scholarly journals Evidence for co-evolution of masking and circadian phase in Drosophila melanogaster

2020 ◽  
Author(s):  
Arijit Ghosh ◽  
Pragya Sharma ◽  
Shephali Dansana ◽  
Vasu Sheeba
Keyword(s):  
Drosophila Melanogaster ◽  
Heritable Variation ◽  
Circadian Phase ◽  
Laboratory Selection ◽  
Advanced Phase ◽  
Eclosion Rhythm ◽  
Selection Window ◽  
Theoretical Predictions ◽  
Experimental Approaches ◽  
Selection For

AbstractHeritable variation in the timing or circadian phases of rhythmic events with respect to daily time cues gives rise to chronotypes. Despite its importance, the mechanisms (clock or non-clock) regulating chronotypes remain elusive. Using artificial laboratory selection for divergent phasing of emergence of adults from pupae, our group has derived populations of Drosophila melanogaster which are early and late chronotypes for eclosion rhythm. Several circadian rhythm characteristics of these populations have since been described. We hypothesized that our selection protocol has inadvertently resulted in selection for masking, a non-clock phenomenon, in the early chronotype due to the placement of our selection window (which includes the lights-ON transition). Based on theoretical predictions and previous studies on our populations, we designed experiments to discriminate between enhanced masking to light versus circadian clock mediated changes in determining enhanced emergence in the morning window in our early chronotypes. Using a series of phase-shift protocols, LD-DD transition, and T-cycle experiments, we find that our early chronotypes have evolved positive masking, and their apparent entrained phases are largely contributed by masking. Through skeleton T-cycle experiments, we find that in addition to the evolution of greater masking, our early chronotypes have also evolved advanced phase of entrainment. Furthermore, our study systematically outlines experimental approaches to examine relative contributions of clock versus non-clock control of an entrained behavior. Although it has previously been suggested that masking may confer an adaptive advantage to organisms, here we provide experimental evidence for the evolution of masking as a mean of phasing of an entrained rhythm that can complement clock control of an entrained behavior.

scholarly journals Evidence for Co-Evolution of Masking With Circadian Phase in Drosophila Melanogaster

2021 ◽  
pp. 074873042199726
Author(s):  
Arijit Ghosh ◽  
Pragya Sharma ◽  
Shephali Dansana ◽  
Vasu Sheeba
Keyword(s):  
Drosophila Melanogaster ◽  
Heritable Variation ◽  
Circadian Phase ◽  
Laboratory Selection ◽  
Advanced Phase ◽  
Eclosion Rhythm ◽  
Selection Window ◽  
Experimental Approaches ◽  
Selection Protocol ◽  
Selection For

Heritable variation in the timing of rhythmic events with respect to daily time cues gives rise to chronotypes. Despite its importance, the mechanisms (clock or non-clock) regulating chronotypes remain elusive. Using artificial laboratory selection for divergent phasing of emergence of adults from pupae, our group has derived populations of Drosophila melanogaster which are early and late chronotypes for eclosion rhythm. Several circadian rhythm characteristics of these populations have since been described. We hypothesized that our selection protocol has inadvertently resulted in selection for masking, a non-clock phenomenon, in the early chronotype due to the placement of our selection window (which includes the lights-ON transition). We designed experiments to discriminate between enhanced masking to light versus circadian clock mediated changes in determining enhanced emergence in the morning window in our early chronotypes. Using a series of phase-shift protocols, LD-DD transition, and T-cycle experiments, we find that our early chronotypes have evolved positive masking, and their apparent entrained phases are largely contributed by masking. Through skeleton T-cycle experiments, we find that in addition to the evolution of greater masking, our early chronotypes have also evolved advanced phase of entrainment. Furthermore, our study systematically outlines experimental approaches to examine relative contributions of clock versus non-clock control of an entrained behavior. Although it has previously been suggested that masking may confer an adaptive advantage to organisms, here we provide experimental evidence for the evolution of masking as a means of phasing that can complement clock control of an entrained behavior.

Using laboratory selection for desiccation resistance to examine the relationship between respiratory pattern and water loss in insects.

1998 ◽  
Vol 201 (21) ◽  
pp. 2945-2952 ◽  
Author(s):  
A E Williams ◽  
M R Rose ◽  
T J Bradley
Keyword(s):  
Drosophila Melanogaster ◽  
Water Loss ◽  
Loss Rate ◽  
Respiratory Pattern ◽  
Desiccation Resistance ◽  
Water Loss Rate ◽  
Laboratory Selection ◽  
Selection For ◽  
The Relationship ◽  
Co2 Release

We conducted concurrent measurements of rates of CO2 and H2O release from individual fruit flies Drosophila melanogaster taken from populations subjected to three different selective regimes: (1) populations selected for resistance to desiccation (D flies); (2) populations maintained as their controls (C flies); and (3) the ancestral populations of the D and C populations (O flies). In the D flies, water loss rates were significantly reduced, the standard error of the regression (SER) of the CO2 release pattern measured over the survival period of the flies was increased, and the ratio of CO2 loss to H2O loss (VCO2/VH2O) was increased. Correlations across all 15 populations from the three selection treatments indicate that survival time was negatively correlated with water loss rate, positively correlated with the SER of CO2 release and positively correlated with the VCO2/VH2O ratio. We did not, however, find a significant correlation between the SER of CO2 release and rates of water loss or the VCO2/VH2O ratio.

Laboratory selection for increased longevity in Drosophila melanogaster reduces field performance

2013 ◽  
Vol 48 (11) ◽  
pp. 1189-1195 ◽  
Author(s):  
Janneke Wit ◽  
Torsten Nygaard Kristensen ◽  
Pernille Sarup ◽  
Jane Frydenberg ◽  
Volker Loeschcke
Keyword(s):  
Drosophila Melanogaster ◽  
Field Performance ◽  
Laboratory Selection ◽  
Selection For

Laboratory selection for the comparative physiologist

1999 ◽  
Vol 202 (20) ◽  
pp. 2709-2718 ◽  
Author(s):  
A.G. Gibbs
Keyword(s):  
Experimental Approach ◽  
Comparative Physiology ◽  
Behavioral Differences ◽  
Physiological Mechanisms ◽  
Success Stories ◽  
Laboratory Selection ◽  
Adaptive Value ◽  
Selection Experiments ◽  
Experimental Approaches ◽  
Selection For

An increasingly popular experimental approach in comparative physiology is to study the evolution of physiological traits in the laboratory, using microbial, invertebrate and vertebrate models. Because selective conditions are well-defined, selected populations can be replicated and unselected control populations are available for direct comparison, strong conclusions regarding the adaptive value of an evolved response can be drawn. These studies have shown that physiological systems evolve rapidly in the laboratory, but not always as one would expect from comparative studies of different species. Laboratory environments are often not as simple as one thinks, so that the evolution of behavioral differences or selection acting on different life stages can lead to unanticipated results. In some cases, unexpected responses to laboratory selection may suggest new insights into physiological mechanisms, which might not be available using other experimental approaches. I outline here recent results (including success stories and caveats for the unwary investigator) and potential directions for selection experiments in comparative physiology.

Selection for Timing of Eclosion Results in Co-evolution of Temperature Responsiveness in Drosophila melanogaster

2019 ◽  
Vol 34 (6) ◽  
pp. 596-609 ◽  
Author(s):  
Lakshman Abhilash ◽  
Arijit Ghosh ◽  
Vasu Sheeba
Keyword(s):  
Drosophila Melanogaster ◽  
Coupled Oscillators ◽  
Temperature Sensitive ◽  
Warm Temperature ◽  
Ambient Temperatures ◽  
Overt Behavior ◽  
Temperature Regimes ◽  
Eclosion Rhythm ◽  
Selection For ◽  
Master Clock

Circadian rhythms in adult eclosion of Drosophila are postulated to be regulated by a pair of coupled oscillators: one is the master clock that is light sensitive and temperature compensated and the other that is a slave oscillator whose period is temperature sensitive and whose phase is reflected in the overt behavior. Within this framework, we reasoned that in populations of Drosophila melanogaster that have been artificially selected for highly divergent phases of eclosion rhythm, there may be changes in this network of the master-slave oscillator system, via changes in the temperature-sensitive oscillator and/or the coupling of the light- and temperature-sensitive oscillators. We used light/dark cycles in conjunction with different constant ambient temperatures and 2 different amplitudes of temperature cycles in an overall cool or warm temperature and analyzed phases, gate width, and normalized amplitude of the rhythms in each of these conditions. We found that the populations selected for eclosion in the morning ( early flies) do not vary their phases with change in temperature regimes, whereas the populations selected for eclosion in the evening ( late flies) show phase lability of up to ~5 h. Our results imply a genetic correlation between timing of behavior and temperature sensitivity of the circadian clock.

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