ABSTRACT
Sensory circuits in the dorsal spinal cord integrate and transmit multiple cutaneous sensory modalities including the sense of light touch. Here, we identify a population of excitatory interneurons (INs) in the dorsal horn that are important for transmitting innocuous light touch sensation. These neurons express the ROR alpha (RORα) nuclear orphan receptor and are selectively innervated by cutaneous low threshold mechanoreceptors (LTMs). Targeted removal of RORα INs in the dorsal spinal cord leads to a marked reduction in behavioral responsiveness to light touch without affecting responses to noxious and itch stimuli. RORα IN-deficient mice also display a selective deficit in corrective foot movements. This phenotype, together with our demonstration that the RORα INs are innervated by corticospinal and vestibulospinal projection neurons, argues that the RORα INs direct corrective reflex movements by integrating touch information with descending motor commands from the cortex and cerebellum.
Subject(s)
Mechanotransduction, Cellular , Neural Pathways , Spinal Cord Dorsal Horn/metabolism , Touch , Animals , Interneurons/metabolism , Mice , Motor Activity , Motor Neurons/metabolism , Nuclear Receptor Subfamily 1, Group F, Member 1/metabolism , Spinal Cord Dorsal Horn/cytology , SynapsesABSTRACT
Pain information processing in the spinal cord has been postulated to rely on nociceptive transmission (T) neurons receiving inputs from nociceptors and Aß mechanoreceptors, with Aß inputs gated through feed-forward activation of spinal inhibitory neurons (INs). Here, we used intersectional genetic manipulations to identify these critical components of pain transduction. Marking and ablating six populations of spinal excitatory and inhibitory neurons, coupled with behavioral and electrophysiological analysis, showed that excitatory neurons expressing somatostatin (SOM) include T-type cells, whose ablation causes loss of mechanical pain. Inhibitory neurons marked by the expression of dynorphin (Dyn) represent INs, which are necessary to gate Aß fibers from activating SOM(+) neurons to evoke pain. Therefore, peripheral mechanical nociceptors and Aß mechanoreceptors, together with spinal SOM(+) excitatory and Dyn(+) inhibitory neurons, form a microcircuit that transmits and gates mechanical pain. PAPERCLIP:
Subject(s)
Neurons/physiology , Pain/metabolism , Spinal Cord/physiology , Animals , Dynorphins/metabolism , Mechanoreceptors/metabolism , Mice , Pain Perception , Somatostatin/metabolismABSTRACT
BMP activity is essential for many steps of neural development, including the initial role in neural induction and the control of progenitor identities along the dorsal-ventral axis of the neural tube. Taking advantage of chick in ovo electroporation, we show a novel role for BMP7 at the time of neurogenesis initiation in the spinal cord. Using in vivo loss-of-function experiments, we show that BMP7 activity is required for the generation of three discrete subpopulations of dorsal interneurons: dI1-dI3-dI5. Analysis of the BMP7 mouse mutant shows the conservation of this activity in mammals. Furthermore, this BMP7 activity appears to be mediated by the canonical Smad pathway, as we demonstrate that Smad1 and Smad5 activities are similarly required for the generation of dI1-dI3-dI5. Moreover, we show that this role is independent of the patterned expression of progenitor proteins in the dorsal spinal cord, but depends on the BMP/Smad regulation of specific proneural proteins, thus narrowing this BMP7 activity to the time of neurogenesis. Together, these data establish a novel role for BMP7 in primary neurogenesis, the process by which a neural progenitor exits the cell cycle and enters the terminal differentiation pathway.
Subject(s)
Bone Morphogenetic Protein 7/metabolism , Interneurons/physiology , Neurogenesis/physiology , Signal Transduction/physiology , Smad Proteins, Receptor-Regulated/metabolism , Spinal Cord/embryology , Analysis of Variance , Animals , Chick Embryo , Immunohistochemistry , In Situ Hybridization , Interneurons/metabolism , Luciferases , Mice , Mutation/genetics , Neurogenesis/genetics , Real-Time Polymerase Chain Reaction , Reverse Transcriptase Polymerase Chain Reaction , Smad Proteins, Receptor-Regulated/geneticsABSTRACT
Ille C. Gebeshuber is Professor of Physics at the Institute of Applied Physics at the Vienna University of Technology, Austria, where she graduated and completed her Ph.D. on technical biophysics of the inner ear in 1998. In 1999, she undertook postdoctoral training in scanning probe microscopy and biomimetics at the University of California, Santa Barbara, CA, USA, and soon after she returned to Austria to her home university to work on ion surface interactions, tribology and (bio-)nanotechnology. From 2009 to 2015, she joined the Institute of Microengineering and Nanoelectronics at the National University of Malaysia. During her expeditions, together with her students from cultural diverse backgrounds and expertise, she learned from the rainforest how nature develops well-adapted structures and materials, inspiring her to apply these principles to solve technological problems for humans to face global challenges in a safe and sustainable way. Her research focuses on nanotechnology and biomimetics, and takes a multidisciplinary approach, from biology and engineering to the fine arts and the social sciences. In 2017, she was elected Austrian of the Year in the "Research" category. We asked Ille about her career, her thoughts about the potential of biomimetic nanotechnology, and her experience during her editorship with Biomimetics.
ABSTRACT
Next Generation is a series of interviews with the awardees of the Biomimetics Travel Awards aimed at supporting early-career researchers and helping them promote their work. Sébastien R. Mouchet is a postdoctoral fellow in the Natural Photonics group led by Prof. Pete Vukusic at the University of Exeter, UK, working in collaboration with his former Ph.D. supervisor, Prof. Olivier Deparis, at the University of Namur, Belgium. His research focuses on fluorescence emission and coloration changes in photonic structures of insects induced by contact with fluids aiming to develop bioinspired technological solutions for chemical sensing and biosensing.
ABSTRACT
Mechanical hypersensitivity is a debilitating symptom for millions of chronic pain patients. It exists in distinct forms, including brush-evoked dynamic and filament-evoked punctate hypersensitivities. We reduced dynamic mechanical hypersensitivity induced by nerve injury or inflammation in mice by ablating a group of adult spinal neurons defined by developmental co-expression of VGLUT3 and Lbx1 (VT3Lbx1 neurons): the mice lost brush-evoked nocifensive responses and conditional place aversion. Electrophysiological recordings show that VT3Lbx1 neurons form morphine-resistant polysynaptic pathways relaying inputs from low-threshold Aß mechanoreceptors to lamina I output neurons. The subset of somatostatin-lineage neurons preserved in VT3Lbx1-neuron-ablated mice is largely sufficient to mediate morphine-sensitive and morphine-resistant forms of von Frey filament-evoked punctate mechanical hypersensitivity. Furthermore, acute silencing of VT3Lbx1 neurons attenuated pre-established dynamic mechanical hypersensitivity induced by nerve injury, suggesting that these neurons may be a cellular target for treating this form of neuropathic pain.
Subject(s)
Amino Acid Transport Systems, Acidic/physiology , Neurons/physiology , Spinal Cord/physiology , Touch/physiology , Action Potentials/drug effects , Action Potentials/physiology , Amino Acid Transport Systems, Acidic/biosynthesis , Amino Acid Transport Systems, Acidic/genetics , Animals , Avoidance Learning/physiology , Clozapine/pharmacology , Diphtheria Toxin/pharmacology , Female , Gene Knock-In Techniques , Heparin-binding EGF-like Growth Factor/genetics , Hyperalgesia/physiopathology , Male , Mice , Mice, Transgenic , Morphine/pharmacology , Muscle Proteins/biosynthesis , Nerve Fibers, Unmyelinated/physiology , Neural Pathways/drug effects , Neural Pathways/physiology , Neurons/drug effects , Neurons/metabolism , Pain Measurement/drug effects , Somatostatin/physiology , Spinal Cord/drug effectsABSTRACT
Light mechanical stimulation of hairy skin can induce a form of itch known as mechanical itch. This itch sensation is normally suppressed by inputs from mechanoreceptors; however, in many forms of chronic itch, including alloknesis, this gating mechanism is lost. Here we demonstrate that a population of spinal inhibitory interneurons that are defined by the expression of neuropeptide Y::Cre (NPY::Cre) act to gate mechanical itch. Mice in which dorsal NPY::Cre-derived neurons are selectively ablated or silenced develop mechanical itch without an increase in sensitivity to chemical itch or pain. This chronic itch state is histamine-independent and is transmitted independently of neurons that express the gastrin-releasing peptide receptor. Thus, our studies reveal a dedicated spinal cord inhibitory pathway that gates the transmission of mechanical itch.
Subject(s)
Interneurons/physiology , Mechanotransduction, Cellular/physiology , Neural Inhibition , Pruritus/physiopathology , Spinal Cord/physiology , Synaptic Transmission , Action Potentials , Animals , Hair/physiology , Mechanoreceptors/physiology , Mechanotransduction, Cellular/genetics , Mice , Mice, Transgenic , Neuropeptide Y/genetics , Neuropeptide Y/physiology , Skin/innervationABSTRACT
Inhibitory neurons in the spinal cord perform dedicated roles in processing somatosensory information and shaping motor behaviors that range from simple protective reflexes to more complex motor tasks such as locomotion, reaching and grasping. Recent efforts examining inhibition in the spinal cord have been directed toward determining how inhibitory cell types are specified and incorporated into the sensorimotor circuitry, identifying and characterizing molecularly defined cohorts of inhibitory neurons and interrogating the functional contribution these cells make to sensory processing and motor behaviors. Rapid progress is being made on all these fronts, driven in large part by molecular genetic and optogenetic approaches that are being creatively combined with neuroanatomical, electrophysiological and behavioral techniques.
Subject(s)
Locomotion/physiology , Neurons/physiology , Spinal Cord/cytology , Spinal Cord/physiology , Synapses/physiology , Animals , Nerve Net/physiology , Neurons/classificationABSTRACT
Neural networks in the hindbrain and spinal cord generate the simple patterns of motor activity that are necessary for breathing and locomotion. These networks function autonomously, producing simple yet flexible rhythmic motor behaviours that are highly responsive to sensory inputs and central control. This review outlines recent advances in our understanding of the genetic programmes controlling the assembly and functioning of circuits in the hindbrain and spinal cord that are responsible for respiration and locomotion. In addition, we highlight the influence that target-derived retrograde signaling and experience-dependent mechanisms have on establishing connectivity, particularly with respect to sensory afferent innervation of the spinal cord.
Subject(s)
Motor Activity/genetics , Motor Neurons/physiology , Nerve Net/physiology , Rhombencephalon/physiology , Spinal Cord/physiology , Animals , Neural Pathways/physiology , Periodicity , Respiration/genetics , Signal Transduction/geneticsABSTRACT
Here we show that Smad3, a transforming growth factor beta (TGFbeta)/activin signaling effector, is expressed in discrete progenitor domains along the dorsoventral axis of the developing chick spinal cord. Restriction of Smad3 expression to the dP6-p2 and p3 domains together with exclusion from the motoneuron progenitor domain, are the result of the activity of key transcription factors responsible for patterning the neural tube. Smad3-mediated TGFbeta activity promotes cell-cycle exit and neurogenesis by inhibiting the expression of Id proteins, and activating the expression of neurogenic factors and the cyclin-dependent-kinase-inhibitor p27(kip1). Furthermore, Smad3 activity induces differentiation of selected neuronal subtypes at the expense of other subtypes. Within the intermediate and ventral domains, Smad3 promotes differentiation of ventral interneurons at the expense of motoneuron generation. Consequently, the absence of Smad3 expression from the motoneuron progenitor domain during pattern formation of the neural tube is a prerequisite for the correct generation of spinal motoneurons.