Human iPS Cell-Derived Neurons Uncover the Impact of Increased Ras Signaling in Costello Syndrome.

Increasing evidence implicates abnormal Ras signaling as a major contributor in neurodevelopmental disorders, yet how such signaling causes cortical pathogenesis is unknown. We examined the consequences of aberrant Ras signaling in the developing mouse brain and uncovered several critical phenotypes, including increased production of cortical neurons and morphological deficits. To determine whether these phenotypes are recapitulated in humans, we generated induced pluripotent stem (iPS) cell lines from patients with Costello syndrome (CS), a developmental disorder caused by abnormal Ras signaling and characterized by neurodevelopmental abnormalities, such as cognitive impairment and autism. Directed differentiation toward a neuroectodermal fate revealed an extended progenitor phase and subsequent increased production of cortical neurons. Morphological analysis of mature neurons revealed significantly altered neurite length and soma size in CS patients. This study demonstrates the synergy between mouse and human models and validates the use of iPS cells as a platform to study the underlying cellular pathologies resulting from signaling deficits. SIGNIFICANCE STATEMENT: Increasing evidence implicates Ras signaling dysfunction as a major contributor in psychiatric and neurodevelopmental disorders, such as cognitive impairment and autism, but the underlying cortical cellular pathogenesis remains unclear. This study is the first to reveal human neuronal pathogenesis resulting from abnormal Ras signaling and provides insights into how these phenotypic abnormalities likely contribute to neurodevelopmental disorders. We also demonstrate the synergy between mouse and human models, thereby validating the use of iPS cells as a platform to study underlying cellular pathologies resulting from signaling deficits. Recapitulating human cellular pathologies in vitro facilitates the future high throughput screening of potential therapeutic agents that may reverse phenotypic and behavioral deficits.

Loss of microRNAs in pyramidal neurons leads to specific changes in inhibitory synaptic transmission in the prefrontal cortex.

MicroRNAs (miRNAs) are critical regulators of nervous system function, and in vivo knockout studies have demonstrated that miRNAs are necessary for multiple aspects of neuronal development and survival. However, the role of miRNA biogenesis in the formation and function of synapses in the cerebral cortex is only minimally understood. Here, we have generated and characterized a mouse line with a conditional neuronal deletion of Dgcr8, a miRNA biogenesis protein predicted to process miRNAs exclusively. Loss of Dgcr8 in pyramidal neurons of the cortex results in a non-cell-autonomous reduction in parvalbumin interneurons in the prefrontal cortex, accompanied by a severe deficit in inhibitory synaptic transmission and a corresponding reduction of inhibitory synapses. Together, these results suggest a vital role for miRNAs in governing essential aspects of inhibitory transmission and interneuron development in the mammalian nervous system. These results may be relevant to human diseases such as schizophrenia, where both altered Dgcr8 levels as well as aberrant inhibitory transmission in the prefrontal cortex have been postulated to contribute to the pathophysiology of the disease.

Afadin, a Ras/Rap effector that controls cadherin function, promotes spine and excitatory synapse density in the hippocampus.

Many molecules regulate synaptogenesis, but intracellular signaling pathways required for their functions are poorly understood. Afadin is a Rap-regulated, actin-binding protein that promotes cadherin complex assembly as well as binding many other cell adhesion molecules and receptors. To examine its role in mediating synaptogenesis, we deleted afadin (mllt1), using a conditional allele, in postmitotic hippocampal neurons. Consistent with its role in promoting cadherin recruitment, afadin deletion resulted in 70% fewer and less intense N-cadherin puncta with similar reductions of ß-catenin and αN-catenin puncta densities and 35% reduction in EphB2 puncta density. Its absence also resulted in 40% decreases in spine and excitatory synapse densities in the stratum radiatum of CA1, as determined by morphology, apposition of presynaptic and postsynaptic markers, and synaptic transmission. The remaining synapses appeared to function normally. Thus, afadin is a key intracellular signaling molecule for cadherin recruitment and is necessary for spine and synapse formation in vivo.

Monoallelic deletion of the microRNA biogenesis gene Dgcr8 produces deficits in the development of excitatory synaptic transmission in the prefrontal cortex.

BACKGROUND: Neuronal phenotypes associated with hemizygosity of individual genes within the 22q11.2 deletion syndrome locus hold potential towards understanding the pathogenesis of schizophrenia and autism. Included among these genes is Dgcr8, which encodes an RNA-binding protein required for microRNA biogenesis. Dgcr8 haploinsufficient mice (Dgcr8+/-) have reduced expression of microRNAs in brain and display cognitive deficits, but how microRNA deficiency affects the development and function of neurons in the cerebral cortex is not fully understood. RESULTS: In this study, we show that Dgcr8+/- mice display reduced expression of a subset of microRNAs in the prefrontal cortex, a deficit that emerges over postnatal development. Layer V pyramidal neurons in the medial prefrontal cortex of Dgcr8+/- mice have altered electrical properties, decreased complexity of basal dendrites, and reduced excitatory synaptic transmission. CONCLUSIONS: These findings demonstrate that precise microRNA expression is critical for the postnatal development of prefrontal cortical circuitry. Similar defects in neuronal maturation resulting from microRNA deficiency could represent endophenotypes of certain neuropsychiatric diseases of developmental onset.

A gain in GABAA receptor synaptic strength in thalamus reduces oscillatory activity and absence seizures.

Neural inhibition within the thalamus is integral in shaping thalamocortical oscillatory activity. Fast, synaptic inhibition is primarily mediated by activation of heteropentameric GABA(A) receptor complexes. Here, we examined the synaptic physiology and network properties of mice lacking GABA(A) receptor alpha3, a subunit that in thalamus is uniquely expressed by inhibitory neurons of the reticular nucleus (nRT). Deletion of this subunit produced a powerful compensatory gain in inhibitory postsynaptic response in nRT neurons. Although, other forms of inhibitory and excitatory synaptic transmission in the circuit were unchanged, evoked thalamic oscillations were strongly dampened in alpha3 knockout mice. Furthermore, pharmacologically induced thalamocortical absence seizures displayed a reduction in length and power in alpha3 knockout mice. These studies highlight the role of GABAergic inhibitory strength within nRT in the maintenance of thalamic oscillations, and demonstrate that inhibitory intra-nRT synapses are a critical control point for regulating higher order thalamocortical network activity.

GABA affinity shapes IPSCs in thalamic nuclei.

Precise neural inhibition in thalamocortical circuits is required for the generation of sleep spindles and suppression of hypersynchrony associated with epileptiform activity. Accordingly, the time course of GABA(A) receptor-mediated IPSC events is an important parameter influencing the strength of inhibitory signaling. In the thalamus, two distinct types of IPSC kinetics are observed: thalamocortical relay neurons in the ventrobasal nucleus (VB) exhibit a fast decaying IPSC, whereas neurons in the adjacent reticular nucleus (RTN) display a long-lasting, slowly decaying IPSC. Here, we used patch-clamp electrophysiology and computational modeling to elucidate the basis for IPSC kinetic heterogeneity in the thalamus. Rapid application of GABA to excised membrane patches revealed that decay kinetics were attributable to intrinsic differences in GABA(A) receptor deactivation. Examination of desensitization and gating properties revealed these to be similar in VB and RTN, with the notable lack of fast and long-lasting desensitized states in both cell types. Computational simulations demonstrate that slow GABA binding and unbinding rates could reproduce the characteristic long-lasting IPSCs in RTN cells. These results indicate that within thalamic circuits, a powerful diversity of inhibitory function can result from simple differences in underlying GABA(A) receptor affinity.

Directed differentiation and transplantation of human embryonic stem cell-derived motoneurons.

Motoneurons represent a specialized class of neurons essential for the control of body movement. Motoneuron loss is the cause of a wide range of neurological disorders including amyotrophic lateral sclerosis and spinal muscular atrophy. Embryonic stem cells are a promising cell source for the study and potential treatment of motoneuron diseases. Here, we present a novel in vitro protocol of the directed differentiation of human embryonic stem cells (hESCs) into engraftable motoneurons. Neural induction of hESCs was induced on MS5 stromal feeders, resulting in the formation of neural rosettes. In response to sonic hedgehog and retinoic acid, neural rosettes were efficiently directed into spinal motoneurons with appropriate in vitro morphological, physiological, and biochemical properties. Global gene expression analysis was used as an unbiased measure to confirm motoneuron identity and type. Transplantation of motoneuron progeny into the developing chick embryo resulted in robust engraftment, maintenance of motoneuron phenotype, and long-distance axonal projections into peripheral host tissues. Transplantation into the adult rat spinal cord yielded neural grafts comprising a large number of human motoneurons with outgrowth of choline acetyltransferase positive fibers. These data provide evidence for in vivo survival of hESC-derived motoneurons, a key requirement in the development of hESC-based cell therapy in motoneuron disease. Disclosure of potential conflicts of interest is found at the end of this article.

An extrasynaptic GABAA receptor mediates tonic inhibition in thalamic VB neurons.

Whole cell patch-clamp recordings were obtained from thalamic ventrobasal (VB) and reticular (RTN) neurons in mouse brain slices. A bicuculline-sensitive tonic current was observed in VB, but not in RTN, neurons; this current was increased by the GABA(A) receptor agonist 4,5,6,7-tetrahydroisothiazolo-[5,4-c]pyridine-3-ol (THIP; 0.1 microM) and decreased by Zn(2+) (50 microM) but was unaffected by zolpidem (0.3 microM) or midazolam (0.2 microM). The pharmacological profile of the tonic current is consistent with its generation by activation of GABA(A) receptors that do not contain the alpha(1) or gamma(2) subunits. GABA(A) receptors expressed in HEK 293 cells that contained alpha(4)beta(2)delta subunits showed higher sensitivity to THIP (gaboxadol) and GABA than did receptors made up from alpha(1)beta(2)delta, alpha(4)beta(2)gamma(2s,) or alpha(1)beta(2)gamma(2s) subunits. Western blot analysis revealed that there is little, if any, alpha(3) or alpha(5) subunit protein in VB. In addition, co-immunoprecipitation studies showed that antibodies to the delta subunit could precipitate alpha(4), but not alpha(1) subunit protein. Confocal microscopy of thalamic neurons grown in culture confirmed that alpha(4) and delta subunits are extensively co-localized with one another and are found predominantly, but not exclusively, at extrasynaptic sites. We conclude that thalamic VB neurons express extrasynaptic GABA(A) receptors that are highly sensitive to GABA and THIP and that these receptors are most likely made up of alpha(4)beta(2)delta subunits. In view of the critical role of thalamic neurons in the generation of oscillatory activity associated with sleep, these receptors may represent a principal site of action for the novel hypnotic agent gaboxadol.

Transmembrane residues define the action of isoflurane at the GABAA receptor alpha-3 subunit.

The gamma-aminobutyric acid type A (GABA(A)) receptor is the target of a structurally diverse group of sedative, hypnotic, and anesthetic drugs, including the volatile anesthetic isoflurane. Previous studies on the GABA(A) receptor have suggested the existence of a cavity located between transmembrane (TM) segments 2 and 3 in both alpha-1 and alpha-2 subunits, within which volatile anesthetics might bind. In this study, we have used site-directed mutagenesis to investigate the involvement of homologous residues of the GABA(A) alpha-3 subunit in allosteric modulation by isoflurane. Mutation of serine residue 294 within the TM2 to histidine or tyrosine increased the potency of GABA and decreased positive modulation by isoflurane. Mutation of alanine residue 315 within the TM3 to tryptophan increased the potency of GABA and abolished isoflurane modulation. The activity of the intravenous anesthetic propofol was unaltered from wild-type at these mutant receptors. These findings are consistent with the action of isoflurane on a critical site within the transmembrane domains of the receptor and suggest a degree of functional homology between the GABA(A) alpha-1, -2, and -3 subunits.

Alanine-scanning mutagenesis in the signature disulfide loop of the glycine receptor alpha 1 subunit: critical residues for activation and modulation.

The glycine receptor enables the generation of inhibitory postsynaptic currents at synapses via neurotransmitter-dependent activation. These receptors belong to the ligand-gated ion channel gene superfamily, in which all members are comprised of five subunits, each of which possesses a signature 13-residue disulfide loop (Cys loop) in the extracellular domain. In this study, we used alanine-scanning mutagenesis of the residues between C138 and C152 of the Cys loop of the glycine receptor alpha1 subunit to identify residues critical for receptor activation and allosteric modulation. Mutation of L142, F145, or P146 to alanine produced decreases in the potency, maximal amplitude, and Hill coefficient for currents elicited by glycine and impaired receptor activation by the agonist taurine. These residues, along with D148, are positionally conserved in the family of LGIC subunits. Mutation at several other positions had little or no effect. The inhaled anesthetics halothane and isoflurane potentiate submaximal agonist responses at wild-type receptors, via an allosteric site. The mutations L142A, F145A, P146A, and D148A abolished positive modulation by these anesthetics, in some cases revealing a small inhibitory effect. A molecular model of the glycine receptor alpha1 subunit suggests that the Cys loop is positioned in a region of the receptor at the interface between the extracellular and transmembrane domains and that the critical functional residues identified here lie along the face of a predominantly hydrophobic surface. The present data implicate the Cys loop as an important functional moiety in the process of glycine receptor activation and allosteric regulation by anesthetics.

A highly conserved aspartic acid residue in the signature disulfide loop of the alpha 1 subunit is a determinant of gating in the glycine receptor.

Ligand-gated ion channels (LGICs) mediate rapid chemical neurotransmission. This gene superfamily includes the nicotinic acetylcholine, GABAA/C, 5-hydroxytryptamine type 3, and glycine receptors. A signature disulfide loop (Cys loop) in the extracellular domain is a structural motif common to all LGIC member subunits. Here we report that a highly conserved aspartic acid residue within the Cys loop at position 148 (Asp-148) of the glycine receptor alpha1 subunit is critical in the process of receptor activation. Mutation of this acidic residue to the basic amino acid lysine produces a large decrease in the potency of glycine, produces a decrease in the Hill slope, and converts taurine from a full agonist to a partial agonist; these data are consistent with a molecular defect in the receptor gating mechanism. Additional mutation of Asp-148 shows that alterations in the EC50 for agonists are dependent upon the charge of the side chain at this position and not molecular volume, polarity, or hydropathy. This study implicates negative charge at position Asp-148 as a critical component of the process in which agonist binding is coupled to channel gating. This finding adds to an emerging body of evidence supporting the involvement of the Cys loop in the gating mechanism of the LGICs.