Descending GABAergic pathway links brain sugar-sensing to peripheral nociceptive gating in Drosophila

Although painful stimuli elicit defensive responses including escape behavior for survival, starved animals often prioritize feeding over escape even in a noxious environment. This behavioral priority is typically mediated by suppression of noxious inputs through descending control in the brain, yet underlying molecular and cellular mechanisms are incompletely understood. Here we identify a cluster of GABAergic neurons in Drosophila larval brain, designated as SEZ-localized Descending GABAergic neurons (SDGs), that project descending axons onto the axon terminals of the peripheral nociceptive neurons and prevent presynaptic activity through GABAB receptors. Remarkably, glucose feeding to starved larvae causes sustained activation of SDGs through glucose-sensing neurons and subsequent insulin signaling in SDGs, which attenuates nociception and thereby suppresses escape behavior in response to multiple noxious stimuli. These findings illustrate a neural mechanism by which sugar sensing neurons in the brain engages descending GABAergic neurons in nociceptive gating to achieve hierarchical interaction between feeding and escape behavior.

Although painful stimuli elicit defensive responses including escape behavior for survival, starved animals often prioritize feeding over escape even in a noxious environment.This behavioral priority is typically mediated by suppression of noxious inputs through descending control in the brain, yet underlying molecular and cellular mechanisms are incompletely understood.
Here we identify a cluster of GABAergic neurons in Drosophila larval brain, designated as SEZ-localized Descending GABAergic neurons (SDGs), that project descending axons onto the axon terminals of the peripheral nociceptive neurons and prevent presynaptic activity through GABA B receptors.Remarkably, glucose feeding to starved larvae causes sustained activation of SDGs through glucose-sensing neurons and subsequent insulin signaling in SDGs, which attenuates nociception and thereby suppresses escape behavior in response to multiple noxious stimuli.These findings illustrate a neural mechanism by which sugar sensing neurons in the brain engages descending GABAergic neurons in nociceptive gating to achieve hierarchical interaction between feeding and escape behavior.
Animals typically display one behavior at a time, and thus need to assign behavioral priorities 1,2 .This behavioral priority is influenced by an animal's behavioral states as well as its internal states.One remarkable example is the behavioral conflict between nociceptive responses and feeding.Once an animal receives potentially harmful stimuli such as harsh mechanical inputs, pungent chemicals, or noxious heat, it immediately escapes from noxious environments 3 .In food-deprived animals, however, feeding often takes precedence over escape responses.For instance, food-deprived cats are less likely to withdraw from acute noxious cutaneous heat during eating 4 , and fooddeprived chickens show fewer pain-motivated behavior in response to tonic pain produced in the legs while eating takes place 5 .Likewise, medicinal leeches show reduced nociceptive response to harsh chemicals and electric shock while feeding 6,7 .Prioritization of feeding over nociceptive responses is likewise observed in crayfish and mollusks [8][9][10] .
In addition, sugar feeding produces analgesic effects in rat and human infants 11,12 .
Previous studies suggest that the hierarchical interaction between feeding and nociceptive responses is in part mediated by nociceptive suppression through descending control in the brain [13][14][15] .Noxious stimuli are typically received by nociceptive neurons, the sensory neurons specialized for their detection [16][17][18] .In mammals, these noxious inputs are relayed directly to spinal motor neurons to provoke escape behavior and to the second-order neurons in the spinal cord to higherorder processing centers in the brain 15,19,20 .This nociceptive sensory processing is often modulated by both the local interneurons in the spinal cord and the descending neurons in the brain that directly innervate the nociceptive circuit in the spinal cord 15,21 .In rodents, electrophysiological studies showed that sugar feeding to starved animals upregulates neural activity of a subpopulation of descending neurons in the brainstem and that pharmacological inactivation of the brainstem neurons attenuates the pain suppression by sugar feeding 22,23 .These data suggest that certain types of descending neurons in the brain are involved in pain suppression during feeding, yet detailed regulatory mechanisms including how feeding engages descending control in pain suppression remain elusive.
Recent studies reveal that Drosophila larvae have a nociceptive sensory system with a circuit arrangement partially analogous to that in mammals [24][25][26] .Noxious stimuli elicit stereotyped escape behaviors in Drosophila larvae including rolling followed by fast crawling [27][28][29] .This noxious stimulus-evoked escape behavior is triggered by peripheral nociceptive neurons, the class IV da (C4da) neurons, which densely innervate the body wall with their dendritic branches and project their axons to the ventral nerve cord (VNC) (Fig. 1a) [30][31][32][33] .In the VNC, C4da axon terminals form synaptic contacts with multiple identified secondorder neurons including some with ascending projections to the brain (for example, A08n) and others, such as mCSIs, that output to motoneurons for reflex responses 27,28,34,35 .Like nociceptive circuits in mammals, the nociceptive circuit in Drosophila larvae receives modulatory inputs from local neurons in the VNC 34,35 .However, to date, descending inputs that modulate nociceptive processing and behavior have not been identified in Drosophila larvae.
In this study, we have identified a small cluster of GABAergic neurons in the Drosophila larval brain, designated as SEZ-localized Descending GABAergic neurons (SDGs), that project descending axons onto axonal terminals of C4da neurons in the VNC.Calcium imaging and optogenetic manipulation revealed that SDGs negatively regulate C4da synaptic activity through GABA B receptors, which terminates escape rolling behavior.Furthermore, we found that feeding D-glucose, but not L-glucose and arabinose, significantly attenuated noxious stimuli-evoked escape behavior in starved larvae.This glucoseinduced nociceptive suppression is mediated by the glucose-sensing CN neurons 36 that directly evoked insulin release from the insulinproducing cells (IPCs) in the brain upon sugar refeeding, which m m m Fig. 1 | Identification of the descending SDGs that innervate C4da axon terminals.a Top, a schematic lateral view of C4da neurons in third instar larvae.Bottom, a schematic ventral view of axon terminal projections of C4da neurons in the ventral nerve cord (VNC).b Cell bodies of SDGs located in the larval brain.Nuclear-targeted GFP (green) and membrane-bound tdTomato (magenta) were driven by SDGs-spGAL4.Similar results were obtained across 3 independent samples per genotype.c Dual labeling of SDGs expressing mCD8::GFP (green) and C4da neurons visualized with ppk-CD4::tdTomato (magenta).Top panels show the signals in the larval brain and VNC.Middle panels show magnified images of the abdominal A6-7 segments in the VNC (the yellow squared area in the top panels).Bottom panels are transverse sections of the A7 segment.Similar results were obtained across 5 independent samples per genotype.d Expression of the presynaptic marker Brp::mCherry (magenta), and mCD8::GFP (green) under the control of SDGs-spGAL4.Similar results were obtained across 5 independent samples per genotype.e Left, a schematic view of Syb-GRASP signals between SDGs and C4da neurons.Middle, confocal images of Syb-GRASP signals in the larval VNC.Right, the axon terminals of SDGs are labeled by CsChrimson::mCherry.Note that each pair of images placed side-by-side shows an identical region.Similar results were obtained across 4 independent samples per genotype.See Supplementary Table 1 for full genotypes.f A schematic image of synaptic contacts from SDGs to C4da axon terminals.
promoted sustained SDGs activation via insulin receptors and thereby attenuates nociception.These findings support a model in which sugar feeding suppresses nociception through glucose sensing neurons and subsequent insulin signaling in GABAergic descending neurons, ensuring hierarchical interactions between feeding and escape behavior.

Results
Identification of SDGs, a previously uncharacterized subpopulation of descending neurons innervating axon terminals of C4da nociceptive neurons To isolate descending neurons that modulate larval escape behavior, we searched for neurons that project to the regions of the neuropil occupied by C4da terminals (Fig. 1a).A visual screen of 6849 Janelia GAL4 collections (https://flweb.janelia.org/cgi-bin/flew.cgi)revealed 9 lines that appeared to label neurites in the VNC with close proximity to the distinctive ladder-like axon terminals of C4da neurons.Among them, R16C06-GAL4 labeled 30-40 cells that were clustered around the SEZ of the larval central brain and had descending projections partially overlapping with C4da axon terminals (Supplementary Fig. 1a).To identify the C4da-innervating descending neurons with higher cellular resolution, we searched for split-GAL4 combinations that cover the R16C06-GAL4/LexA-labeled subpopulations and found that the intersection between R21F01-p65.AD and R93B07-GAL4.DBD specifically captured 6 of the 30-40 neurons labeled by R16C06-LexA (Supplementary Fig. 1b).All 6 neurons had their cell bodies in the SEZ (Fig. 1b, c), and their descending projections exhibited a substantial overlap with the ladder-like axonal terminals of C4da neurons (Fig. 1c).Based on these characteristics, we designated this distinct subpopulation as "SEZ-localized Descending GABAergic neurons (SDGs)", and henceforth refer to this combination of split-GAL4 as SDGs-spGAL4.Since the presynaptic marker Brp::mCherry expressed in SDGs was largely confined in their descending neurites in the VNC (Fig. 1d), SDGs likely project axons to the VNC.To examine whether SDGs might form synaptic contacts with C4da axon terminals, we performed activity-dependent GFP Reconstitution Across Synaptic Partners (Syb-GRASP) analysis 37 and found that presynaptic expression of one half of the split-GFP protein (spGFP 1-10 ) in SDGs generated a ladder-like GRASP signal along their entire axons when the other half (spGFP 11 ) was expressed in C4da neurons (Fig. 1e).It is thus likely that SDGs have direct synaptic contacts with C4da axon terminals (Fig. 1f).

SDGs are necessary and sufficient to suppress escape behavior evoked by multimodal noxious stimuli
Next, to examine whether SDGs modulate escape behavior, we hyperpolarized SDGs via expression of the inwardly rectifying potassium channel Kir2.1 while optogenetically stimulating C4da neurons using the red-shifted channelrhodopsin ReaChR.We found that Kir2.1expression by either R16C06-GAL4 (Supplementary Fig. 2a) or SDGs-spGAL4 (Fig. 2a; No-GAL4 control, 1.5 (1.0-2.1)s, n = 14; No-UAS control, 1.8 (1.5-3.0)s, n = 26; SDGs silencing, 12± (7.8-15) s, n = 25; each value indicates median (interquartile range: Q1-Q3) s; Supplementary Fig. 2b and Supplementary Movie 1) significantly prolonged rolling duration compared to control.We further performed optogenetic stimulation of C4da neurons with varying light intensities and found that SDGs-silenced larvae showed significantly higher rolling probabilities compared to genetic controls at all intensities tested, even under dim light conditions where the control group failed to show any response (Fig. 2b).These data suggest that SDGs negatively regulate behavioral sensitivity to noxious stimuli as well as duration of rolling escape behavior.
We further examined whether acute SDGs activation could terminate sustained rolling behavior, which is a key regulatory step for escape behavioral transition from rolling to fast crawling [26][27][28] .Allyl isothiocyanate (AITC), a pungent compound found in cruciferous plants such as wasabi, elicits larval rolling by stimulating TRPA1 channels expressed at the outer body surface including C4da nociceptors 34,42,43 .Once soaked in a high concentration of AITC solution, the control larvae continuously rolled and rarely stopped (Fig. 2h and Supplementary Fig. 2e).Strikingly, larvae expressing CsChrimson in SDGs halted their rolling behaviors in response to the red-light illumination, even after the onset of intense rolling in the AITC solution (Fig. 2h; No-GAL4 control, 15%, n = 20; No-UAS control, 20%, n = 20; SDGs activation, 70%, n = 20).In addition, in a reversed procedure where larvae were first optogenetically stimulated and then treated with AITC, the prior activation of SDGs significantly delayed the onset of nociceptive rolling (Supplementary Fig. 2f), further suggesting that excitation of SDGs leads to rolling termination upon noxious stimuli.These data, together with the silencing/activation results, indicate that SDGs negatively regulate nociceptive rolling to sculp larval escape behavior.

SDGs suppress escape behavior via GABAergic signaling
To gain insights into how SDGs suppress escape responses, we next searched for neurotransmitters expressed in SDGs.Immunohistochemistry of neurotransmitters and related markers revealed that SDGs are all GABA-positive (Fig. 3a and Supplementary Fig. 3a, b).Moreover, the fluorescence marker driven by SDGs-spGAL4 overlapped with another marker simultaneously expressed by glutamate decarboxylase 1 (Gad1; encoding the GABA synthesis enzyme)-LexA (Fig. 3a and Supplementary Fig. 3a, b).Since SDGs were immunoreactive to neither choline acetyltransferase (ChAT) nor vesicular glutamate transporter (VGluT) (Supplementary Fig. 3c), GABA likely serves as the major neurotransmitter in SDGs.
We further aimed to establish the role of GABA signaling in the SDGs-mediated Ca 2+ inhibition in C4da axon terminals.First as expected, bath application of GABA in an ex vivo brain preparation reduced the C4da Ca 2+ response upon optogenetic stimulation (Fig. 4c,  d; without GABA, 42.7 (27.5-49.3)%,n = 16; GABA, 22.7 (14.6-35.4)%,n = 19), suggesting that GABA indeed suppresses C4da activity at axon terminals upon stimulation.Next, we applied the same genetic tools used in the behavioral assays, RNAi and PTX, to examine effects of GABA B receptors on Ca 2+ levels in C4da axon terminals and found that C4da-specific expression of either GABA B -R1 or -R2 RNAi (Fig. 4e ).These physiological data further support the notion that, similar to GABAergic descending neurons in the mammalian brain 15 , SDGs presynaptically gate nociceptive responses of C4da neurons through a GABA signaling pathway, specifically involving the metabotropic GABA B -R1 and -R2 subunits.
Since previous studies showed that GABAergic neurons are activated in response to sensory inputs and presynaptically inhibit sensory neurons though GABA B receptors in Drosophila olfactory and gustatory circuits 48,[52][53][54] , we hypothesized that SDGs might become physiologically activated in response to noxious stimuli, prior to exerting their inhibitory effects on peripheral nociceptors.We investigated this possibility by monitoring Ca 2+ levels of SDGs expressing the Ca 2+ indicator RGECO following optogenetic stimulation of ChR2expressing C4da neurons.We observed a rapid surge in SDGs' Ca 2+ levels upon optogenetic C4da activation, which was absent when larvae were reared without all-trans-retinal (ATR), an obligate ChR2 cofactor (Fig. 4g; No ATR, 11.5 (−25.5-26.1)%,n = 7; ATR, 62.2 (44.0-70.8)%,n = 7), suggesting that C4da activation transiently enhances SDGs activity.These findings, together with the SDGssilencing and -activation experiments, suggest a negative feedback circuit for larval nociceptive outputs: nociceptive stimuli on peripheral C4da neurons lead to SDGs activation, which induces SDGs to send inhibitory inputs back to C4da neurons.

Refeeding in starved larvae suppresses nociceptive responses through SDGs-mediated presynaptic inhibition in C4da neurons
SDGs are located in the SEZ, the brain region that receives multiple sensory inputs and sends out commands to the VNC and motor neurons 55,56 .We thus hypothesized that SDGs might play a role in integrating internal as well as external information into the nociceptive circuits.Inspired by the hierarchical relationship between feeding and nociception in a wide variety of organisms 6-10 , we first asked whether feeding might take precedence over escape behavior in starved larvae.We found that although starvation alone had no detectable effect on nociceptive responses to noxious heat, refeeding of fasted larvae with sucrose significantly increased the latency of thermo-nociceptive responses (Fig. 5a, b; Fed, 2.2 (1.6-2.8)s, n = 44; Starved, 2.1 (1.2-3.4) s, n = 55; Refed, 8.1 (4.5-14) s, n = 44).Similarly, refeeding following starvation significantly reduced rolling probability upon mechanonociceptive stimulation and optogenetic C4da activation (Fig. 5c; Fed, 65%, n = 115; Starved, 57%, n = 116; Refed, 34%, n = 117, and Fig. 5d; Fed, 57%, n = 74; Starved, 54%, n = 80; Refed, 28%, n = 79).These behavioral phenotypes were less likely attributed to general locomotion defects as sugar-refeeding did not affect larval crawling speed (Supplementary Fig. 4a).We thus examined whether SDGs are involved in the sugar refeeding-induced nociceptive suppression in starved larvae.We found that the effects of refeeding on nociceptive responses was largely canceled by silencing SDGs with Kir2.1 expression (Fig. 5e), suggesting that sugar refeeding-induced nociceptive suppression is mainly mediated by SDGs.
A recent study has shown that D-glucose enters a pair of corazonin (Crz)/short neuropeptide F (sNPF) double-positive neurons (named CN neurons) in the fly brain through glucose transporters and that the activated CN neurons trigger glucose-homeostasis responses 36 .Intriguingly, the monosaccharides capable of activating CN neurons, namely D-glucose and D-fructose but not L-glucose, are consistent with the types of monosaccharides capable of extending the rolling latency in refed larvae (Fig. 6a).We thus reasoned that glucose uptake and subsequent activation of CN neurons might be involved in refeeding-induced nociceptive suppression.Administration of phlorizin, a competitive inhibitor of glucose transporters that was shown to inhibit D-glucose-induced CN activation 36  , enabling independent stimulation).These results suggest that the glucose-sensing CN neurons mediate the sugar refeeding-induced nociceptive suppression (Fig. 6i).
We further examined whether the Ilps release from IPCs is required for refeeding-induced nociceptive suppression.To this end, we transiently blocked secretion from IPCs by expressing a temperature-sensitive form of dynamin protein (shibire ts , abbreviated as shi ts ) 59 using insulin-like peptide 2 (ilp2)-GAL4 for temporal silencing of IPCs 36 .Larvae refed under permissive temperature showed prolonged latencies to nociceptive stimuli with no apparent differences between genotypes (Fig. 7b  We next investigated the site of action for the sugar-induced Ilps.One potential scenario is that SDGs directly receive the secreted Ilps from IPCs.Since InR is the sole receptor involved in Drosophila insulin signaling 60 , we asked whether genetic manipulations of InR specifically in SDGs perturb the refeeding-induced nociceptive suppression.We found that expression of a dominant negative form of InR (InR DN ) in SDGs fully suppressed the (Fig. 7c; No-GAL4 control, Fed, 2.5 (1.9-3.9)s, n = 48; Starved, 2.4 (1.5-4.1)s, n = 57; Refed, 6.4 (3.6-11) s, n = 53; InR DN expression in SDGs, Fed, 3.8 (2.3-6.4) s, n = 33; Starved, 3.7 (2.3-7.1)s, n = 38; Refed, 3.0 (2.0-6.9)s, n = 33) and the reduction in rolling probability upon mechanical stimulation (Supplementary Fig. 5a), both after sugar refeeding.Conversely, expression of a constitutively active variant of InR (InR CA ) in SDGs increased rolling latency even under normal food conditions (Fig. 7d; No-GAL4 control, 3.0 (2.0-4.4) s, n = 71; InR CA expression in SDGs, 8.6 (5.5-17) s, n = 68).To avoid potential effects on developmental processes, we next manipulated InR activity for a limited amount of time by using the temperature sensitive variant of GAL80 (a repressor of GAL4) ubiquitously expressed under the tubulin promoter (tub-GAL80 ts ).Since GAL80 cannot bind to split GAL4s, we turned to R16C06-GAL4, the original line found in our screen that cover the neuronal subpopulation including SDGs (Supplementary Fig. 1).For temporal InR inactivation via tub-GAL80 ts , R16C06-GAL4-driven InR DN expression was suppressed by rearing larvae at low temperature (21 °C).Temperature was then Fig. 4 | SDGs mediate presynaptic inhibition of C4da neurons through GABA B receptors.a Ca 2+ imaging during C4da optogenetic stimulation while SDGs were silenced by Kir2.1 expression.ChR2 was activated by blue-light illumination while intracellular Ca 2+ levels were measured by the red-shifted Ca 2+ indicator RGECO.Top, traces of ΔF/F 0 .The thick lines (black, SDGs-spGAL4>+; magenta, SDGs-spGAL4>UAS-Kir2.1) and accompanying shades represent the median and interquartile range, respectively.The blue-shaded box indicates the time window of optogenetic stimulation.Bottom, peak ΔF/F 0 changes.In this and following panels, 'n' indicates the number of biologically independent animals used for each group.Box plots show the median with an interquartile range, and whiskers represent the minimum-to-maximum range.**p < 0.005 (Mann-Whitney U-test).b Ca 2+ imaging of C4da while SDGs were hyperexcited via NaChBac expression.Black, SDGs-spGAL4>+; magenta, SDGs-spGAL4>UAS-NaChBac. *p < 0.05 (Mann-Whitney U-test).c Schematic design of Ca 2+ imaging in C4da.GABA was applied to the buffer 15 min prior to the photo-stimulation and imaging.d-f Traces of ΔF/F 0 (top) and quantified changes in the peak ΔF/F 0 (bottom).The effect of GABA application is shown in d.Black, without GABA application; magenta, with GABA application.For e and f, samples were prepared from larvae expressing either RNAi constructs for GABA B -Rs (e) or PTX (f) in C4da.**p < 0.005, *p < 0.05 (Mann-Whitney U-test with Bonferroni correction).g Left, a schematic of Ca 2+ imaging in SDGs while optogenetically stimulating C4da (top), and representative images of C4da axon terminals from larvae reared with or without ATR, prior to ("Pre") or during ("Stim") the blue-light illumination (bottom).Note that RGECO was expressed in SDGs but not in C4da, which is different from a-f.Right, traces of ΔF/F 0 were measured in larvae reared without ATR (black) or with ATR (magenta).*p < 0.05 (Mann-Whitney Utest).Note that each experiment was carried out under distinct imaging condition optimized for each purpose, as detailed in Supplementary Table 2. See Supplementary Table 1 for full genotypes.Source data are provided as a Source Data file.shifted to 30 °C for GAL80 ts inactivation during the 6-h starvation followed by 1 h of sugar refeeding.As a result, the refed test group showed a shortened latency of thermo-nociceptive rolling compared to the refed no-GAL4 control (Supplementary Fig. 5b).This effect was temperature dependent, as both groups exhibited comparable levels of refeeding-induced extension in rolling latency when larvae were kept constantly at 21 °C (Supplementary Fig. 5b).Similarly for conditional InR activation, larvae harboring UAS-InR CA with tub-GAL80 ts were reared at 21 °C from the day of egg laying to suppress the R16C06-GAL4-driven expression through most of the developmental period.Transiently exposing larvae to 30 °C caused the delay in thermonociceptive rolling onset, whereas rearing them at 21 °C without the temperature shift did not (Supplementary Fig. 5c).Collectively, both chronic and time-restricted manipulations of InR activity in SDGs  These behavioral consequences of InR manipulations led us to conduct Ca 2+ imaging in SDGs, asking whether insulin signaling directly affects their activity levels.In agreement with the behavioral phenotypes, expression of InR DN lowered the Ca 2+ levels of SDGs in sugarrefed larvae (Fig. 7e; No-GAL4 control, Fed, 111 (95.3-130)%, n = 7; Refed, 155 (132-184)%, n = 7; InR DN expression in SDGs, Fed, 117 (63.9-134)%, n = 7; Refed, 86.5 (72.8-97.5)%,n = 7), whereas InR CAexpressing SDGs exhibited a heightened level of basal activity compared to the genetic control, both fed normally without starvation (Fig. 7f; No-GAL4 control, 55.6 (50.7-62.6)%,n = 4; InR CA expression in SDGs, 67.9 (62.1-87.0)%,n = 6).These data consistently suggest that insulin signaling induces sustained activation of SDGs, leading to nociceptive suppression.Taken all together, these data propose a model in which (i) the nutritional homeostatic system signals through the insulin/InR axis to potentiate the neuronal responsiveness of descending SDGs, and subsequently (ii) tipping the balance towards escape termination via GABA/GABA B -Rs-mediated presynaptic inhibition of peripheral C4da sensory neurons (Fig. 8a, b).

Discussion
In this study, we identified SDGs, a cluster of descending GABAergic neurons in the larval brain, that negatively regulate noxious stimulusevoked escape behavior in a context-dependent manner.Upon noxious stimuli, SDGs are transiently activated and provide negative feedback inputs to C4da nociceptive neurons to terminate escape behavior and propel behavioral transition.Furthermore, sugar feeding to starved larvae leads to sustained SDGs activation through the glucose-sensing CN neurons and subsequent insulin signaling, which presynaptically attenuates C4da activity and thereby prioritizes feeding over escape.

GABAergic descending neurons in the larval brain gate nociception through GABA B receptor-mediated presynaptic inhibition
Appropriate implementation of gain control in the first synapse plays an important role in sensory processing.In this study, we identified GABAergic SDGs in the larval brain and showed that SDGs play a critical role in gain control of nociceptive inputs at the presynapses on C4da axons.This notion is supported by the following lines of evidence.First, SDGs project descending axons and form synaptic contacts with C4da axonal terminals in the VNC (Fig. 1).Second, immunochemical studies revealed that SDGs are GABA-and Gad1-positive populations, indicating that SDGs are GABAergic neurons.Indeed, Gad1 RNAi in SDGs dampened their inhibitory modulation on C4da neurons (Fig. 3).Third, GABA A and GABA B receptors are expressed in C4da neurons, and specific blockade of GABA B -Rs, but not GABA A -Rs, in C4da neurons enhances nociceptive responses to multiple noxious stimuli (Fig. 3).Fourth, Ca 2+ imaging revealed that GABAergic inputs attenuate C4da activation-evoked Ca 2+ elevation in C4da presynapses (Fig. 4).Lastly, optogenetic activation of SDGs immediately terminates larval rolling behavior (Fig. 2).
Recent studies in rodents identified multiple populations of descending GABAergic neurons in the brainstem that potentially function in pain control.A subpopulation of dual GABAergic and enkephalinergic (GABA + , Penk + ) neurons project axons onto sensory afferent terminals in the dorsal spinal cord and suppress behavioral sensitivity to both heat and mechanical stimuli 61 .In contrast, GABAergic but not enkephalinergic (GABA + , Penk − ) neurons facilitate mechanical pain by inhibiting local inhibitory neurons in the spinal cord that presynaptically inhibit mechanosensitive primary afferent neurons 62 .Considering the functional and structural characteristics, SDGs in Drosophila might play a role analogous to GABA + , Penk + neurons in rodents.It is also known that GABA B receptors play a critical role in pain control at the spinal cord, as mice lacking GABA B receptors exhibit strong hyperalgesia 63 and a spinally administered GABA B antagonist significantly increases pain responses 64 .Although previous studies suggested multiple roles including presynaptic gating for GABA B receptors in nociceptive circuits 65,66 , underlying mechanisms are not fully understood.Given that SDGs-mediated presynaptic gating in C4da neurons requires GABA B receptors, further studies in the SDGs-C4da circuit might lead to a better understanding of how GABA B receptors mediate gain control in nociceptive neurons.
In addition to GABAergic modulations, nociceptive neurons in mammals receive multiple descending modulatory inputs in the spinal cord including serotonergic and norepinephrinergic inputs from the rostral ventromedial medulla and the locus coeruleus, respectively, which positively and negatively fine-tune nociception 67,68 .How these modulatory inputs are orchestrated to regulate nociception in mammals remains elusive, partially due to the complicated arrangement of the mammalian nociceptive circuit in the spinal cord.Similar to the mammalian nociceptive circuit, the Drosophila larval nociceptive circuit likely receives multiple types of presynaptic modulations at the first synapses, and each modulation seems to regulate nociception in a context-dependent manner.For example, serotonergic inputs on C4da presynapses contribute to experience-dependent reduction of nociceptive sensitivity in developing larvae 34 , whereas neuropeptidergic inputs on C4da presynapses enhance nociceptive responses in mature larvae 35 .The relatively simple structure of the Drosophila nociceptive circuit might provide an ideal system to elucidate how multiple modulatory inputs function coordinatively as well as independently in nociceptive processing.

SDGs-mediated nociceptive gating sculps nociceptive escape behavior
In the stereotyped escape behavior, Drosophila larvae quickly switch their movement from rolling to fast clawing within seconds 26,28,29 .Strikingly, SDGs silencing as well as blockage of GABAergic inputs from SDGs to C4da neurons significantly prolonged the rolling duration compared to control (Fig. 2), indicating that SDGs activity tunes the Fig. 5 | Sugar feeding is prioritized over escape behavior in starved larvae through SDGs-mediated presynaptic inhibition of C4da neurons.a Schematic of the feeding experimental setup.b Thermo-nociceptive responses of larvae after normal feeding, starvation, or starvation followed by refeeding with sucrose.In this and following panels, 'n' indicates the number of biologically independent animals used for each group, and the thick line and the thin error bar represent the median and the interquartile range, respectively.a, b p < 0.0001 (Kruskal-Wallis one-way ANOVA).c Mechano-nociceptive rolling probability of larvae under different nutritive conditions.***p < 0.0005, **p < 0.005 (Fisher's exact test with Bonferroni correction).d Optogenetically induced rolling in larvae under different nutritive states.Channelrhodopsin-expressing C4da neurons were activated by a red-light LED at 8.75 µW/mm 2 .***p < 0.0005, **p < 0.005 (Fisher's exact test with Bonferroni correction).e Rolling latency of larvae in which SDGs were genetically silenced under altered nutritional conditions.**p < 0.005, *p < 0.05, n.s.p ≥ 0.05 (Mann-Whitney U-test with Bonferroni correction).f Neuronal activity of photostimulated C4da neurons under altered feeding conditions, tested either in the wild-type or SDGs-silenced background.The same procedure shown in (a) was applied for larval feeding, prior to the ex vivo sample preparation.g, h Top, traces of ΔF/F 0 .Black, fed; blue, starved; magenta, refed.Note that the blue-shaded box indicates the 3-s optogenetic stimulation time window, starting from 10.5 s and ending at 13.5 s.Bottom, peak ΔF/F 0 changes during the optogenetic stimulation.Box plots indicate the median with the interquartile range, and whiskers represent the minimum-to-maximum range.*p < 0.05, n.s.p ≥ 0.05 (Mann-Whitney U-test with Bonferroni correction).See Supplementary Table 1 for full genotypes.Source data are provided as a Source Data file.
duration of rolling behavior and thus controls orderly transition of escape behaviors.Ca 2+ imaging of SDGs revealed a transient Ca 2+ elevation in SDGs axon terminals in response to C4da activation (Fig. 4).It is thus likely that, in response to noxious stimuli, SDGs are activated by C4da-derived nociceptive signals and then provide negative feedback signals to block C4da synaptic transmission (Fig. 8a).This feedback inhibition should contribute to sculp larval escape behavior by terminating escape rolling immediately after noxious stimuli and thus enabling larvae to propel behavioral transition from rolling to fast crawling at the appropriate moment (Fig. 8a).An important element of this feedback inhibition might be presynaptic GABA B receptors in C4da neurons.GABA B metabotropic receptors are major sites for slow synaptic inhibition in the nervous system, providing an extended time window before suppressing synaptic activity compared to GABA A   In addition to the behavioral transition, SDGs control nociceptive sensitivity, as silencing SDGs sensitized larvae to multiple noxious stimuli (Fig. 2).In the olfactory system, presynaptic gating by GABAergic neurons defines the dynamic range of the olfactory sensitivity and fine-tunes olfactory behavior 48,52 .Similarly, fine-tuning the gain for noxious cues should be important for adjusting an organism's sensitivity to its environments.To maximize chances of survival, animals need to flexibly decide behavioral priorities, especially in natural environments.This form of nociceptive gain control should contribute to a flexible decision making between competitive behaviors such as escape from danger and searching for energy sources.

Glucose-sensing neurons promote sustained SDGs activation through insulin signaling
In this study, we found that sugar refeeding consistently and dramatically attenuates escape behavior to thermal and mechanical insults in larvae (Fig. 5).By contrast, hunger alone showed no significant effect on larval escape behavior (Fig. 5).Similarly, refeeding in mice (2-h feeding after 24-h food deprivation) suppressed both acute and chronic pain 69 , whereas hunger (24-h food deprivation) had less effect on acute pain by thermal, mechanical, and chemical insult while selectively abolishing inflammatory pain responses 70 .It is thus likely that refeeding and hunger have distinct impacts on nociceptive responses in both flies and mammals.
Notably, nutritive sugars such as D-glucose and D-fructose effectively suppressed escape behavior, whereas nonnutritive sugars, L-glucose and arabinose, had no significant analgesic effect in insulted larvae (Fig. 6).This nutritive sugar-specific nociceptive suppression is mediated, at least in part, by the glucose-sensing CN neurons, as CN neurons are selectively activated by nutritive sugars such as D-glucose and D-fructose and inhibited by the glucose transporter antagonist phlorizin 36 .Indeed, both silencing CN neurons by Kir2.1 and phlorizin application significantly attenuated feeding-induced nociceptive suppression (Fig. 6).Given that CN neurons directly innervate IPCs and induce Ilps secretion from IPCs in response to acute elevation of D-glucose levels in hemolymph 36 , it is likely that sugar feeding engages SDGs in nociceptive gating through activation of the sugar-sensing CN neurons in response to acute D-glucose elevation in the brain and subsequent insulin signaling derived from IPCs (Fig. 6).Consistent with this notion, expression of a dominant negative InR in SDGs blocked refeeding-evoked SDGs activity and thus feeding-induced nociceptive suppression, whereas expression of a constitutively active InR upregulated SDGs activity and induced nociceptive suppression even in non-feeding condition (Fig. 7).
Recent studies revealed that insulin and insulin-like growth factor (IGF) have a wide variety of brain functions in vertebrates and invertebrates 71 .In Drosophila, insulin signaling transcriptionally regulates expression levels of sNPF receptors and Tachykinin receptors in particular classes of the olfactory receptor neurons, which facilitates food-searching behavior 72,73 .Similarly, insulin signaling regulates expression levels of multiple neuropeptides in mammalian hypothalamic neurons 74,75 .Recent studies suggest that multiple different types of glucose-sensing neurons exist in the mammalian brain regions including the hypothalamus, amygdala, and brainstem 76 , although their physiological functions in vivo remain largely unknown.It is thus of great interest to investigate whether insulin/IGF signaling and the glucose-sensing neurons might be involved in pain suppression through descending neurons in the mammalian brain.

Fly Strains
Fig. 6 | CN neurons mediate refeeding-induced nociceptive suppression.a Rolling latency in larvae refed with various types of sugars.Each sugar was refed to starved larvae at the same concentration (600 mM).In this and following panels, 'n' indicates the number of biologically independent animals used for each group, and the thick line and the thin error bar represent the median and the interquartile range, respectively.a, b p < 0.0001 (Kruskal-Wallis one-way ANOVA and Dunn's multiple comparison test).b Suppressive effect of phlorizin, the glucose uptake inhibitor, on sugar-dependent rolling modulation.Fasted larvae were refed with either D-glucose or D-fructose, each at two concentrations (60 mM and 600 mM).***p < 0.0005, n.s.p ≥ 0.05 (Mann-Whitney U-test with Bonferroni correction).c Thermo-nociceptive responses of larvae in which CN neurons were chronically silenced by Kir2.1 expression.a, b p < 0.0001 (Kruskal-Wallis one-way ANOVA and Dunn's multiple comparison test).d Effect of CN neurons temporal silencing on the sugar-induced rolling delay.GtACR1-expressing CN neurons were optogenetically inhibited by green light illumination during the 1-h refeeding period, followed by thermo-nociception assay.**p < 0.005, n.s.p ≥ 0.05 (Mann-Whitney U-test with Bonferroni correction).e Thermo-nociceptive responses of larvae in which CN neurons were chronically activated by NachBac expression.***p < 0.0005 (Mann-Whitney U-test with Bonferroni correction).f-h Behavioral and physiological effects of CN neurons temporal activation.Starved larvae expressing CsChrimson in CN neurons were first illuminated with red light for 1 h without refeeding (f).Subsequently, larvae were subjected to either thermo-nociception assay (g) or Ca 2+ imaging in C4da neurons coupled with optogenetic stimulation (h).Black, CN>+; magenta, CN>CsChrimson.Note that CN and C4da neurons expressed different channelrhodopsins (red-light responsive CsChrimson and blue-light responsive ChR2) enabling independent stimulation.Box plots show the median with an interquartile range, and whiskers represent the minimum-tomaximum range.*p < 0.05 (Mann-Whitney U-test).See Supplementary Table 1 for full genotypes.Source data are provided as a Source Data file.i A potential pathway for sugar refeeding-mediated suppression of nociceptive responses.

Behavioral assays
Experiments were performed in a blinded fashion where the experimenter was unaware of larval genotypes.All movies were manually checked frame-by-frame.ImageJ was used to load the movies, saved as avi or multi-tiff files, to observe each frame without any special processing.Manual detection of the rolling occurrence, defined as a "corkscrew-like" behavior in which a larva turned on its long axis more Thermal stimulation.Stage-and density-controlled 3rd instar larvae (96 ± 2 h after egg laying) were prepared as above.Larvae were gently washed with water and placed on the surface-wet agarose plate.The heat probe, set at 46 ± 0.5 °C with a custom-built thermocouple device, was applied to forward-locomoting larvae at mid-abdominal segments (A4-6) until the execution of nociceptive rolling.In case where rolling was not observed for more than 20 s after the probe attachment, the rolling latency was analyzed as 20 s.Movies were recorded under the same conditions as the mechano-nociception assay.
Optogenetic activation/inhibition.Larvae were grown in the standard medium containing 1 mM all-trans-retinal (ATR; R2500, Sigma-Aldrich) at 25 °C.Third-instar wandering larvae were washed with deionized water.Five to ten larvae were then placed at the center of the arena made of 1% agarose.To stimulate red-shifted channelrhodopsins ReaChR and CsChrimson, larvae were exposed to red light (617 nm, 35 µW/mm 2 ).For optogenetic inhibition using the anion channelrhodopsin GtACR1, green light (575 nm, 30 µW/mm 2 ) was applied.Movies were recorded using a CCD-Camera (1500M-GE, Thorlabs) at 2 fps.Rolling duration following the photo-stimulation was measured from initiation to termination of the first roll.
Chemical stimulation.Allyl isothiocyanate (AITC; I0185, Tokyo Chemical Industry) was used as a nociceptive agent.Third-instar wandering larvae were washed with deionized water.Five to ten larvae were placed at the center of a plastic plate with a diameter of 10 cm.The substrate was poured with 500 μl of 500 mM AITC.Red light illumination and movie recordings were conducted under the same conditions as the optogenetic activation experiments.

Ca 2+ imaging
Larvae were reared from eggs on a standard medium containing 1 mM ATR (R2500, Sigma-Aldrich).Third-instar wandering larvae were pinned down on a silicon dish (Silpot 184, Dow Corning Toray) and were dissected along the dorsal midline in either calcium-free HL3.1 buffer 81 (70 mM NaCl, 5 mM KCl, 4 mM MgCl 2 , 10 mM NaHCO 3 , 5 mM trehalose, 115 mM sucrose, 5 mM HEPES, pH 7.2), sugar-free buffer 82 (108 mM NaCl, 5 mM KCl, 8.2 mM MgCl 2 , 4 mM NaHCO 3 , 1 mM NaH 2 PO 4 , 5 mM HEPES, pH 7.5), or sugar-free buffer with GABA (γ-Aminobutyric acid, A2129, Sigma-Aldrich).Note that using the "calcium-free" buffer was key to avoid brain movements due to larval muscle contractions.Internal organs except for neural tissues were removed.Axon terminals of either C4da or SDGs at the A5-6 segments in the VNC were imaged using a microscope (BX51WI, Olympus) equipped with a spinning-disk confocal unit (Yokogawa CSU10, Yokogawa) and an EM-CCD digital camera (Evolve, Photometrics).For activation of C4da neurons expressing the light-gated channelrhodopsin ChR2, blue light with a wavelength of 475 nm and a power of 208 μW/mm 2 was delivered by the pE-300 device (CoolLED).See Supplementary Table 2 for full imaging conditions.Obtained images were analyzed using Metamorph (ver.7.10.4.407 and offline ver.77.5.0,Molecular Devices) and ImageJ (NIH) software.To obtain stable Ca 2+ signals, each image was manually checked and motion correction was applied using the StackReg/TurboReg plugins 83 (available at http://bigwww.epfl.ch/thevenaz/stackreg/)for ImageJ.Four ROIs, each with a diameter of 1 µm per one segment of either side (depicted in the schema of Fig. 1a as the triangle-shaped region of C4da axon terminal), were set.After the mean signal intensity within each ROI was measured using ImageJ, values from 4 ROIs were averaged to represent the data of one brain sample.The number of brain preps (not the number of ROIs) for each genotype/treatment group was shown as (n) within figures.As a baseline, F 0 was calculated by averaging the fluorescent signals for the first 10 s prior to onset of optogenetic stimulation.Calcium transient ΔF/F 0 was calculated by normalizing the raw signal intensity F at each timeframe to F 0 with the following formula: ΔF/F 0 = (F − F 0 )/F 0 .
For Ca 2+ imaging in SDGs, dissection and imaging were performed as above except that ROIs were set on the neurites of SDGs at the A5-6 segments.Signal intensity of the calcium indicator GCaMP (F GCaMP ) and the neurite-labeling CsChrimson::mCherry (F mCherry ) were alternately measured.See Supplementary Tables 1 and 2 for full genotypes and detailed imaging conditions, respectively.

Larval locomotion activity
For Supplementary Fig. 2c, locomotion speed was calculated from the 10-s pre-stimulation windows before the optogenetic activation in Fig. 2a.For Supplementary Fig. 2d, each movie was newly recorded for 10 s to measure the locomotion speed.For Supplementary Fig. 4a, larvae were placed on 2% agarose plates without food source after each nutritional treatment described in Fig. 5a.Movies were recorded for 2 min with the same camera used in optogenetic experiments (see "Optogenetic activation/inhibition" described above), and locomotion speed was measured from the last 10 s of the recorded data.

Transcription-based measurement of neuronal activity
The CaLexA system 58 was applied to measure the activities of CN neurons after sugar refeeding, essentially according to the previous report in adults 36 .Parental CN-GAL4 and the CaLexA reporter lines were crossed, and offspring larvae were reared to third instar.Collected larvae were starved on a water-soaked paper for 12 h and subsequently refed in a 600 mM sucrose vial, as described above.Brains were dissected and the native fluorescence of GFP signals were observed under the confocal microscope.Signal intensity at the cell body was measured by ImageJ.

Temporally-controlled neuronal silencing
Larvae harboring UAS-shibire ts were raised at 22 °C for 5 d (instead of 4 d in normal assays raised at 25 °C) after egg collection.For restrictive temperature treatment, larvae were starved on water-soaked papers at 22 °C for 6 h, followed by a pre-warming step at 31 °C for 30 min.Larvae were then quickly transferred onto either water-or sucrose-soaked papers and were subsequently refed at 31 °C for 2 h.The thermonociception assay was performed as above.

Temporally-controlled manipulation of InR activity
Parental R16C06-GAL4 and either UAS-InR DN ; tub-GAL80 ts or UAS-InR CA ; tub-GAL80 ts lines were mated for 2 d under the standard condition.Parents were then transferred to fresh food vials for egg collection.To increase the yield of offspring, parents were kept at 25 °C (instead of 21 °C) during 9 h of egg laying.Collected embryos were reared at 21 °C to prevent the R16C06-GAL4-driven expression.For temporal InR inactivation, larvae were kept at 21 °C for 5 d (note that it takes additional 1 d to reach the 3rd instar compared to the standard condition at 25 °C) until the last ~7 h preceding behavior assays.Temperature was subsequently shifted to 30 °C, the restrictive temperature for GAL80 ts , from the beginning of the 6-h starvation and through the end of the 1-h sugar refeeding.For conditional InR activation, larvae were reared at 21 °C for 96 h, until the day before the behavior assays.For the following 15 h, larvae underwent an over-night warming at 30 °C to disrupt the GAL80 ts function, thus allowing InR CA expression.After the high-temperature treatments, larvae were briefly washed and immediately tested for thermal nociceptive responses at room temperature.

Statistical analysis
Statistical analyses by Kruskal-Wallis one-way ANOVA, Mann-Whitney U-test, or Fisher's exact test were performed by Prism 9.4.1 (RRID:SCR_002798, GraphPad).All statistical tests were two-sided.Bonferroni correction was applied for multiple comparisons.Asterisks (*) represent p-values as indicated within each figure legend.All data necessary to reproduce the figure panels and statistical analyses are available as Source Data file.

Reporting summary
Further information on research design is available in the Nature Portfolio Reporting Summary linked to this article.
Fig. 2 | SDGs are necessary and sufficient for suppression of C4da-mediated escape behavior.a Rolling duration following optogenetic C4da activation.In this and following panels, 'n' indicates the number of biologically independent animals used for each group, and the thick line and the thin error bar represent the median and interquartile range, respectively.***p < 0.0005 (Mann-Whitney U-test with Bonferroni correction).b Rolling probability of SDGs-silenced larvae in which C4da neurons were optogenetically stimulated under various light intensities.Asterisks indicate statistical differences between the two genotypes at each light intensity.***p < 0.0005, **p < 0.005 (Fisher's exact test).c Effect of SDGs chronic silencing on thermo-nociceptive rolling.***p < 0.0005 (Mann-Whitney U-test with Bonferroni correction).d Effect of SDGs chronic silencing on mechano-nociceptive rolling.A local force of 50 mN was applied twice in rapid succession using the von Frey filament.Rolling probabilities after the second force application are shown.***p < 0.0005 (Fisher's exact test with Bonferroni correction).e Mechanonociceptive rolling of larvae in which SDGs were optogenetically silenced.Top,

Fig. 3 |
Fig. 3 | SDGs negatively control rolling behavior through GABAergic inputs to C4da neurons.a Top, immunohistochemistry of GABA (magenta) at the cell body of SDGs labeled with GFP (green).Bottom, dual detection of GCaMP and CsChrimson::mCherry signals driven by Gad1-LexA (magenta) and SDGs-spGAL4 (green), respectively.Similar results were obtained across 5 independent samples per genotype.b-d Behavioral phenotypes caused by Gad1 knockdown in SDGs.C4da neurons were stimulated by three distinct approaches.For mechanical stimulation (b), rolling probability is shown in the bar graph.Note that the background genotypes of parental flies used in b were different from other experiments; see Supplementary Table1for full genotypes.In this and following panels, 'n' indicates the number of biologically independent animals used for each group, and the thick line and the thin error bar represent the median and interquartile range, respectively.**p < 0.005 (Fisher's exact test).For thermal (c) and optogenetic (d) stimulation, latency and duration are each indicated.***p < 0.0005 (Mann-Whitney U-test).e Colocalization of GFP driven by either GABA B -R1 2A-GAL4 or GABA B -R2 2A-GAL4 (green) with ppk-CD4-tdTomato (magenta) in C4da cell bodies.Similar results were obtained across 4 independent samples per genotype.f, g Nociceptive responses in larvae expressing RNAi constructs targeting each GABA B -R gene in C4da neurons.Rolling probabilities after the mechanical stimulation are shown in the bar graph (f).***p < 0.0005, **p < 0.005 (Fisher's exact test with Bonferroni correction).For optogenetic experiments (g), rolling durations within the 60-s stimulation period are indicated.***p < 0.0005, **p < 0.005 (Mann-Whitney U-test with Bonferroni correction).h Effect of PTX expression on larval rolling induced by optogenetic C4da activation.***p < 0.0005 (Mann-Whitney U-test).See SupplementaryTable 1 for full genotypes.Source data are provided as a Source Data file.

ionotropic receptors 65 .
Although the timescale of C4da synapse activity and the dynamics of GABA release from SDGs require further investigation, GABA B receptors might ensure the translation of transient neural signals into more sustained cellular and behavioral responses across time scales.

Table 1
for full genotypes.Source data are provided as a Source Data file.
Fig. 7 | Insulin signaling in SDGs enhances SDG activity and suppresses escape behavior.aCNneurons-dependentalteration of Ilp2 immunoreactivity in IPCs after sugar refeeding.Left, representative images of larval IPCs stained with the anti-Ilp2 antibody.Right, relative intensities of Ilp2 signals measured within IPCs.In this and following panels, 'n' indicates the number of biologically independent animals used for each group, and the thick line and the thin error bar represent the median and the interquartile range, respectively.***p<0.0005, n.s.Rolling latency of normally fed larvae with artificially enhanced InR activity in SDGs.InR CA , the constitutively activated variant of InR.***p < 0.0005 (Mann-Whitney U-test).e Basal neuronal activity of SDGs expressing the dominant negative InR.Samples were prepared from larvae fed with normal food.Top, traces of F GCaMP /F mCherry , calculated by normalizing the signal intensity of GCaMP with that of CsChrimson::mCherry expressed as a marker.Thick lines and accompanying shades represent the median and the interquartile range, respectively.Black, +>InR DN fed; magenta, +>InR DN refed; gray, SDGs > InR DN fed; blue, SDGs > InR DN refed.Bottom, mean F GCaMP /F mCherry values from the 10-s recording windows.Box plots show the median with an interquartile range, and whiskers represent the minimum-to-maximum range.**p<0.005, n.s.p ≥ 0.05 (Mann-Whitney U-test with Bonferroni correction).fSDGsactivity with enhanced InR functions.Black, +>InR CA ; magenta, SDGs > InR CA .*p<0.05 (Mann-Whitney U-test).See Supplementary Table1for full genotypes.Source data are provided as a Source Data file.
For immunohistochemical analyses, larval brains were washed for 5 times with PBST and were incubated in 5% normal goat serum (NGS)/ PBST or 5% bovine serum albumin (BSA)/PBST (for Ilp2 detection) at room temperature for 2 h.Samples were subsequently incubated at 4 °C overnight with primary antibodies diluted in 5% NGS/PBST or 5% BSA/PBST (for Ilp2 detection).Followed by PBST washes for 5 times, samples were further incubated at 4 °C overnight with secondary antibodies diluted in 5% NGS/PBST or 5% BSA/PBST (for Ilp2 detection).
Presynaptic inhibition by SDGs via GABA signaling.Noxious stimuli first activate the peripheral C4da neurons, followed by subsequent activation of downstream secondary neurons that trigger the onset of larval rolling.During this process of nociceptive information relay, SDGs become activated and in turn send GABAergic inhibitory inputs to C4da neurons via GABA B -Rs.This SDGsmediated negative feedback induces rolling termination with a time lag, which enables behavior transition for efficient escape from danger.bSDGs mediate refeeding-dependent nociceptive suppression via insulin/InR signaling.Ingestion of nutritional sugar stimulates the metabolic neuronal system in the central brain, comprising the glucose-sensing CN neurons and insulin-producing cells (IPCs).Neuronal activities in SDGs, of which cell bodies are located at the SEZ brain region, are subsequently potentiated through the insulin/InR axis.The heightened responsiveness of SDGs enhances the descending inhibitory signals sent to C4da neurons, tipping the balance towards escape termination and feeding prioritization.than90°, was followed by quantification of rolling parameters.Duration and latency were measured based on time stamps extracted from recorded movies using the VLC media player (available at https://www.videolan.org/vlc/index.en_GB.html)with an extension plugin "Time v3.2" (available at https://addons.videolan.org/p/1154032/).