Establishing Hedgehog Gradients during Neural Development.

A morphogen is a signaling molecule that induces specific cellular responses depending on its local concentration. The concept of morphogenic gradients has been a central paradigm of developmental biology for decades. Sonic Hedgehog (Shh) is one of the most important morphogens that displays pleiotropic functions during embryonic development, ranging from neuronal patterning to axon guidance. It is commonly accepted that Shh is distributed in a gradient in several tissues from different origins during development; however, how these gradients are formed and maintained at the cellular and molecular levels is still the center of a great deal of research. In this review, we first explored all of the different sources of Shh during the development of the nervous system. Then, we detailed how these sources can distribute Shh in the surrounding tissues via a variety of mechanisms. Finally, we addressed how disrupting Shh distribution and gradients can induce severe neurodevelopmental disorders and cancers. Although the concept of gradient has been central in the field of neurodevelopment since the fifties, we also describe how contemporary leading-edge techniques, such as organoids, can revisit this classical model.

Heterozygous Dcc Mutant Mice Have a Subtle Locomotor Phenotype.

Axon guidance receptors such as deleted in colorectal cancer (DCC) contribute to the normal formation of neural circuits, and their mutations can be associated with neural defects. In humans, heterozygous mutations in DCC have been linked to congenital mirror movements, which are involuntary movements on one side of the body that mirror voluntary movements of the opposite side. In mice, obvious hopping phenotypes have been reported for bi-allelic Dcc mutations, while heterozygous mutants have not been closely examined. We hypothesized that a detailed characterization of Dcc heterozygous mice may reveal impaired corticospinal and spinal functions. Anterograde tracing of the Dcc+/- motor cortex revealed a normally projecting corticospinal tract, intracortical microstimulation (ICMS) evoked normal contralateral motor responses, and behavioral tests showed normal skilled forelimb coordination. Gait analyses also showed a normal locomotor pattern and rhythm in adult Dcc+/- mice during treadmill locomotion, except for a decreased occurrence of out-of-phase walk and an increased duty cycle of the stance phase at slow walking speed. Neonatal isolated Dcc+/- spinal cords had normal left-right and flexor-extensor coupling, along with normal locomotor pattern and rhythm, except for an increase in the flexor-related motoneuronal output. Although Dcc+/- mice do not exhibit any obvious bilateral impairments like those in humans, they exhibit subtle motor deficits during neonatal and adult locomotion.

The Shh receptor Boc is important for myelin formation and repair.

Myelination leads to the formation of myelin sheaths surrounding neuronal axons and is crucial for function, plasticity and repair of the central nervous system (CNS). It relies on the interaction of the axons and the oligodendrocytes: the glial cells producing CNS myelin. Here, we have investigated the role of a crucial component of the Sonic hedgehog (Shh) signalling pathway, the co-receptor Boc, in developmental and repairing myelination. During development, Boc mutant mice display a transient decrease in oligodendroglial cell density together with delayed myelination. Despite recovery of oligodendroglial cells at later stages, adult mutants still exhibit a lower production of myelin basic protein correlated with a significant decrease in the calibre of callosal axons and a reduced amount of the neurofilament NF-M. During myelin repair, the altered OPC differentiation observed in the mutant is reminiscent of the phenotype observed after blockade of Shh signalling. In addition, Boc mutant microglia/macrophages unexpectedly exhibit the apparent inability to transition from a highly to a faintly ramified morphology in vivo Altogether, these results identify Boc as an important component of myelin formation and repair.

Loss of Dcc in the spinal cord is sufficient to cause a deficit in lateralized motor control and the switch to a hopping gait.

BACKGROUND: Humans with heterozygous mutations in the axon guidance receptor DCC display congenital mirror movements (MMs), which are involuntary movements of body parts, such as fingers, on one side of the body that mirror voluntary movement of the opposite side. In mice, the homozygous Dcckanga mutant allele causes synchronous MM-like hindlimb movements during locomotion, resulting in hopping. In both human and mice, the neuroanatomical defect responsible for the deficit in lateralized motor control remains to be elucidated. RESULTS: Using the HoxB8-Cre line to specifically remove Dcc from the spinal cord, we found misrouting of commissural axons during their migration toward the floor plate, resulting in fewer axons crossing the midline. These mice also have a hopping gait, indicating that spinal cord guidance defects alone are sufficient to cause hopping. CONCLUSIONS: Dcc plays a role in the development of local spinal networks to ensure proper lateralization of motor control during locomotion. Local spinal cord defects following loss of Dcc cause a hopping gait in mice and may contribute to MM in humans. Developmental Dynamics 247:620-629, 2018. © 2017 Wiley Periodicals, Inc.

Hedgehog: Multiple Paths for Multiple Roles in Shaping the Brain and Spinal Cord.

Since the discovery of the segment polarity gene Hedgehog in Drosophila three decades ago, our knowledge of Hedgehog signaling pathway has considerably improved and paved the way to a wide field of investigations in the developing and adult central nervous system. Its peculiar transduction mechanism together with its implication in tissue patterning, neural stem cell biology, and neural tissue homeostasis make Hedgehog pathway of interest in a high number of normal or pathological contexts. Consistent with its role during brain development, misregulation of Hedgehog signaling is associated with congenital diseases and tumorigenic processes while its recruitment in damaged neural tissue may be part of the repairing process. This review focuses on the most recent data regarding the Hedgehog pathway in the developing and adult central nervous system and also its relevance as a therapeutic target in brain and spinal cord diseases.

Genetic activation of Hedgehog signaling unbalances the rate of neural stem cell renewal by increasing symmetric divisions.

In the adult brain, self-renewal is essential for the persistence of neural stem cells (NSCs) throughout life, but its regulation is still poorly understood. One NSC can give birth to two NSCs or one NSC and one transient progenitor. A correct balance is necessary for the maintenance of germinal areas, and understanding the molecular mechanisms underlying NSC division mode is clearly important. Here, we report a function of the Sonic Hedgehog (SHH) receptor Patched in the direct control of long-term NSC self-renewal in the subependymal zone. We show that genetic conditional activation of SHH signaling in adult NSCs leads to their expansion and the depletion of their direct progeny. These phenotypes are associated in vitro with an increase in NSC symmetric division in a process involving NOTCH signaling. Together, our results demonstrate a tight control of adult neurogenesis and NSC renewal driven by Patched.

Investigation of the proteolipid protein promoter activity during demyelination and repair.

The transgenic plp-GFP mouse line expressing the green fluorescent protein (GFP) driven by the mouse myelin proteolipid protein (plp) gene promoter has been previously used to study the contribution of the plp lineage to oligodendrocyte development in the embryonic brain. Here, we show that the GFP fluorescence reflects the developmental expression of proteolipid protein during the postnatal development until adulthood in brain slices and in primary cultures of plp-GFP(+) cells derived from postnatal animals. In the adult brain, plp-GFP-expressing cells are mature oligodendrocytes but not oligodendroglial progenitors. In the model of focal demyelination induced by lysolecithin (LPC) in the corpus callosum of adult plp-GFP animals, we observed an up-regulation of the morphogen Sonic Hedgehog (Shh) in the LPC-induced lesion but not in the control animals. Moreover, we show that the adenovirus-mediated transfer of Shh in the lesion results in the attenuation of the demyelination extent as evidenced by GFP fluorescence analysis in Shh-treated and control animals. Altogether these data show how plp-GFP fluorescence can be monitored to follow the oligodendrocyte lineage during demyelination and identify Shh morphogen as an important factor during repair.

Sonic Hedgehog signaling is a positive oligodendrocyte regulator during demyelination.

The morphogen Sonic Hedgehog (Shh) controls the generation of oligodendrocyte (OLs) during embryonic development and regulates OL production in adulthood in the cortex and corpus callosum. The roles of Shh in CNS repair following lesions associated with demyelinating diseases are still unresolved. Here, we address this issue by using a model of focal demyelination induced by lysolecithin in the corpus callosum of adult mice. Shh transcripts and protein were not detected in control animals but were upregulated in a time-dependent manner in the oligodendroglial lineage within the lesion. We report an increased transcription of Shh target genes suggesting a broad reactivation of the Shh pathway. We show that the adenovirus-mediated transfer of Shh into the lesioned brain results in the attenuation of the lesion extent with the increase of OL progenitor cells (OPCs) and mature myelinating OL numbers due to survival, proliferation, and differentiation activities as well as the decrease of astrogliosis and macrophage infiltration. Furthermore, the blocking of Shh signaling during the lesion, using its physiological antagonist, Hedgehog interacting protein, results in a decrease of OPC proliferation and differentiation, preventing repair. Together, our findings identify Shh as a necessary factor playing a positive role during demyelination and indicate that its signaling activation stands as a potential therapeutic approach for myelin diseases.

Hedgehog trafficking, cilia and brain functions.

The primary cilium has recently emerged as an important center for transduction of the Sonic Hedgehog (Shh) signal. Genetic studies have shown that Shh signaling at the level of primary cilia is essential for patterning the ventral neural tube and regulating adult stem cells. Some defects observed in human diseases and resulting from mutations affecting the organization of the primary cilium have been attributed to defective Shh signaling. The recent development of Shh pathway inhibitors for treating tumors linked to perturbations of Shh signaling has fostered studies to understand their mechanism of action in Shh receptor complex trafficking at the primary cilium.