The distinct localization of CDC42 isoforms is responsible for their specific functions during migration.

The small G-protein CDC42 is an evolutionary conserved polarity protein and a key regulator of polarized cell functions, including directed cell migration. In vertebrates, alternative splicing gives rise to two CDC42 proteins: the ubiquitously expressed isoform (CDC42u) and the brain isoform (CDC42b), which only differ in their carboxy-terminal sequence, including the CAAX motif essential for their association with membranes. We show that these divergent sequences do not directly affect the range of CDC42's potential binding partners but indirectly influence CDC42-driven signaling by controlling the subcellular localization of the two isoforms. In astrocytes and neural precursors, which naturally express both variants, CDC42u associates with the leading-edge plasma membrane of migrating cells, where it recruits the Par6-PKCζ complex to fulfill its polarity function. In contrast, CDC42b mainly localizes to intracellular membrane compartments, where it regulates N-WASP-mediated endocytosis. Both CDC42 isoforms contribute their specific functions to promote the chemotaxis of neural precursors, demonstrating that their expression pattern is decisive for tissue-specific cell behavior.

Mitochondrial MDM2 Regulates Respiratory Complex I Activity Independently of p53.

Accumulating evidence indicates that the MDM2 oncoprotein promotes tumorigenesis beyond its canonical negative effects on the p53 tumor suppressor, but these p53-independent functions remain poorly understood. Here, we show that a fraction of endogenous MDM2 is actively imported in mitochondria to control respiration and mitochondrial dynamics independently of p53. Mitochondrial MDM2 represses the transcription of NADH-dehydrogenase 6 (MT-ND6) in vitro and in vivo, impinging on respiratory complex I activity and enhancing mitochondrial ROS production. Recruitment of MDM2 to mitochondria increases during oxidative stress and hypoxia. Accordingly, mice lacking MDM2 in skeletal muscles exhibit higher MT-ND6 levels, enhanced complex I activity, and increased muscular endurance in mild hypoxic conditions. Furthermore, increased mitochondrial MDM2 levels enhance the migratory and invasive properties of cancer cells. Collectively, these data uncover a previously unsuspected function of the MDM2 oncoprotein in mitochondria that play critical roles in skeletal muscle physiology and may contribute to tumor progression.

Disruption of melatonin synthesis is associated with impaired 14-3-3 and miR-451 levels in patients with autism spectrum disorders.

Autism spectrum disorders (ASD) are characterized by a wide genetic and clinical heterogeneity. However, some biochemical impairments, including decreased melatonin (crucial for circadian regulation) and elevated platelet N-acetylserotonin (the precursor of melatonin) have been reported as very frequent features in individuals with ASD. To address the mechanisms of these dysfunctions, we investigated melatonin synthesis in post-mortem pineal glands - the main source of melatonin (9 patients and 22 controls) - and gut samples - the main source of serotonin (11 patients and 13 controls), and in blood platelets from 239 individuals with ASD, their first-degree relatives and 278 controls. Our results elucidate the enzymatic mechanism for melatonin deficit in ASD, involving a reduction of both enzyme activities contributing to melatonin synthesis (AANAT and ASMT), observed in the pineal gland as well as in gut and platelets of patients. Further investigations suggest new, post-translational (reduced levels of 14-3-3 proteins which regulate AANAT and ASMT activities) and post-transcriptional (increased levels of miR-451, targeting 14-3-3ζ) mechanisms to these impairments. This study thus gives insights into the pathophysiological pathways involved in ASD.

Cortical lesion stimulates adult subventricular zone neural progenitor cell proliferation and migration to the site of injury.

The subventricular zone (SVZ) is the principal neurogenic niche present in the adult non-human mammalian brain. Neurons generated in the SVZ migrate along the rostral migratory stream to reach the olfactory bulb. Brain injuries stimulate SVZ neurogenesis and direct migration of new progenitors to the sites of injury. To date, cortical injury-induced adult SVZ neurogenesis in mice remains ambiguous and migration of neural progenitors to the site of injury has not been studied in detail. Here we report that aspiration lesion in the motor cortex induces a transient, but significant increase in the proliferation as well as neurogenesis in the SVZ. New neural progenitors migrate ectopically to the injured area with the assistance of blood vessels and reactive astrocytes. The SVZ origin of these progenitors was further confirmed using lentiviral transduction. In addition, we show that astrocyte-assisted ectopic migration is regulated by CXCR4/SDF-1 signaling pathway. Finally, upon reaching the lesion area, these progenitors differentiate mainly into glial cells and, to a lesser extent, mature neurons. These data provide a detailed account of the changes occurring in the SVZ and the cortex following lesion, and indicate the potential of the endogenous neural progenitors in cortical repair.

MARK2/Par-1 guides the directionality of neuroblasts migrating to the olfactory bulb.

In rodents and most other mammals studied, neuronal precursors generated in the subventricular zone (SVZ) migrate to the adult olfactory bulb (OB) to differentiate into interneurons called granule and periglomerular cells. How the newborn cells navigate in the postnatal forebrain to reach precisely their target area is largely unknown. However, it is often thought that postnatal neurogenesis recapitulates the neuronal development occurring during embryogenesis. During brain development, intracellular kinases are key elements for controlling cell polarization as well as the coupling between polarization and cellular movement. We show here that the polarity kinase MARK2 maintains its expression in the postnatal SVZ-OB system. We therefore investigated the potential role of this kinase in adjusting postnatal neuroblast migration. We employed mouse brain slices maintained in culture, in combination with lentiviral vector injections designed to label neuronal precursors with GFP and to diminish the expression of MARK2. Time-lapse video microscopy was used to monitor neuroblast migration in the postnatal forebrain from SVZ precursors to cells populating the OB. We found that reduced MARK2 expression resulted in altered migratory patterns and stalled neuroblasts in the rostral migratory stream (RMS). In agreement with the observed migratory defects, we report a diminution of the proportion of cells reaching the OB layers. Our study reveals the involvement of MARK2 in the maintenance of the migratory direction in postnatally-generated neuroblasts and consequently on the control of the number of newly-generated neurons reaching and integrating the appropriate target circuits.

NKCC1 controls GABAergic signaling and neuroblast migration in the postnatal forebrain.

From an early postnatal period and throughout life there is a continuous production of olfactory bulb (OB) interneurons originating from neuronal precursors in the subventricular zone. To reach the OB circuits, immature neuroblasts migrate along the rostral migratory stream (RMS). In the present study, we employed cultured postnatal mouse forebrain slices and used lentiviral vectors to label neuronal precursors with GFP and to manipulate the expression levels of the Na-K-2Cl cotransporter NKCC1. We investigated the role of this Cl- transporter in different stages of postnatal neurogenesis, including neuroblast migration and integration in the OB networks once they have reached the granule cell layer (GCL). We report that NKCC1 activity is necessary for maintaining normal migratory speed. Both pharmacological and genetic manipulations revealed that NKCC1 maintains high [Cl-]i and regulates the resting membrane potential of migratory neuroblasts whilst its functional expression is strongly reduced at the time cells reach the GCL. As in other developing systems, NKCC1 shapes GABAA-dependent signaling in the RMS neuroblasts. Also, we show that NKCC1 controls the migration of neuroblasts in the RMS. The present study indeed indicates that the latter effect results from a novel action of NKCC1 on the resting membrane potential, which is independent of GABAA-dependent signaling. All in all, our findings show that early stages of the postnatal recruitment of OB interneurons rely on precise, orchestrated mechanisms that depend on multiple actions of NKCC1.

Dynamic development of the first synapse impinging on adult-born neurons in the olfactory bulb circuit.

The olfactory bulb (OB) receives and integrates newborn interneurons throughout life. This process is important for the proper functioning of the OB circuit and consequently, for the sense of smell. Although we know how these new interneurons are produced, the way in which they integrate into the pre-existing ongoing circuits remains poorly documented. Bearing in mind that glutamatergic inputs onto local OB interneurons are crucial for adjusting the level of bulbar inhibition, it is important to characterize when and how these inputs from excitatory synapses develop on newborn OB interneurons. We studied early synaptic events that lead to the formation and maturation of the first glutamatergic synapses on adult-born granule cells (GCs), the most abundant subtype of OB interneuron. Patch-clamp recordings and electron microscopy (EM) analysis were performed on adult-born interneurons shortly after their arrival in the adult OB circuits. We found that both the ratio of N-methyl-D-aspartate receptor (NMDAR) to α-amino-3-hydroxy-5-methyl-4-isoxazolepropionic acid receptor (AMPAR), and the number of functional release sites at proximal inputs reached a maximum during the critical period for the sensory-dependent survival of newborn cells, well before the completion of dendritic arborization. EM analysis showed an accompanying change in postsynaptic density shape during the same period of time. Interestingly, the latter morphological changes disappeared in more mature newly-formed neurons, when the NMDAR to AMPAR ratio had decreased and functional presynaptic terminals expressed only single release sites. Together, these findings show that the first glutamatergic inputs to adult-generated OB interneurons undergo a unique sequence of maturation stages.

Centrifugal drive onto local inhibitory interneurons of the olfactory bulb.

The olfactory bulb is known to receive signals from sensory neurons and to convey them to higher processing centers. However, in addition to relaying sensory information to the cortex, the olfactory bulb is actively involved in sensory information processing. Hence, olfactory sensory inputs generate a reproducible spatial pattern of restricted activation in the glomerular layer that is subsequently transformed into highly distributed patterns by lateral interactions between output relay neurons and diverse types of local interneurons. Odor representation is thus highly dynamic and temporally orchestrated, right from the first central relay of the olfactory system. This major function of the olfactory bulb is subject to extensive local and extrinsic synaptic influences. The external (or centrifugal) inputs include the dense innervations preferentially targeting the granule cells of the olfactory bulb. The continuous arrival of newly generated neurons in the olfactory bulb of adults provides another source of plasticity influencing the olfactory circuitry. This review deals with the neuromodulation of granule cell activity and of the continuous recruitment of these cells throughout life.

Adult neurogenesis promotes synaptic plasticity in the olfactory bulb.

To explore the functional consequences of adult neurogenesis in the mouse olfactory bulb, we investigated plasticity at glutamatergic synapses onto GABAergic interneurons. We found that one subset of excitatory synapses onto adult-born granule cells showed long-term potentiation shortly after their arrival in the bulb. This property faded as the newborn neurons matured. These results indicate that recently generated adult-born olfactory interneurons undergo different experience-dependent synaptic modifications compared with their pre-existing mature neighbors and provide a possible substrate for adult neurogenesis-dependent olfactory learning.

A niche for adult neurogenesis in social behavior.

The structural and functional changes occurring into the brain is the hallmark of its tremendous capacity for dealing with the complexity that we are facing throughout life. It is also the hallmark of what neuroscientists refer as neuroplasticity. The continuous generation of cohorts of new neurons in some discrete regions of the adult brain, including the olfactory system, is a newly recognized form of neuroplasticity that has been recently the focus of neuroscience studies. Several lines of evidence indicate that this recruitment of newly-generated neurons is extremely sensitive to the overall neuronal activity of the host circuits. Therefore, adult neurogenesis represents, not only a constitutive replacement mechanism for lost neurons, but also a process supporting a capacity of neural plasticity in response to specific experience throughout life. The remarkable complexity of the social life offers a host of daily challenges that require a diversity of brain mechanism to make sense of the ever-changing social world. This review describes some recent findings which have begun to define reciprocal relationships between the production and integration of newborn neurons in the adult brain and social behavior. These studies demonstrate how this domain of research has the potential to address issues in the functional contribution of adult neurogenesis in the expression of some social traits as well in the role of some social contexts to finely regulate the production, survival and integration of adult newborn neurons.

Functional maturation of the first synapse in olfaction: development and adult neurogenesis.

The first synapse in olfaction undergoes considerable anatomical plasticity in both early postnatal development and adult neurogenesis, yet we know very little concerning its functional maturation at these times. Here, we used whole-cell recordings in olfactory bulb slices to describe olfactory nerve inputs to developing postnatal neurons and to maturing adult-born cells labeled with a GFP-encoding lentivirus. In both postnatal development and adult neurogenesis, the maturation of olfactory nerve synapses involved an increase in the relative contribution of AMPA over NMDA receptors, and a decrease in the contribution of NMDA receptors containing the NR2B subunit. These postsynaptic transformations, however, were not mirrored by presynaptic changes: in all cell groups, paired-pulse depression remained constant as olfactory nerve synapses matured. Although maturing cells may therefore offer, transiently, a functionally distinct connection for inputs from the nose, presynaptic function at the first olfactory connection remains remarkably constant in the face of considerable anatomical plasticity.

The how and why of adult neurogenesis.

Brain plasticity refers to the brain's ability to change structure and/or function during maturation, learning, environmental challenges, or disease. Multiple and dissociable plastic changes in the adult brain involve many different levels of organization, ranging from molecules to systems, with changes in neural elements occurring hand-in-hand with changes in supportive tissue elements, such as glia cells and blood vessels. There is now substantial evidence indicating that new functional neurons are constitutively generated from endogenous pools of neural stem cells in restricted areas of the mammalian brain, throughout life. So, in addition to all the other known structural changes, entire new neurons can be added to the existing network circuitry. This addition of newborn neurons provides the brain with another tool for tinkering with the morphology of its own functional circuitry. Although the ongoing neurogenesis and migration have been extensively documented in non-mammalian species, its characteristics in mammals have just been revealed and thus several questions remain yet unanswered. "Is adult neurogenesis an atavism, an empty-running leftover from evolution? What is adult neurogenesis good for and how does the brain 'know' that more neurons are needed? How is this functional demand translated into signals a precursor cell can detect? "[corrected].Adult neurogenesis may represent an adaptive response to challenges imposed by an environment and/or internal state of the animal. To ensure this function, the production, migration, and survival of newborn neurons must be tightly controlled. We attempt to address some of these questions here, using the olfactory bulb as a model system.

Sonic hedgehog is a potent inducer of rat oligodendrocyte development from cortical precursors in vitro.

Sonic Hedgehog (Shh) induces oligodendrocyte development in the ventral neural tube and telencephalon but its role in oligodendrocyte generation in dorsal telencephalon is debated. Transcripts for Shh and its receptor complex were detected in subventricular zone and neocortex from E17 to birth. As Shh is not yet expressed in E15 neocortex, we grew E15 cortical precursors (CP) into neurospheres in the presence of recombinant Octyl-Shh (O-Shh). After sphere adhesion and removal of O-Shh, enhanced neurite outgrowth and cell migration were already observed at 3 h. Three days after O-Shh treatment, oligodendrocyte progenitors (OP) emerged and continued to increase in number for 7 days while the ratio of neuronal cells decreased compared to control. Shh selectively triggered mitosis of OP but not neuronal progenitors and enhanced growth of neonatal OP. Thus Shh in E15-17 embryonic neocortex can signal CP to adopt an oligodendrocyte fate and favors expansion of this lineage.