Neuronal Receptors Research Articles

Modulation of the sex pheromone detection by nutritional and hormonal signals in a male insect

As in other animals, insects can modulate their odor-guided behaviors, especially sexual behavior, according to environmental and physiological factors such as the individual's nutritional state. This behavioral flexibility results from modifications of the olfactory pathways under the control of hormones. Most studies have focused on the central modulation of the olfactory system and less attention has been paid to the peripheral olfactory system. To understand how nutritional inputs influence the detection of sex pheromones in insects, we turned to the male moth Agrotis ipsilon for which the behavioral responsiveness to sex pheromones is dependent on diet and reproductive hormones, juvenile hormone (JH) and 20-hydroxyecdysone (20E). We demonstrated that a sugar-rich diet with sodium increases the sensitivity of olfactory receptor neurons to (Z)-7-dodecen-1-yl acetate, the major sex pheromone compound, and the antennal expression of the pheromone binding protein (PBP2) and the pheromone receptor (OR3). Such a diet also induces overexpression of the Methoprene-tolerant receptor to JH and underexpression of the ecdysone receptor to 20E in antennae. The diet-induced olfactory responses were maintained by treatment with Cucurbitacin B, a 20E antagonist, but were suppressed by the topic application of Precocene, a JH biosynthesis inhibitor. These findings reveal that a positive nutritional state enhances the sex pheromone detection through JH actions on the peripheral actors of the pheromone system in male moths. More broadly in insects, our study provides, for the first time, a neuronal and molecular basis of the dietary-dependent endocrine modulation of the peripheral olfactory system.

The astrocytic zinc transporter ZIP12 is a synaptic protein that contributes to synaptic zinc levels in mouse auditory cortex.

Synaptically released zinc is a neuronal signaling system that arises from the actions of the presynaptic vesicular zinc transporter protein ZnT3. Mechanisms that regulate the actions of zinc at synapses are of great importance for many aspects of synaptic signaling in the brain. Here, we identify the astrocytic zinc transporter protein ZIP12 as a candidate mechanism that contributes to zinc clearance at cortical synapses. We identify small molecule compounds that antagonize the function of ZIP12 in heterologous expression systems, and we use one of these compounds, ZiMo12.8, to increase the concentration of ZnT3-dependent zinc at synapses in the brain of male and female mice to inhibit the activity of neuronal AMPA and NMDA glutamate receptors. These results identify a cellular mechanism and provide a pharmacological toolbox to target the molecular machinery that supports the actions of synaptic zinc in the brain.Significance Statement Synaptic zinc is loaded into presynaptic glutamatergic vesicles by the protein zinc transporter 3 (ZnT3), where it is co-released with glutamate during synaptic transmission. Evidence from clinical studies in humans shows that alterations in the expression of the neuronal zinc transporter protein ZnT3 and the astrocytic zinc transporter protein ZIP12 are associated with schizophrenia, suggesting that dysregulation of these brain-specific zinc transporter proteins may contribute altered synaptic signaling in the brain. Our results show that ZIP12 protein is expressed by astrocytes at synapses in the brain. We identify pharmacological agents that inhibit ZIP12 and we use them to modulate zinc levels in the brain. This research advances our understanding of the roles of synaptic zinc in health and disease.

Capillary connections between sensory circumventricular organs and adjacent parenchyma enable local volume transmission.

Among contributors to diffusible signaling are portal systems which join two capillary beds through connecting veins. Portal systems allow diffusible signals to be transported in high concentrations directly from one capillary bed to the other without dilution in the systemic circulation. Two portal systems have been identified in the brain. The first was discovered almost a century ago and connects the median eminence to the anterior pituitary gland. The second was discovered a few years ago and links the suprachiasmatic nucleus to the organum vasculosum of the lamina terminalis, a sensory circumventricular organ (CVO). Sensory CVOs bear neuronal receptors for sensing signals in the fluid milieu. They line the surface of brain ventricles and bear fenestrated capillaries thereby lacking blood-brain barriers. It is not known whether the other sensory CVOs, namely the subfornical organ (SFO), and area postrema (AP) form portal neurovascular connections with nearby parenchymal tissue. To preserve the integrity of the vasculature of CVOs and their adjacent neuropil, we combined iDISCO clearing and light-sheet microscopy to acquire volumetric images of blood vessels and traced the vasculature in two experiments. In the first, the whole brain vasculature was registered to the Allen Brain Atlas in order to identify the nuclei to which the SFO and AP are attached. In the second study, regionally specified immunolabeling was used to identify the attachment sites and vascular connections between the AP, and the SFO to their respective parenchymal attachment sites. There are venous portal pathways linking the capillary vessels of the SFO and the posterior septal nuclei, namely the septofimbrial nucleus and the triangular nucleus of the septum. Unlike the arrangement of portal vessels, the AP and the nucleus of the solitary tract share a common capillary bed. Taken together, the results reveal that all three sensory CVOs bear direct capillary connections to adjacent neuropil, providing a direct route for diffusible signals to travel from their source to their targets.

Deficiency of histamine H2 receptors in parvalbumin-positive neurons leads to hyperactivity, impulsivity, and impaired attention.

Attention deficit hyperactivity disorder (ADHD), affecting 4% of the population, is characterized by inattention, hyperactivity, and impulsivity; however, its neurophysiological mechanisms remain unclear. Here, we discovered that deficiency of histamine H2 receptor (H2R) in parvalbumin-positive neurons in substantia nigra pars recticulata (PVSNr) attenuates PV+ neuronal activity and induces hyperactivity, impulsivity, and inattention in mice. Moreover, decreased H2R expression was observed in PVSNr in patients with ADHD symptoms and dopamine-transporter-deficient mice, whose behavioral phenotypes were alleviated by H2R agonist treatment. Dysfunction of PVSNr efferents to the substantia nigra pars compacta dopaminergic neurons and superior colliculus differently contributes to H2R-deficiency-induced behavioral disorders. Collectively, our results demonstrate that H2R deficiency in PV+ neurons contributes to hyperactivity, impulsivity, and inattention by dampening PVSNr activity and involving different efferents in mice. It may enhance understanding of the molecular and circuit-level basis of ADHD and afford new potential therapeutic targets for ADHD-like psychiatric diseases.

Cholesterol metabolites modulate ionotropic P2X4 and P2X7 receptor current in microglia cells.

The central nervous system is a well-known steroidogenic tissue producing, among others, cholesterol metabolites such as neuroactive steroids, oxysterols and steroid hormones. It is well known that these endogenous molecules affect several receptor classes, including ionotropic GABAergic and NMDA glutamatergic receptors in neurons. It has been shown that also ionotropic purinergic (P2X) receptors are cholesterol metabolites' targets. Among P2X receptors, purinergic P2X4 and P2X7 receptors are expressed in microglia, the innate immune cells involved in the brain inflammatory response. In this study, we explore the ionotropic purinergic receptors modulation by cholesterol metabolites in microglia. Patch-clamp experiments were performed in BV2 cells, a murine microglia cell line, to evaluate effects of cholesterol metabolites using micro- and nanomolar concentrations. About P2X4 receptor, we found that testosterone butyrate (20μM and 200nM) and allopregnanolone (10μM and 100nM) both potentiated its current, while neither 25-hydroxycholesterol (10μM and 100nM) nor 17β-estradiol (1μM) showed any effects. On the other hand, P2X7 receptor current was potentiated by allopregnanolone (10μM) and 25-hydroxycholesterol (10μM and 100nM). Taken together, our data show that modulation of either P2X4 and P2X7 current is affected differently by cholesterol metabolites, suggesting a structure-activity relationship among these players. Identifying the possible link between purinergic transmission, microglia and cholesterol metabolites will allow to define new targets for drug development to treat neuroinflammation.

Cannabinoid type-1 receptors in CaMKII neurons drive impulsivity in pathological eating behavior.

Overconsumption of palatable food and energy accumulation are evolutionary mechanisms of survival when food is scarce. This innate mechanism becomes detrimental in obesogenic environment promoting obesity and related comorbidities, including mood disorders. The endocannabinoid system favors energy accumulation and regulates reward circuits. We applied a genetic strategy to reconstitute cannabinoid type-1 receptor (CB1) expression at functional levels specifically in CaMKII+neurons (CaMKII-CB1-RS) and adipocytes (Ati-CB1-RS), respectively, in a CB1 deficient background. Rescued CB1 expression in CaMKII+neurons, but not in adipocytes, promotes feeding behavior, leading to fasting-induced hyperphagia, increased motivation, and impulsivity to palatable food seeking. In a diet-induced obesity model, CB1 re-expression in CaMKII+neurons, but not in adipocytes, compared to complete CB1 deficiency, was sufficient to largely restore weight gain, food intake without any effect on glucose intolerance associated with high-fat diet consumption. In a model of glucocorticoid-mediated metabolic syndrome, CaMKII-CB1-RS mice showed all metabolic alterations linked to the human metabolic syndrome except of glucose intolerance. In a binge-eating model mimicking human pathological feeding, CaMKII-CB1-RS mice showed increased seeking and compulsive behavior to palatable food, suggesting crucial roles in foraging and an enhanced susceptibility to addictive-like eating behaviors. Importantly, other contingent behaviors, including increased cognitive flexibility and reduced anxiety-like behaviors, but not depressive-like behaviors, were also observed. To sum up, CB1 in CaMKII+neurons is instrumental in feeding behavior and energy storage under physiological conditions. The exposure to risk factors (hypercaloric diet, glucocorticoid dysregulation) leads to obesity, metabolic syndrome, binge-eating and food addiction.

Membrane tension sensing formin-binding protein 1 is a neuronal nutrient stress-responsive Golgiphagy receptor.

Nutrient stress-responsive neuronal homeostasis relies on intricate autophagic mechanisms that modulate various organelle integrity and function. The selective autophagy of the Golgi, known as Golgiphagy, regulates secretory processes by modulating vesicle trafficking during nutrient starvation. In this study, we explored a genetic screen of BAR-domain-containing proteins to elucidate the role of formin-binding protein 1 (FNBP1) as a Golgiphagy receptor in modulating Golgi dynamics in response to varying nutrient availability in neurons. Mapping the systems network of FNBP1 and its interacting proteins reveals the putative involvement of FNBP1 in autophagy and Golgi-associated processes. While nutrient depletion causes Golgi fragmentation, FNBP1 preferentially localizes to the fragmented Golgi membrane through its 284FEDYTQ289 motif during nutrient stress. Simultaneously, FNBP1 engages in molecular interactions with LC3B through a conserved 131WKQL134 LC3 interacting region, thereby sequestering the fragmented Golgi membrane in neuronal autophagosomes. Increased aggregation of GM130, abnormal clumping of RAB11-positive secretory granules, and enhanced senescent death of FNBP1-depleted starved neurons indicate disruptions of neuronal homeostasis under metabolic stress. The identification of FNBP1 as a nutrient stress-responsive Golgiphagy receptor expands our insights into the molecular mechanisms underlying Golgiphagy, establishing the crosstalk between nutrient sensing and membrane tension-sensing regulatory autophagic processes of Golgi turnover in neurons.

Neuronal TRPV1-CGRP axis regulates peripheral nerve regeneration through ERK/HIF-1 signaling pathway.

Severe trauma frequently leads to nerve damage. Peripheral nerves possess a degree of regenerative ability, and actively promoting their recovery can help restore the sensory and functional capacities of tissues. The neuropeptide calcitonin gene-related peptide (CGRP) is believed to regulate the repair of injured peripheral nerves, with neuronal transient receptor potential vanilloid type 1 (TRPV1) potentially serving as a crucial upstream factor. In this study, we established a mouse model of sciatic nerve (SN) crush injury and found that intrathecal injection of capsaicin (Cap) activated the neuronal TRPV1-CGRP axis, thereby promoting SN repair. Conversely, the application of capsazepine (Cpz), which inhibits the neuronal TRPV1-CGRP axis, delayed SN repair. Local restoration of CGRP expression at the injury site enhanced the repair process. Invitro experiments, we employed the rat Schwann cell (SC) line RSC96 to establish an indirect co-culture model of neurons and SCs. We observed that the proliferation, migration, expression of myelination-associated proteins, and neurotrophic secretion functions of RSC96 cells are positively correlated with the degree of activation of neuronal TRPV1. Inhibition of neuronal TRPV1, followed by the restoration of CGRP levels, improved these functions in RSC96 cells. Furthermore, activation of the neuronal TRPV1-CGRP axis resulted in an upregulation of extracellular signal-regulated kinases 1/2 (ERK1/2) phosphorylation levels and an increase in hypoxia-inducible factor 1α (HIF-1α) accumulation in RSC96 cells, thereby promoting their proliferation and migration. In summary, this study demonstrates that neuronal TRPV1-CGRP axis can regulate biological behavior of SCs and axon regeneration by activating the ERK/HIF-1 signaling pathway following peripheral nerve injury. This finding clarifies the role of CGRP in neuroregulatory networks and provides a novel reference point for the development of drugs and biomaterials for treating nerve damage.

Quantifying spectral information about source separation in multisource odour plumes.

Odours released by objects in natural environments can contain information about their spatial locations. In particular, the correlation of odour concentration timeseries produced by two spatially separated sources contains information about the distance between the sources. For example, mice are able to distinguish correlated and anti-correlated odour fluctuations at frequencies up to 40 Hz, while insect olfactory receptor neurons can resolve fluctuations exceeding 100 Hz. Can this high-frequency acuity support odour source localization? Here we answer this question by quantifying the spatial information about source separation contained in the spectral constituents of correlations. We used computational fluid dynamics simulations of multisource plumes in two-dimensional chaotic flow environments to generate temporally complex, covarying odour concentration fields. By relating the correlation of these fields to the spectral decompositions of the associated odour concentration timeseries, and making simplifying assumptions about the statistics of these decompositions, we derived analytic expressions for the Fisher information contained in the spectral components of the correlations about source separation. We computed the Fisher information for a broad range of frequencies and source separations for three different source arrangements and found that high frequencies were more informative than low frequencies when sources were close relative to the sizes of the large eddies in the flow. We observed a qualitatively similar effect in an independent set of simulations with different geometry, but not for surrogate data with a similar power spectrum to our simulations but in which all frequencies were a priori equally informative. Our work suggests that the high-frequency acuity of olfactory systems may support high-resolution spatial localization of odour sources. We also provide a model of the distribution of the spectral components of correlations that is accurate over a broad range of frequencies and source separations. More broadly, our work establishes an approach for the quantification of the spatial information in odour concentration timeseries.

Recent odor experience selectively modulates olfactory sensitivity across the glomerular output in the mouse olfactory bulb.

Although animals can reliably locate and recognize odorants embedded in complex environments, the neural circuits for accomplishing these tasks remain incompletely understood. Adaptation is likely to be important as it could allow neurons in a brain area to adjust to the broader sensory environment. Adaptive processes must be flexible enough to allow the brain to make dynamic adjustments, while maintaining sufficient stability so that organisms do not forget important olfactory associations. Processing within the mouse olfactory bulb is likely involved in generating adaptation, although there are conflicting models of how it transforms the glomerular output of the mouse olfactory bulb. Here we performed 2-photon Ca2+ imaging from mitral/tufted glomeruli in awake mice to determine the time course of recovery from adaptation, and whether it acts broadly or selectively across the glomerular population. Individual glomerular responses, as well as the overall population odor representation was similar across imaging sessions. However, odor-concentration pairings presented with interstimulus intervals upwards of 30-s evoked heterogeneous adaptation that was concentration-dependent. We demonstrate that this form of adaptation is unrelated to variations in respiration, and olfactory receptor neuron glomerular measurements indicate that it is unlikely to be inherited from the periphery. Our results indicate that the olfactory bulb output can reliably transmit stable odor representations, but recent odor experiences can selectively shape neural responsiveness for upwards of 30 seconds. We propose that neural circuits that allow for non-uniform adaptation across mitral/tufted glomerular could be important for making dynamic adjustments in complex odor environments.

Microglia‐Derived Vitamin D Binding Protein Mediates Synaptic Damage and Induces Depression by Binding to the Neuronal Receptor Megalin

AbstractVitamin D binding protein (VDBP) is a potential biomarker of major depressive disorder (MDD). This study demonstrates for the first time that VDBP is highly expressed in core emotion‐related brain regions of mice susceptible to chronic unpredictable mild stress (CUMS). Specifically, the overexpression of microglia (MG)‐derived VDBP in the prelimbic leads to depression‐like behavior and aggravates CUMS‐induced depressive phenotypes in mice, whereas conditional knockout of MG‐derived VDBP can reverse both neuronal damage and depression‐like behaviors. Mechanistically, the binding of MG‐derived VDBP with the neuronal receptor megalin mediates the downstream SRC signaling pathway, leading to neuronal and synaptic damage and depression‐like behaviors. These events may be caused by biased activation of inhibitory neurons and excitatory–inhibitory imbalance. Importantly, this study has effectively identified MG‐derived VDBP as a pivotal mediator in the interplay between microglia and neurons via its interaction with the neuronal receptor megalin and intricate downstream impacts on neuronal functions, thus offering a promising therapeutic target for MDD.

Anatomy and histology of the olfactory organ of the javelin goby Synechogobius hasta (Gobiiformes, Gobiidae)

The olfactory organ of Synechogobius hasta was investigated with a focus on its environmental adaptation, using stereo microscopy and light microscopy. This research revealed the following anatomical and histological characteristics: (i) tubular anterior nostril, (ii) one longitudinal lamella, (iii) two accessory nasal sacs, (iv) lymphatic cells in the lower part of the sensory epithelium, (v) four to five villi of olfactory receptor neurons, (vi) abundant blood capillaries beneath the sensory epithelium, and (vii) rod-shaped erythrocytes. These findings hint that the olfactory organ of S. hasta has anatomical and histological adaptations to intertidal pools that undergo periodic hypoxia and increased temperature under stagnant water conditions due to the tidal cycle.

Perceptual constancy for an odor is acquired through changes in primary sensory neurons.

The ability to consistently recognize an object despite variable sensory input is termed perceptual constancy. This ability is not innate; rather, it develops with experience early in life. We show that, when mice are naïve to an odor object, perceptual constancy is absent across increasing concentrations. The perceptual change coincides with a rapid reduction in activity from a single olfactory receptor channel that is most sensitive to the odor. This drop in activity is not a property of circuit interactions within the olfactory bulb; instead, it is due to a sensitivity mismatch of olfactory receptor neurons within the nose. We show that, after forming an association of this odor with food, the sensitivity of the receptor channel is matched to the odor object, preventing transmission failure and promoting perceptual stability. These data show that plasticity of the primary sensory organ enables learning of perceptual constancy.

Pharyngeal neuronal mechanisms governing sour taste perception in Drosophila melanogaster.

Sour taste, which is elicited by low pH, may serve to help animals distinguish appetitive from potentially harmful food sources. In all species studied to date, the attractiveness of oral acids is contingent on concentration. Many carboxylic acids are attractive at ecologically relevant concentrations but become aversive beyond some maximal concentration. Recent work found that Drosophila ionotropic receptors IR25a and IR76b expressed by sweet-responsive gustatory receptor neurons (GRNs) in the labellum, a peripheral gustatory organ, mediate appetitive feeding behaviors toward dilute carboxylic acids. Here, we disclose the existence of pharyngeal sensors in Drosophila melanogaster that detect ingested carboxylic acids and are also involved in the appetitive responses to carboxylic acids. These pharyngeal sensors rely on IR51b, IR94a, and IR94h, together with IR25a and IR76b, to drive responses to carboxylic acids. We then demonstrate that optogenetic activation of either Ir94a+ or Ir94h+ GRNs promotes an appetitive feeding response, confirming their contributions to appetitive feeding behavior. Our discovery of internal pharyngeal sour taste receptors opens up new avenues for investigating the internal sensation of tastants in insects.

Pharyngeal neuronal mechanisms governing sour taste perception in Drosophila melanogaster

Sour taste, which is elicited by low pH, may serve to help animals distinguish appetitive from potentially harmful food sources. In all species studied to date, the attractiveness of oral acids is contingent on concentration. Many carboxylic acids are attractive at ecologically relevant concentrations but become aversive beyond some maximal concentration. Recent work found that Drosophila ionotropic receptors IR25a and IR76b expressed by sweet-responsive gustatory receptor neurons (GRNs) in the labellum, a peripheral gustatory organ, mediate appetitive feeding behaviors toward dilute carboxylic acids. Here, we disclose the existence of pharyngeal sensors in Drosophila melanogaster that detect ingested carboxylic acids and are also involved in the appetitive responses to carboxylic acids. These pharyngeal sensors rely on IR51b, IR94a, and IR94h, together with IR25a and IR76b, to drive responses to carboxylic acids. We then demonstrate that optogenetic activation of either Ir94a+ or Ir94h+ GRNs promotes an appetitive feeding response, confirming their contributions to appetitive feeding behavior. Our discovery of internal pharyngeal sour taste receptors opens up new avenues for investigating the internal sensation of tastants in insects.

A genome-wide association study implicates the olfactory system in Drosophila melanogaster diapause-associated lifespan extension and fecundity.

The effects of environmental stress on animal life are gaining importance with climate change. Diapause is a dormancy program that occurs in response to an adverse environment, followed by resumption of development and reproduction upon the return of favorable conditions. Diapause is a complex trait, so we leveraged the Drosophila genetic reference panel (DGRP) lines and conducted a Genome-Wide Association Study (GWAS) to characterize the genetic basis of diapause. We assessed post-diapause and non-diapause fecundity across 193 DGRP lines. GWAS revealed 546 genetic variants, encompassing single nucleotide polymorphisms, insertions and deletions associated with post-diapause fecundity. We identified 291 candidate diapause-associated genes, 40 of which had previously been associated with diapause, and 89 of which were associated with more than one SNP. Gene network analysis indicated that the diapause-associated genes were primarily linked to neuronal and reproductive system development. Similarly, comparison with results from other fly GWAS revealed the greatest overlap with olfactory-behavior-associated and fecundity-and-lifespan-associated genes. An RNAi screen of selected candidates identified two neuronal genes, Dip-𝛾 and Scribbler, to be required during recovery for post-diapause fecundity. We complemented the genetic analysis with a test of which neurons are required for successful diapause. We found that although amputation of the antenna had little to no effect on non-diapause lifespan, it reduced diapause lifespan and postdiapause fecundity. We further show that olfactory receptor neurons and temperature-sensing neurons are required for successful recovery from diapause. Our results provide insights into the molecular, cellular, and genetic basis of adult reproductive diapause in Drosophila .

Editor's view: Is the brain's perception of ideas an underappreciated human sense?

Humans have developed sensory organs for their 'major' senses and specific neuronal receptors for a number of additional senses. Although information from sensors is integrated and processed in the brain, the brain itself has not been proposed as a sensory organ associated with a particular sense - at least not in Western culture or scientific literature. Perception of ideas has many elements of a separate sense, with the brain being a primary sensory organ. I support this notion based on 17 years of experience in the application of the Child Health and Nutrition Research Initiative (CHNRI) method for setting research priorities, which resulted in more than 150 publications involving thousands of experts who prioritised more than 20 000 research ideas. This body of work allows for the generalisation of the following key concepts: defining an idea in the context of the brain's sensory perception; defining the point of origin, sensory qualities, and common types of ideas; considering responses of the body to the brain's sensory exposure to ideas; and defining the key criteria that the brain uses to discriminate between and prioritise ideas. The human brain is continuously being exposed to ideas, which can be self-generated, triggered by information from other sensors, or introduced from the external world. From the brain's sensory perspective, ideas are competing possibilities of purposeful activities that, if followed, would be expected to result in an alternative version of the future. Pursuing ideas tends to drive most of human activity. It requires prioritising between short-, mid-, and long-term investment of energy and time. The brain's sensory role is to continuously assess many competing ideas and prioritise between them based on motivational/emotional ('attractiveness'), operational/rational ('feasibility') and outcome-related perspective ('impact'). Exposure to new ideas may instigate physiological and psychological responses, ranging from enthusiasm and excitement to feeling a threat or fear. Ideas can be used to mobilise large groups of people whose brains respond with excessive enthusiasm that can sometimes be fanatical. The judgment on the attractiveness, feasibility, and potential impact of ideas is affected by education, experience, and cognitive abilities. This sense may be sharpened through an increased level of expert knowledge and experience. Misinformation and disinformation are dangerous because they affect the brain's perception of ideas. Impairment of this inherent sense may perhaps contribute to some mental health issues. The proposed view of the brain as the sensor of ideas could lead to many qualitative or quantitative experiments to further explore the properties of this sense in both individuals and populations, establishing 'the science of ideas'.

Metaxin-2 tunes mitochondrial transportation and neuronal function in Drosophila.

Metaxins are a family of evolutionarily conserved proteins that reside on the mitochondria outer membrane (MOM) and participate in the protein import into the mitochondria. Metaxin-2 (Mtx2), a member of this family, has been identified as a key component in the machinery for mitochondrial transport in both C. elegans and human neurons. To deepen our understanding of Mtx2's role in neurons, we examined the homologous genes CG5662 and CG8004 in Drosophila. The CG5662 is a non-essential gene while CG8004 null mutants die at late pupal stages. The CG8004 protein is widely expressed throughout the Drosophila nervous system and is targeted to mitochondria. However, neuronal CG8004 is dispensable for animal survival and is partially required for mitochondrial distribution in certain neuropil regions. Conditional knockout of CG8004 in adult gustatory receptor neurons (GRNs) impairs mitochondrial trafficking along GRN axons and diminishes the mitochondrial quantities in axon terminals. The absence of CG8004 also leads to mitochondrial fragmentation within GRN axons, a phenomenon that may be linked to mitochondrial transport through its genetic interaction with the fusion proteins Marf and Opa1. While the removal of neuronal CG8004 is not lethal during the developmental stage, it does have consequences for the lifespan and healthspan of adult Drosophila. At last, double knockout (KO) of CG5662 and CG8004 shows similar phenotypes as the CG8004 single KO, suggesting that CG5662 does not compensate for the loss of CG8004. In summary, our findings suggest that CG8004 plays a conserved and context-dependent role in axonal mitochondrial transport, as well it is important for sustaining neuronal function. Therefore, we refer to CG8004 as the Drosophila Metaxin-2 (dMtx2).

GluN2D-containing NMDA receptors in parvalbumin neurons in the nucleus accumbens regulate nocifensive responses in neuropathic pain.

Neuropathic pain presents a significant challenge, with its underlying mechanisms still not fully understood. Here, we investigated the role of GluN2C- and GluN2D-containing NMDA receptors in the development of neuropathic pain induced by cisplatin, a widely used chemotherapeutic agent. Through genetic and pharmacological strategies, we found that GluN2D-containing NMDA receptors play a targeted role in regulating cisplatin-induced neuropathic pain (CINP), while sparing inflammatory or acute pain responses. Specifically, both GluN2D knockout (KO) mice and pharmacological blockade of GluN2D-containing receptors produced robust reduction in mechanical nocifensive response in CINP. In contrast, GluN2C KO mice behaved similar to wildtype mice in CINP but showed reduced mechanical hypersensitivity in inflammatory pain. Using conditional KO strategy, we addressed the region- and cell-type involved in GluN2D-mediated changes in CINP. Animals with conditional deletion of GluN2D receptors from parvalbumin interneurons (PVIs) or local ablation of GluN2D from nucleus accumbens (NAc) displayed reduced mechanical hypersensitivity in CINP, underscoring the pivotal role of accumbal GluN2D in PVIs in neuropathic pain. Furthermore, CINP increased excitatory neurotransmission in the NAc in wildtype mice and this effect is dampened in PV-GluN2D KO mice. Other changes in CINP in NAc included an increase in vGluT1 and c-fos labeled neurons in wildtype which were absent in PV-GluN2D KO mice. GiDREADD-induced inhibition of PVIs in the NAc produced reduction in mechanical hypersensitivity in CINP. These findings unveil a novel cell-type and region-specific role of GluN2D-containing NMDA receptors in neuropathic pain and identify PVIs in NAc as a novel mediator of pain behaviors.

Probiotics-sensing mechanism in neurons that initiates gut mitochondrial surveillance for pathogen defense

Animals constantly face microbial challenges, and microbe-mediated infection protection is crucial for host survival. Identifying specific bacteria and their interactions with host intracellular surveillance systems is important but challenging. Here, we develop a "probiotics" screening system that identifies Escherichia coli mutants, such as ΔymcB, which protect hosts from Pseudomonas aeruginosa PA14 infection by activating the mitochondrial unfolded protein response (UPRmt). Genetic screening reveals that MDSS-1, a neuronal transmembrane protein, is crucial for sensing ΔymcB and triggering intestinal UPRmt. MDSS-1 functions as a potential receptor in ASE neurons, detecting ΔymcB and transmitting signals through neuropeptides, GPCRs, Wnt signaling, and endopeptidase inhibitors to activate intestinal UPRmt and enhance protection. Constitutive activation of MDSS-1 in ASE neurons is sufficient to induce UPRmt and confer infection resistance. This study uncovers a neuron-intestine communication mechanism, where ASE neurons detect bacteria and modulate the intestinal mitochondrial surveillance system for host adaptation to pathogens.