More Like this

1. Analysis of Sleep and Circadian Rhythms from Drosophila Activity-Monitoring Data Using SCAMP

   https://doi.org/10.1101/pdb.prot108182  

   Vecsey, Christopher G; Koochagian, Casey; Porter, Maria T; Roman, Gregg; Sitaraman, Divya (February 2024, Cold Spring Harbor Protocols)

   Sleep is a fundamental feature of life for virtually all multicellular animals, but many questions remain about how sleep is regulated and what biological functions it plays. Substantial headway has been made in the study of both circadian rhythms and sleep in the fruit flyDrosophila melanogaster, much of it through studies of individual fly activity using beam break counts fromDrosophilaactivity monitors (DAMs). The number of laboratories worldwide studying sleep inDrosophilahas grown from only a few 20 years ago to hundreds today. The utility of these studies is limited by the quality of the metrics that can be extracted from the data. Many software options exist to help analyze DAM data; however, these are often expensive or have significant limitations. Therefore, we describe here a method for analyzing DAM-based data using the sleep and circadian analysis MATLAB program (SCAMP). This user-friendly software has an advantage of combining several analyses of both sleep and circadian rhythms in one package and produces graphical outputs as well as spreadsheets of the outputs for further statistical analysis. The version of SCAMP described here is also the first published software package that can analyze data from multibeam DAM5Ms, enabling determination of positional preference over time. 

   more » « less
2. Rewarding Capacity of Optogenetically Activating a Giant GABAergic Central-Brain Interneuron in Larval Drosophila

   https://doi.org/10.1523/JNEUROSCI.2310-22.2023  

   Mancini, Nino; Thoener, Juliane; Tafani, Esmeralda; Pauls, Dennis; Mayseless, Oded; Strauch, Martin; Eichler, Katharina; Champion, Andrew; Kobler, Oliver; Weber, Denise; et al (November 2023, The Journal of Neuroscience)

   Larvae of the fruit flyDrosophila melanogasterare a powerful study case for understanding the neural circuits underlying behavior. Indeed, the numerical simplicity of the larval brain has permitted the reconstruction of its synaptic connectome, and genetic tools for manipulating single, identified neurons allow neural circuit function to be investigated with relative ease and precision. We focus on one of the most complex neurons in the brain of the larva (of either sex), the GABAergic anterior paired lateral neuron (APL). Using behavioral and connectomic analyses, optogenetics, Ca²⁺imaging, and pharmacology, we study how APL affects associative olfactory memory. We first provide a detailed account of the structure, regional polarity, connectivity, and metamorphic development of APL, and further confirm that optogenetic activation of APL has an inhibiting effect on its main targets, the mushroom body Kenyon cells. All these findings are consistent with the previously identified function of APL in the sparsening of sensory representations. To our surprise, however, we found that optogenetically activating APL can also have a strong rewarding effect. Specifically, APL activation together with odor presentation establishes an odor-specific, appetitive, associative short-term memory, whereas naive olfactory behavior remains unaffected. An acute, systemic inhibition of dopamine synthesis as well as an ablation of the dopaminergic pPAM neurons impair reward learning through APL activation. Our findings provide a study case of complex circuit function in a numerically simple brain, and suggest a previously unrecognized capacity of central-brain GABAergic neurons to engage in dopaminergic reinforcement. SIGNIFICANCE STATEMENTThe single, identified giant anterior paired lateral (APL) neuron is one of the most complex neurons in the insect brain. It is GABAergic and contributes to the sparsening of neuronal activity in the mushroom body, the memory center of insects. We provide the most detailed account yet of the structure of APL in larvalDrosophilaas a neurogenetically accessible study case. We further reveal that, contrary to expectations, the experimental activation of APL can exert a rewarding effect, likely via dopaminergic reward pathways. The present study both provides an example of unexpected circuit complexity in a numerically simple brain, and reports an unexpected effect of activity in central-brain GABAergic circuits. 

   more » « less
3. Activity Monitoring for Analysis of Sleep in Drosophila melanogaster

   https://doi.org/10.1101/pdb.top108095  

   Sitaraman, Divya; Vecsey, Christopher G; Koochagian, Casey (February 2024, Cold Spring Harbor Protocols)

   Sleep is important for survival, and the need for sleep is conserved across species. In the past two decades, the fruit flyDrosophila melanogasterhas emerged as a promising system in which to study the genetic, neural, and physiological bases of sleep. Through significant advances in our understanding of the regulation of sleep in flies, the field is poised to address several open questions about sleep, such as how the need for sleep is encoded, how molecular regulators of sleep are situated within brain networks, and what the functions of sleep are. Here, we describe key findings, open questions, and commonly used methods that have been used to inform existing theories and develop new ways of thinking about the function, regulation, and adaptability of sleep behavior. 

   more » « less
4. The Drosophila circadian clock gene cycle controls the development of clock neurons

   https://doi.org/10.1371/journal.pgen.1011441  

   Biondi, Grace; McCormick, Gina; Fernandez, Maria P (October 2024, PLOS Genetics)

   Ewer, John (Ed.)

   Daily behavioral and physiological rhythms are controlled by the brain’s circadian timekeeping system, a synchronized network of neurons that maintains endogenous molecular oscillations. These oscillations are based on transcriptional feedback loops of clock genes, which inDrosophilainclude the transcriptional activatorsClock (Clk)andcycle (cyc). While the mechanisms underlying this molecular clock are very well characterized, the roles that the core clock genes play in neuronal physiology and development are much less understood. TheDrosophilatimekeeping center is composed of ~150 clock neurons, among which the four small ventral lateral neurons (sLN_vs) are the most dominant pacemakers under constant conditions. Here, we show that downregulating the clock genecycspecifically in thePdf-expressing neurons leads to decreased fasciculation both in larval and adult brains. This effect is due to a developmental role ofcyc, as both knocking downcycor expressing a dominant negative form ofcycexclusively during development lead to defasciculation phenotypes in adult clock neurons.Clkdownregulation also leads to developmental effects on sLNv morphology. Our results reveal a non-circadian role forcyc, shedding light on the additional functions of circadian clock genes in the development of the nervous system. 

   more » « less
5. Overlapping Central Clock Network Circuitry Regulates Circadian Feeding and Activity Rhythms in Drosophila

   https://doi.org/10.1177/07487304241263734  

   Saurabh, Sumit; Meier, Ruth_J; Pireva, Liliya_M; Mirza, Rabab_A; Cavanaugh, Daniel_J (July 2024, Journal of Biological Rhythms)

   The circadian system coordinates multiple behavioral outputs to ensure proper temporal organization. Timing information underlying circadian regulation of behavior depends on a molecular circadian clock that operates within clock neurons in the brain. In Drosophila and other organisms, clock neurons can be divided into several molecularly and functionally discrete subpopulations that form an interconnected central clock network. It is unknown how circadian signals are coherently generated by the clock network and transmitted across output circuits that connect clock cells to downstream neurons that regulate behavior. Here, we have exhaustively investigated the contribution of clock neuron subsets to the control of two prominent behavioral outputs in Drosophila: locomotor activity and feeding. We have used cell-specific manipulations to eliminate molecular clock function or induce electrical silencing either broadly throughout the clock network or in specific subpopulations. We find that clock cell manipulations produce similar changes in locomotor activity and feeding, suggesting that overlapping central clock circuitry regulates these distinct behavioral outputs. Interestingly, the magnitude and nature of the effects depend on the clock subset targeted. Lateral clock neuron manipulations profoundly degrade the rhythmicity of feeding and activity. In contrast, dorsal clock neuron manipulations only subtly affect rhythmicity but produce pronounced changes in the distribution of activity and feeding across the day. These experiments expand our knowledge of clock regulation of activity rhythms and offer the first extensive characterization of central clock control of feeding rhythms. Despite similar effects of central clock cell disruptions on activity and feeding, we find that manipulations that prevent functional signaling in an identified output circuit preferentially degrade locomotor activity rhythms, leaving feeding rhythms relatively intact. This demonstrates that activity and feeding are indeed dissociable behaviors, and furthermore suggests that differential circadian control of these behaviors diverges in output circuits downstream of the clock network. 

   more » « less