals. In Drosophila melanogaster, substantial circadian light inputs are mediated via the blue light photoreceptor CRYPTOCHROME (CRY) expressed in clock neurons within the brain. The current model predicts that, upon light activation, CRY interacts with the clock proteins TIMELESS (TIM) and PERIOD (PER), thereby inducing their degradation, which in turn leads to a resetting of the molecular oscillations within the circadian clock. Here the authors investigate the function of another putative extraretinal circadian photoreceptor, the Hofbauer-Buchner eyelet (H-B eyelet), located between the retina and the medulla in the fly optic lobes. Blocking synaptic transmission between the H-B eyelet and its potential target cells, the ventral circadian pacemaker neurons, impaired the flies' ability to resynchronize their behavior under jet-lag conditions in the context of nonfunctional retinal photoreception and a mutation in the CRY-encoding gene. The same manipulation also affected synchronized expression of the clock proteins TIM and PER in different subsets of the clock neurons. This shows that synaptic communication between the H-B eyelet and clock neurons contributes to synchronization of molecular and behavioral rhythms and confirms that the H-B eyelet functions as a circadian photoreceptor. Blockage of synaptic transmission from the H-B eyelet in the presence of functional compound eyes and the absence of CRY also results in increased numbers of flies that are unable to synchronize to extreme photoperiods, supplying independent proof for the role of the H-B eyelet as a circadian photoreceptor.

Published

2007

3. Veela defines a molecular link between Cryptochrome and Timeless in the light-input pathway to Drosophila's circadian clock.

Author

Peschel N, Veleri S, and Stanewsky R

Subjects

Alleles, Amino Acid Sequence, Animals, Animals, Genetically Modified, Cryptochromes, Drosophila Proteins chemistry, Drosophila Proteins genetics, Drosophila melanogaster genetics, F-Box Proteins chemistry, F-Box Proteins genetics, F-Box Proteins metabolism, Flavoproteins genetics, Molecular Sequence Data, Motor Activity, Mutation genetics, Neuroglia metabolism, Neurons metabolism, Polymorphism, Genetic genetics, Renin metabolism, Sequence Alignment, Circadian Rhythm physiology, Drosophila Proteins metabolism, Drosophila melanogaster metabolism, Flavoproteins metabolism, Light, Signal Transduction

Abstract

Organisms use the daily cycles of light and darkness to synchronize their internal circadian clocks with the environment. Because they optimize physiological processes and behavior, properly synchronized circadian clocks are thought to be important for the overall fitness. In Drosophila melanogaster, the circadian clock is synchronized with the natural environment by light-dependent degradation of the clock protein Timeless, mediated by the blue-light photoreceptor Cryptochrome (Cry). Here we report identification of a genetic variant, Veela, which severely disrupts this process, because these genetically altered flies maintain behavioral and molecular rhythmicity under constant-light conditions that usually stop the clock. We show that the Veela strain carries a natural timeless allele (ls-tim), which encodes a less-light-sensitive form of Timeless in combination with a mutant variant of the F-box protein Jetlag. However, neither the ls-tim nor the jetlag genetic variant alone is sufficient to disrupt light input into the central pacemaker. We show a strong interaction between Veela and cryptochrome genetic variants, demonstrating that the Jetlag, Timeless, and Cry proteins function in the same pathway. Veela also reveals a function for the two natural variants of timeless, which differ in their sensitivity to light. In combination with the complex array of retinal and extraretinal photoreceptors known to signal light to the pacemaker, this previously undescribed molecular component of photic sensitivity mediated by the two Timeless proteins reveals that an unexpectedly rich complexity underlies modulation of this process.

Published

2006

4. A self-sustaining, light-entrainable circadian oscillator in the Drosophila brain.

Author

Veleri S, Brandes C, Helfrich-Förster C, Hall JC, and Stanewsky R

Subjects

Animals, Brain physiology, Chromosome Mapping, Cryptochromes, Darkness, Flavoproteins physiology, Gene Expression Profiling, Immunohistochemistry, Luciferases physiology, Luminescent Measurements, Motor Activity physiology, Period Circadian Proteins, Photoperiod, Receptors, G-Protein-Coupled, Transgenes physiology, Biological Clocks physiology, Brain cytology, Circadian Rhythm physiology, Drosophila physiology, Drosophila Proteins, Eye Proteins, Neurons physiology, Nuclear Proteins physiology, Photoreceptor Cells, Invertebrate

Abstract

Background: The circadian clock of Drosophila is able to drive behavioral rhythms for many weeks in continuous darkness (DD). The endogenous rhythm generator is thought to be generated by interlocked molecular feedback loops involving circadian transcriptional and posttranscriptional regulation of several clock genes, including period. However, all attempts to demonstrate sustained rhythms of clock gene expression in DD have failed, making it difficult to link the molecular clock models with the circadian behavioral rhythms. Here we restricted expression of a novel period-luciferase transgene to certain clock neurons in the Drosophila brain, permitting us to monitor reporter gene activity in these cells in real-time., Results: We show that only a subset of the previously described pacemaker neurons is able to sustain PERIOD protein oscillations after 5 days in constant darkness. In addition, we identified a sustained and autonomous molecular oscillator in a group of clock neurons in the dorsal brain with heretofore unknown function. We found that these "dorsal neurons" (DNs) can synchronize behavioral rhythms and that light input into these cells involves the blue-light photoreceptor cryptochrome., Conclusions: Our results suggest that the DNs play a prominent role in controlling locomotor behavior when flies are exposed to natural light-dark cycles. Analysis of similar "stable mosaic" transgenes should help to reveal the function of the other clock neuronal clusters within the fly brain.

Published

2003