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The biological clock is involved in many aspects of regulating complex physiology in all animals. It was in 1935 when German zoologists, Hans Kalmus and Erwin Bünning, discovered the existence of circadian rhythm in Drosophila melanogaster. However, the internal molecular mechanisms behind the circadian clock remained a mystery until 1984, when Jeffrey C. Hall, Michael Rosbash, and Michael W. Young discovered the expression of the Per gene oscillating over a 24-hour cycle. In subsequent...
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The circadian—or biological—clock is an intrinsic, timekeeping, molecular mechanism that allows plants to coordinate physiological activities over 24-hour cycles called circadian rhythms. Photoperiodism is a collective term for the biological responses of plants to variations in the relative lengths of dark and light periods. The period of light-exposure is called the photoperiod.
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Circadian rhythms are cyclic changes that are crucial in plasma drug concentrations. Various standard circadian parameters, including core body temperature, heart rate, and other cardiovascular factors, directly impact disease states and the therapeutic response to drug therapy.
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The reticular formation is a complex network of gray and white matter located within the brainstem extending from the medulla to the midbrain.
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Global regulatory systems in bacteria enable rapid and coordinated responses to environmental changes by integrating sensory inputs with gene expression, ensuring efficient adaptation to fluctuating conditions. Key global regulatory mechanisms include regulons, two-component systems, sigma factors, and secondary messengers.Regulons and Global RegulatorsA regulon is a collection of genes and operons controlled by a common global regulator. These regulators enable bacteria to prioritize resource...
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Sleep, an essential biological state, involves significant reductions in physical activity, sensory awareness, and interaction with the environment. This complex physiological process is primarily regulated by specific brain regions, notably the hypothalamus and pons, which govern the sleep-wake cycle or circadian rhythm.
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Related Experiment Video

Updated: Feb 23, 2026

Parallel Measurement of Circadian Clock Gene Expression and Hormone Secretion in Human Primary Cell Cultures
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Parallel Measurement of Circadian Clock Gene Expression and Hormone Secretion in Human Primary Cell Cultures

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Coordination between Differentially Regulated Circadian Clocks Generates Rhythmic Behavior.

Deniz Top1, Michael W Young1

  • 1Laboratory of Genetics, The Rockefeller University, New York, New York 10065.

Cold Spring Harbor Perspectives in Biology
|September 13, 2017
PubMed
Summary
This summary is machine-generated.

Brain neurons mediate circadian rhythms by integrating environmental cues. Differences in protein expression create local clocks within the Drosophila circadian network, coordinating behavior.

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Area of Science:

  • Neuroscience
  • Chronobiology
  • Molecular Biology

Background:

  • Circadian rhythms are fundamental biological processes organized by specialized brain neurons.
  • The Drosophila circadian clock involves seven neuronal clusters expressing core clock proteins (Period, Timeless, Clock, Cycle).
  • Neuronal clusters are anatomically distributed, experiencing unique local environments.

Purpose of the Study:

  • To review communication within the Drosophila circadian neuronal network.
  • To highlight molecular differences, particularly protein expression patterns, among these neurons.
  • To explore how these variations contribute to functional differences in local clocks and overall behavioral rhythms.

Main Methods:

  • Review of existing literature on Drosophila circadian neurobiology.
  • Analysis of protein expression patterns in different circadian neuronal clusters.
  • Integration of findings on neuronal communication and intracellular mechanisms.

Main Results:

  • Core clock proteins are universally expressed, but regulatory proteins show differential expression, creating "local clocks."
  • Variations in protein expression impart functional specificity to individual neuronal clusters.
  • Communication between neurons and intracellular mechanisms converge to regulate coherent behavioral rhythms.

Conclusions:

  • Understanding local clock variations is crucial for deciphering circadian behavior.
  • Further research is needed to identify specific regulatory mechanisms within each neuronal cluster.
  • Elucidating these mechanisms will advance our understanding of the molecular basis of circadian behavior.