François Lallemend

Schwann Cell Precursors from Nerve Innervation Are a Cellular Origin of Melanocytes in Skin

Current opinion holds that pigment cells, melanocytes, are derived from neural crest cells produced at the dorsal neural tube and that migrate under the epidermis to populate all parts of the skin. Here, we identify growing nerves projecting throughout the body as a stem/progenitor niche containing Schwann cell precursors (SCPs) from which large numbers of skin melanocytes originate. SCPs arise as a result of lack of neuronal specification by Hmx1 homeobox gene function in the neural crest ventral migratory pathway. Schwann cell and melanocyte development share signaling molecules with both the glial and melanocyte cell fates intimately linked to nerve contact and regulated in an opposing manner by Neuregulin and soluble signals including insulin-like growth factor and platelet-derived growth factor. These results reveal SCPs as a cellular origin of melanocytes, and have broad implications on the molecular mechanisms regulating skin pigmentation during development, in health and pigmentation disorders.

Molecular interactions underlying the specification of sensory neurons

Sensory neurons of the dorsal root ganglion (DRG) respond to many different kinds of stimulus. The ability to discriminate between the diverse types of sensation is reflected by the existence of functionally and morphologically specialized sensory neurons. This neuronal diversity is created in a step-wise process extending well into postnatal life. Here, we review the hierarchical organization and the molecular process involving interactions between environmental growth factors, used and reused in different developmental contexts in self-reinforcing and cross-inhibitory mechanisms, and intrinsic gene programs that underlie the progressive diversification of sensory progenitors into specialized neurons. The recent advance in knowledge of sensory neuron specification may provide mechanistic principles that could extend to other parts of the nervous system.

Sox2 and Mitf cross-regulatory interactions consolidate progenitor and melanocyte lineages in the cranial neural crest

The cellular origin and molecular mechanisms regulating pigmentation of head and neck are largely unknown. Melanocyte specification is controlled by the transcriptional activity of Mitf, but no general logic has emerged to explain how Mitf and progenitor transcriptional activities consolidate melanocyte and progenitor cell fates. We show that cranial melanocytes arise from at least two different cellular sources: initially from nerve-associated Schwann cell precursors (SCPs) and later from a cellular source that is independent of nerves. Unlike the midbrain-hindbrain cluster from which melanoblasts arise independently of nerves, a large center of melanocytes in and around cranial nerves IX-X is derived from SCPs, as shown by genetic cell-lineage tracing and analysis of ErbB3-null mutant mice. Conditional gain- and loss-of-function experiments show genetically that cell fates in the neural crest involve both the SRY transcription factor Sox2 and Mitf, which consolidate an SCP progenitor or melanocyte fate by cross-regulatory interactions. A gradual downregulation of Sox2 in progenitors during development permits the differentiation of both neural crest- and SCP-derived progenitors into melanocytes, and an initial small pool of nerve-associated melanoblasts expands in number and disperses under the control of endothelin receptor B (Ednrb) and Wnt5a signaling.

Activation of protein kinase CbetaI constitutes a new neurotrophic pathway for deafferented spiral ganglion neurons.

In mammals, degeneration of peripheral auditory neurons constitutes one of the main causes of sensorineural hearing loss. Unfortunately, to date, pharmacological interventions aimed at counteracting this condition have not presented complete effectiveness in protecting the integrity of cochlear neural elements. In this context, the protein kinase C (PKC) family of enzymes are important signalling molecules that play a role in preventing neurodegeneration after nervous system injury. The present study demonstrates, for the first time, that the PKC signalling pathway is directly neurotrophic to axotomised spiral ganglion neurons (SGNs). We found that PKCβI was strictly expressed by postnatal and adult SGNs both in situ and in vitro. In cultures of SGNs, we observed that activators of PKC, such as phorbol esters and bryostatin 1, induced neuronal survival and neurite regrowth in a manner dependent on the activation of PKCβI. The neuroprotective effects of PKC activators were suppressed by pre-treatment with LY294002 (a PI3K inhibitor) and with U0126 (a MEK inhibitor), indicating that PKC activators promote the survival and neurite outgrowth of SGNs by both PI3K/Akt and MEK/ERK-dependent mechanisms. In addition, whereas combining the neurotrophins brain-derived neurotrophic factor (BDNF) and neurotrophin-3 (NT3) was shown to provide only an additive effect on SGN survival, the interaction between PKC and neurotrophin signalling gave rise to a synergistic increase in SGN survival. Taken together, the data indicate that PKCβI activation represents a key factor for the protection of the integrity of neural elements in the cochlea.

Ephrin-A5/EphA4 signalling controls specific afferent targeting to cochlear hair cells

Hearing requires an optimal afferent innervation of sensory hair cells by spiral ganglion neurons in the cochlea. Here we report that complementary expression of ephrin-A5 in hair cells and EphA4 receptor among spiral ganglion neuron populations controls the targeting of type I and type II afferent fibres to inner and outer hair cells, respectively. In the absence of ephrin-A5 or EphA4 forward signalling, a subset of type I projections aberrantly overshoot the inner hair cell layer and invade the outer hair cell area. Lack of type I afferent synapses impairs neurotransmission from inner hair cells to the auditory nerve. By contrast, radial shift of type I projections coincides with a gain of presynaptic ribbons that could enhance the afferent signalling from outer hair cells. Ephexin-1, cofilin and myosin light chain kinase act downstream of EphA4 to induce type I spiral ganglion neuron growth cone collapse. Our findings constitute the first identification of an Eph/ephrin-mediated mutual repulsion mechanism responsible for specific sorting of auditory projections in the cochlea.

The retinoic acid inducible Cas-family signaling protein Nedd9 regulates neural crest cell migration by modulating adhesion and actin dynamics.

Cell migration is essential for the development of numerous structures derived from embryonic neural crest cells (NCCs), however the underlying molecular mechanisms are incompletely understood. NCCs migrate long distances in the embryo and contribute to many different cell types, including peripheral neurons, glia and pigment cells. In the present work we report expression of Nedd9, a scaffolding protein within the integrin signaling pathway, in non-lineage-restricted neural crest progenitor cells. In particular, Nedd9 was found to be expressed in the dorsal neural tube at the time of neural crest delamination and in early migrating NCCs. To analyze the role of Nedd9 in neural crest development we performed loss- and gain-of-function experiments and examined the subsequent effects on delamination and migration in vitro and in vivo. Our results demonstrate that loss of Nedd9 activity in chick NCCs perturbs cell spreading and the density of focal complexes and actin filaments, properties known to depend on integrins. Moreover, a siRNA dose-dependent decrease in Nedd9 activity results in a graded reduction of NCCs migratory distance while forced overexpression increases it. Retinoic acid (RA) was found to regulate Nedd9 expression in NCCs. Our results demonstrate in vivo that Nedd9 promotes the migration of NCCs in a graded manner and suggest a role for RA in the control of Nedd9 expression levels.

Glial versus melanocyte cell fate choice: Schwann cell precursors as a cellular origin of melanocytes.

Melanocytes and Schwann cells are derived from the multipotent population of neural crest cells. Although both cell types were thought to be generated through completely distinct pathways and molecular processes, a recent study has revealed that these different cell types are intimately interconnected far beyond previously postulated limits in that they share a common post-neural crest progenitor, i.e. the Schwann cell precursor. This finding raises interesting questions about the lineage relationships of hitherto unrelated cell types such as melanocytes and Schwann cells, and may provide clinical insights into mechanisms of pigmentation disorders and for cancer involving Schwann cells and melanocytes.

miR-183 cluster scales mechanical pain sensitivity by regulating basal and neuropathic pain genes

A cluster of microRNAs regulates both normal pain sensitivity and the pathological responses of chronic pain. MicroRNAs in functional and dysfunctional pain Pain serves the useful purpose of alerting us to danger. Chronic pain, however, can arise from dysfunctional responses. Peng et al. found that a cluster of microRNAs regulates the gene networks behind both physiological and dysfunctional pain (see the Perspective by Cassels and Barde). The recruitment of genes that regulate a subset of the light-touch mechanoreceptors found in hairy skin was critical to the generation of dysfunctional pain. Science, this issue p. 1168; see also p. 1124 Nociception is protective and prevents tissue damage but can also facilitate chronic pain. Whether a general principle governs these two types of pain is unknown. Here, we show that both basal mechanical and neuropathic pain are controlled by the microRNA-183 (miR-183) cluster in mice. This single cluster controls more than 80% of neuropathic pain–regulated genes and scales basal mechanical sensitivity and mechanical allodynia by regulating auxiliary voltage-gated calcium channel subunits α2δ-1 and α2δ-2. Basal sensitivity is controlled in nociceptors, and allodynia involves TrkB+ light-touch mechanoreceptors. These light-touch–sensitive neurons, which normally do not elicit pain, produce pain during neuropathy that is reversed by gabapentin. Thus, a single microRNA cluster continuously scales acute noxious mechanical sensitivity in nociceptive neurons and suppresses neuropathic pain transduction in a specific, light-touch–sensitive neuronal type recruited during mechanical allodynia.

Structure and development of cochlear afferent innervation in mammals

In mammals, sensorineural deafness results from damage to the auditory receptors of the inner ear, the nerve pathways to the brain or the cortical area that receives sound information. In this review, we first focused on the cellular and molecular events taking part to spiral ganglion axon growth, extension to the organ of Corti, and refinement. In the second half, we considered the functional maturation of synaptic contacts between sensory hair cells and their afferent projections. A better understanding of all these processes could open insights into novel therapeutic strategies aimed to re-establish primary connections from sound transducers to the ascending auditory nerve pathways.

Multipotent peripheral glial cells generate neuroendocrine cells of the adrenal medulla

Following the yellow brick road The adrenal glands affect a variety of processes such as stress responses and metabolism. The mature adrenal gland is formed from multiple tissue sources, including cells of neural origin. Furlan et al. traced the origins of these cells. The cells first become Schwann cell precursors and follow along nerves to travel from the dorsal root ganglia of the spine to the adrenal gland. Once there, the cells differentiate into chromaffin cells. The authors used singlecell transcriptomics to reveal the shifts in functional programs during migration, development, and differentiation. Science, this issue p. eaal3753 The adrenal gland is built from cells that travel along highways of nerves. INTRODUCTION Circulating adrenaline can have profound effects on the body’s “inner world,” adjusting levels depending on demand to maintain organ and bodily homeostasis during daily living. In the more extreme fight-or-flight response, the surge of adrenaline is “energizing” through effects on organs and tissues, including increased heart rate and blood glucose levels, and redirecting oxygen and glucose to limb muscles. Chromaffin cells located in the adrenal medulla constitute the main hormonal component of the autonomic nervous system and are the principal source for release of catecholamines, including adrenaline, in the systemic circulation. Understanding the cellular origin and biological processes by which the adrenal medulla is formed during development is needed for mechanistic insights into how the hormonal component of the autonomic nervous system is formed and its relation to the rest of the autonomic nervous system. RATIONALE Adrenergic chromaffin cells in the adrenal medulla are thought to originate from a common sympathoadrenal lineage close to the dorsal aorta, where these cells split in a dorsoventral direction, forming the sympathetic chain and adrenal medulla, respectively. Revisiting this dogma, we examined the cell type origin of chromaffin cells, lineage segregation of sympathoblasts and chromaffin cells, the gene programs driving specification of chromaffin cells from progenitors, and the proliferative dynamics by which the adrenal medulla is formed. RESULTS We found that chromaffin cells of the adrenal medulla are formed from peripheral glia stem cells, termed Schwann cell precursors. Genetic cell lineage tracing revealed that most chromaffin cells arise from Schwann cell precursors, and consistently, genetic ablation of Schwann cell precursors results in marked depletion of chromaffin cells. Genetic ablation of the preganglionic nerve, on which Schwann cell precursors migrate, similarly leads to marked deficiencies of chromaffin cells, and fate-tracing cells unable to differentiate into chromaffin cells reveal an accumulation of glia cells in the region of the adrenal medulla. Experiments reveal that sympathetic and adrenergic lineages diverge at an unexpectedly early stage during embryonic development. Embryonic development of the adrenal medulla relies on recruitment of numerous Schwann cell precursors with limited cell expansion. Thus, the large majority of chromaffin cells arise from Schwann cell precursors migrating on preganglionic nerves innervating the adrenal medulla. Unexpectedly, single-cell RNA sequencing revealed a complex gene-regulatory mechanism during differentiation of Schwann cell precursors to chromaffin cells, whereby Schwann cell precursors enter into a gene expression program unique for a transient cellular state. Subsequently, this gene program and chromaffin cell gene networks suppress glial gene programs, advancing cells into the chromaffin cell identity. CONCLUSION By revisiting development of the adrenergic sympathetic system, we discovered a new cellular origin of this nervous system component. The adrenergic medulla is built from both neural crest cells and Schwann cell precursors, with a major contribution from Schwann cell precursors in rodents. A cellular origin from Schwann cell precursors highlights the importance of peripheral nerves as a stem cell niche and transportation routes for progenitors essential for neuroendocrine development. These results and mechanisms of differentiation through a transient intermediate cell type may also be helpful in advancing our knowledge on neuroblastoma and pheochromocytoma, because these most often arise from the adrenal gland region. Adrenal medulla largely originates from Schwann cell precursors. Overview of adrenal medulla development resulting from lineage tracing and nerve ablation experiments. SCP, Schwann cell precursor; AG, adrenal gland; NT, neural tube; n, notochord; DRG, dorsal root ganglion; IML, intermediolateral column; NCC, neural crest cells; NC, neural crest; DA, dorsal aorta; SRG, suprarenal sympathetic ganglion. Red encodes early NCCs and their derivatives. Blue encodes late neural crest and SCP-derived cell types. Adrenaline is a fundamental circulating hormone for bodily responses to internal and external stressors. Chromaffin cells of the adrenal medulla (AM) represent the main neuroendocrine adrenergic component and are believed to differentiate from neural crest cells. We demonstrate that large numbers of chromaffin cells arise from peripheral glial stem cells, termed Schwann cell precursors (SCPs). SCPs migrate along the visceral motor nerve to the vicinity of the forming adrenal gland, where they detach from the nerve and form postsynaptic neuroendocrine chromaffin cells. An intricate molecular logic drives two sequential phases of gene expression, one unique for a distinct transient cellular state and another for cell type specification. Subsequently, these programs down-regulate SCP-gene and up-regulate chromaffin cell–gene networks. The AM forms through limited cell expansion and requires the recruitment of numerous SCPs. Thus, peripheral nerves serve as a stem cell niche for neuroendocrine system development.