Yehezkel Sztainberg

miRNA malfunction causes spinal motor neuron disease

Defective RNA metabolism is an emerging mechanism involved in ALS pathogenesis and possibly in other neurodegenerative disorders. Here, we show that microRNA (miRNA) activity is essential for long-term survival of postmitotic spinal motor neurons (SMNs) in vivo. Thus, mice that do not process miRNA in SMNs exhibit hallmarks of spinal muscular atrophy (SMA), including sclerosis of the spinal cord ventral horns, aberrant end plate architecture, and myofiber atrophy with signs of denervation. Furthermore, a neurofilament heavy subunit previously implicated in motor neuron degeneration is specifically up-regulated in miRNA-deficient SMNs. We demonstrate that the heavy neurofilament subunit is a target of miR-9, a miRNA that is specifically down-regulated in a genetic model of SMA. These data provide evidence for miRNA function in SMN diseases and emphasize the potential role of miR-9–based regulatory mechanisms in adult neurons and neurodegenerative states.

High-order social interactions in groups of mice

Social behavior in mammals is often studied in pairs under artificial conditions, yet groups may rely on more complicated social structures. Here, we use a novel system for tracking multiple animals in a rich environment to characterize the nature of group behavior and interactions, and show strongly correlated group behavior in mice. We have found that the minimal models that rely only on individual traits and pairwise correlations between animals are not enough to capture group behavior, but that models that include third-order interactions give a very accurate description of the group. These models allow us to infer social interaction maps for individual groups. Using this approach, we show that environmental complexity during adolescence affects the collective group behavior of adult mice, in particular altering the role of high-order structure. Our results provide new experimental and mathematical frameworks for studying group behavior and social interactions. DOI: http://dx.doi.org/10.7554/eLife.00759.001

An environmental enrichment model for mice

Environmental enrichment for animals is a combination of complex inanimate and social stimulation and generally consists of housing conditions that facilitate enhanced sensory, cognitive, motor and social stimulation relative to standard housing conditions. One of the most robust effects of environmental enrichment is the reduction of anxiety levels. However, the extreme variability in enrichment protocols may account for some of the inconsistencies in its effects and the variance among results reported by different laboratories. In this protocol, we describe a simple environmental enrichment strategy for the induction of a robust and replicable anxiolytic-like effect in mice. We provide detailed instructions on how to build an enrichment cage that is specially designed for easy manipulation, cleaning and observation by the experimenter. In addition, we describe the different enrichment items, their order in the cage, the frequency of renewal and their cleaning and sterilization procedures. The total length of the protocol is 6 weeks.

Reversal of phenotypes in MECP2 duplication mice using genetic rescue or antisense oligonucleotides

Copy number variations have been frequently associated with developmental delay, intellectual disability and autism spectrum disorders. MECP2 duplication syndrome is one of the most common genomic rearrangements in males and is characterized by autism, intellectual disability, motor dysfunction, anxiety, epilepsy, recurrent respiratory tract infections and early death. The broad range of deficits caused by methyl-CpG-binding protein 2 (MeCP2) overexpression poses a daunting challenge to traditional biochemical-pathway-based therapeutic approaches. Accordingly, we sought strategies that directly target MeCP2 and are amenable to translation into clinical therapy. The first question that we addressed was whether the neurological dysfunction is reversible after symptoms set in. Reversal of phenotypes in adult symptomatic mice has been demonstrated in some models of monogenic loss-of-function neurological disorders, including loss of MeCP2 in Rett syndrome, indicating that, at least in some cases, the neuroanatomy may remain sufficiently intact so that correction of the molecular dysfunction underlying these disorders can restore healthy physiology. Given the absence of neurodegeneration in MECP2 duplication syndrome, we propose that restoration of normal MeCP2 levels in MECP2 duplication adult mice would rescue their phenotype. By generating and characterizing a conditional Mecp2-overexpressing mouse model, here we show that correction of MeCP2 levels largely reverses the behavioural, molecular and electrophysiological deficits. We also reduced MeCP2 using an antisense oligonucleotide strategy, which has greater translational potential. Antisense oligonucleotides are small, modified nucleic acids that can selectively hybridize with messenger RNA transcribed from a target gene and silence it, and have been successfully used to correct deficits in different mouse models. We find that antisense oligonucleotide treatment induces a broad phenotypic rescue in adult symptomatic transgenic MECP2 duplication mice (MECP2-TG), and corrected MECP2 levels in lymphoblastoid cells from MECP2 duplication patients in a dose-dependent manner.

Lessons learned from studying syndromic autism spectrum disorders

Syndromic autism spectrum disorders represent a group of childhood neurological conditions, typically associated with chromosomal abnormalities or mutations in a single gene. The discovery of their genetic causes has increased our understanding of the molecular pathways critical for normal cognitive and social development. Human studies have revealed that the brain is particularly sensitive to changes in dosage of various proteins from transcriptional and translational regulators to synaptic proteins. Investigations of these disorders in animals have shed light on previously unknown pathogenic mechanisms leading to the identification of potential targets for therapeutic intervention. The demonstration of reversibility of several phenotypes in adult mice is encouraging, and brings hope that with novel therapies, skills and functionality might improve in affected children and young adults. As new research reveals points of convergence between syndromic and nonsyndromic autism spectrum disorders, we believe there will be opportunities for shared therapeutics for this class of conditions.

An Anxiolytic Role for CRF Receptor Type 1 in the Globus Pallidus

Corticotropin-releasing factor receptor type 1 (CRFR1) plays a major role in the regulation of neuroendocrine and behavioral responses to stress and is considered a key mediator of anxiety behavior. The globus pallidus external (GPe), a main relay center within the basal ganglia that is primarily associated with motor and associative functions, is one of the brain nuclei with the highest levels of CRFR1 expression in the rodent brain. However, the role of CRFR1 in the GPe is yet unknown. In the present study, we used a lentiviral-based system of RNA interference to show that knockdown of CRFR1 mRNA expression in the GPe of adult mice induces a significant increase in anxiety-like behavior, as revealed by the light–dark transfer, open-field, and elevated plus-maze tests. This effect was further confirmed by pharmacological administration of the selective CRFR1 antagonist NBI 30775 (1.75 μg/side) directly into the GPe. In the marble-burying test, blockade of CRFR1 in the GPe increased the percentage of marbles buried and the duration of burying behavior. Additionally, we present evidence suggesting that the enkephalin system is involved in the effect of GPe-CRFR1 on anxiety-like behavior. In contrast to the well established anxiogenic role of CRFR1 in the extended amygdala, our data reveal a novel anxiolytic role for CRFR1 in the GPe.

Restoration of Mecp2 expression in GABAergic neurons is sufficient to rescue multiple disease features in a mouse model of Rett syndrome

The postnatal neurodevelopmental disorder Rett syndrome, caused by mutations in MECP2, produces a diverse array of symptoms, including loss of language, motor, and social skills and the development of hand stereotypies, anxiety, tremor, ataxia, respiratory dysrhythmias, and seizures. Surprisingly, despite the diversity of these features, we have found that deleting Mecp2 only from GABAergic inhibitory neurons in mice replicates most of this phenotype. Here we show that genetically restoring Mecp2 expression only in GABAergic neurons of male Mecp2 null mice enhanced inhibitory signaling, extended lifespan, and rescued ataxia, apraxia, and social abnormalities but did not rescue tremor or anxiety. Female Mecp2+/- mice showed a less dramatic but still substantial rescue. These findings highlight the critical regulatory role of GABAergic neurons in certain behaviors and suggest that modulating the excitatory/inhibitory balance through GABAergic neurons could prove a viable therapeutic option in Rett syndrome. DOI: http://dx.doi.org/10.7554/eLife.14198.001

Overexpression of Corticotropin-Releasing Factor Receptor Type 2 in the Bed Nucleus of Stria Terminalis Improves Posttraumatic Stress Disorder-like Symptoms in a Model of Incubation of Fear

BACKGROUND Posttraumatic stress disorder (PTSD) is a severe, persistent psychiatric disorder in response to a traumatic event, causing intense anxiety and fear. These responses may increase over time upon conditioning with fear-associated cues, a phenomenon termed fear incubation. Corticotropin-releasing factor receptor type 1 (CRFR1) is involved in activation of the central stress response, while corticotropin-releasing factor receptor type 2 (CRFR2) has been suggested to mediate termination of this response. Corticotropin-releasing factor (CRF) receptors are found in stress-related regions, including the bed nucleus of stria terminalis (BNST), which is implicated in sustained fear. METHODS Fear-related behaviors were analyzed in rats exposed to predator-associated cues, a model of psychological trauma, over 10 weeks. Rats were classified as susceptible (PTSD-like) or resilient. Expression levels of CRF receptors were measured in the amygdala nuclei and BNST of the two groups. In addition, lentiviruses overexpressing CRFR2 were injected into the medial division, posterointermediate part of the BNST (BSTMPI) of susceptible and resilient rats and response to stress cues was measured. RESULTS We found that exposure to stress and stress-associated cues induced a progressive increase in fear response of susceptible rats. The behavioral manifestations of these rats were correlated both with sustained elevation in CRFR1 expression and long-term downregulation in CRFR2 expression in the BSTMPI. Intra-BSTMPI injection of CRFR2 overexpressing lentiviruses attenuated behavioral impairments of susceptible rats. CONCLUSIONS These results implicate the BNST CRF receptors in the mechanism of coping with stress. Our findings suggest increase of CRFR2 levels as a new approach for understanding stress-related atypical psychiatric syndromes such as PTSD.

A novel corticotropin-releasing factor receptor splice variant exhibits dominant negative activity: a putative link to stress-induced heart disease

A growing body of experimental and clinical studies supports a strong association between psychological stress and cardiovascular disease. An important endogenous cardioprotective role in heart physiology has been attributed to corticotropin‐releasing factor receptor type 2β (CRFR2β). Here, we report the isolation of cDNA from mouse (m) heart encoding a novel CRFR2β splice variant. Translation of this insertion variant (iv)‐mCRFR2β isoform produces a 421‐aa protein that includes a unique C‐terminal cytoplasmic tail. Our functional analysis and cellular localization studies demonstrated that when coexpressed with wild‐type mCRFR2β, iv‐mCRFR2β significantly inhibited the wild‐type mCRFR2P membrane expression and its functional signaling by ER‐Golgi complex retention, suggesting a dose‐dependent dominant negative effect. Interestingly, mice exposed to a 4‐wk paradigm of chronic variable stress, a model of chronic psychological stress in humans, presented significantly lower levels of mCRFR2β and higher levels of ivmCRFR2β mRNA expression in their hearts, compared to nonstressed control mice. The dominant‐negative effect of iv‐mCRFR2β and its up‐regulation by psychological stress suggest a new form of regulation of the mCRFR2β cardioprotective effect and a potential role for this novel isoform in stress‐induced heart disease.—Sztainberg, Y.,Kuperman, Y., Issler, O., Gil, S., Vaughan, J., Rivier, J., Vale, W., Chen, A. A novel corticotropin‐releasing factor receptor splice variant exhibits dominant negative activity: a putative link to stress‐induced heart disease. FASEB J. 23, 2186–2196 (2009)

Knockdown of CRF1 receptors in the ventral tegmental area attenuates cue- and acute food deprivation stress-induced cocaine seeking in mice.

Corticotrophin-releasing factor (CRF) modulates the influence of stress on cocaine reward and reward seeking acting at multiple sites, including the ventral tegmental area (VTA). There is controversy, however, concerning the contribution of CRF receptor type 1 (CRFR1) to this effect and whether CRF within the VTA is involved in other aspects of reward seeking independent of acute stress. Here we examine the role of CRFR1 within the VTA in relation to cocaine and natural reward using viral delivery of short hairpin RNAs (lenti-shCRFR1) and investigate the effect on operant self-administration and motivation to self-administer, as well as stress- and cue-induced reward seeking in mice. While knockdown of CRFR1 in the VTA had no effect on self-administration behavior for either cocaine or sucrose, it effectively blocked acute food deprivation stress-induced reinstatement of cocaine seeking. We also observed reduced cue-induced cocaine seeking assessed in a single extinction session after extended abstinence, but cue-induced sucrose seeking was unaffected, suggesting dissociation between the contribution of CRFR1 in the VTA in cocaine reward and sucrose and cocaine seeking. Further, our data indicate a role for VTA CRFR1 signaling in cocaine seeking associated with, and independent of, stress potentially involving conditioning and/or salience attribution of cocaine reward-related cues. CRFR1 signaling in the VTA therefore presents a target for convergent effects of both cue- and stress-induced cocaine-seeking pathways.