Syngap1 regulates experience-dependent cortical ensemble plasticity by promoting in vivo excitatory synapse strengthening

A significant proportion of autism risk genes regulate synapse function, including plasticity, which is believed to contribute to behavioral abnormalities. However, it remains unclear how impaired synapse plasticity contributes to network-level processes linked to adaptive behaviors, such as experience-dependent ensemble plasticity. We found that Syngap1, a major autism risk gene, promoted measures of experience-dependent excitatory synapse strengthening in the mouse cortex, including spike-timing–dependent glutamatergic synaptic potentiation and presynaptic bouton formation. Synaptic depression and bouton elimination were normal in Syngap1 mice. Within cortical networks, Syngap1 promoted experience-dependent increases in somatic neural activity in weakly active neurons. In contrast, plastic changes to highly active neurons from the same ensemble that paradoxically weaken with experience were unaffected. Thus, experience-dependent excitatory synapse strengthening mediated by Syngap1 shapes neuron-specific plasticity within cortical ensembles. We propose that other genes regulate neuron-specific weakening within ensembles, and together, these processes function to redistribute activity within cortical networks during experience.

Autism risk genes converge on several neurobiological functions, including the regulation of synapse biology (1–3). Synapse processes directly controlled by autism spectrum disorder (ASD) risk genes include de novo synapse formation, synapse maturation, and activity-driven changes in synapse function (i.e., synapse plasticity). Synapse plasticity, especially in cortical excitatory neurons, is a process enabling neural circuits to store new information, which is essential for experience-dependent modifications of behavior to promote survival (4, 5). Thus, risk genes are thought to contribute to ASD etiology by disrupting how neural circuits change in response to novel experiences, which in turn contributes to maladaptive behaviors. However, the study of risk gene biology and their relationship to neural plasticity is largely restricted to reduced biological preparations that focus on isolated changes to a small subset of synapses. Therefore, it is unclear how risk gene–driven regulation of synapse plasticity contributes to changes in neural dynamics within intact functional networks known to drive adaptive behaviors.Neuronal ensembles, or groups of coactivated neurons, are thought to be the direct neural substrate of cognitive processes and behavior (6). In cortex, ensemble plasticity is a multidimensional process that reflects the distribution of distinct cellular plasticity mechanisms across individual neuronal components within the assembly. For example, neurons within the same sensory-evoked cortical ensemble can undergo either increases or decreases in activity in response to the same sensory experience (7–9). While this general phenomenon has been observed in multiple contexts, it is unclear how neurons within the same functional network can have opposing changes to enduring neuronal activity in response to the same sensory experience. One way that this may occur is through the simultaneous activation of distinct forms of experience-dependent plasticity that are differentially distributed throughout neurons that comprise a functional network. Indeed, sensory experience drives the induction of Hebbian-type synaptic plasticity that can strengthen or weaken excitatory synaptic input onto sensory-responsive neurons (10). Experience-dependent circuit plasticity is not limited to changes in excitatory synaptic strength. Robust changes to the function and connectivity of GABAergic interneurons within cortical microcircuits also occurs in response to novel experience, which in turn regulates the output of pyramidal neurons (11–13). Moreover, intrinsic changes to neuronal excitability have also been observed, and in combination with changes to GABAergic function, these collective processes are thought to maintain a set firing rate within networks even as activity is redistributed among individual neurons (8, 14, 15).We propose that experience induces heterogenous changes in activity within neurons of a cortical assembly through cellular processes controlled, at least in part, by genetic mechanisms linked to ASD risk. This hypothesis originates from the clear overrepresentation of ASD risk genes that regulate the neurobiology of synapses and synapse plasticity (1–3). However, because of the multidimensional nature of cortical network plasticity, one cannot infer how a gene influences experience-dependent changes in distributed network dynamics when the function of the gene has only been studied in isolated subcellular structures, such as synapses. It is therefore important to study major ASD risk genes in the context of intact functional networks. Doing so will help to elucidate how their influence over molecular and cellular functions contribute to intermediate network-level processes more directly linked to behaviors, such as cortical ensemble plasticity.In this study, we investigated how a major ASD risk gene, SYNGAP1/Syngap1 (HUMAN/mouse–mouse only from now on), regulates specific aspects of cellular plasticity in vivo and how this process shapes experience-dependent ensemble plasticity with sensory-responsive cortical networks. The Syngap1 gene, which is a major autism risk factor (16), is a robust regulator of various forms of long-term potentiation (LTP) (17), a cellular model of Hebbian plasticity. It regulates LTP through control of excitatory synapse structure and function by gating NMDA receptor-dependent regulation of AMPA receptor trafficking and dendritic spine size (18–20). The role of Syngap1 in regulating synapse plasticity has been observed by various researchers across distinct neuronal subtypes in a variety of in vitro and ex vivo preparations (21–24). Based on this past work in reduced preparations, we hypothesized that Syngap1 regulates experience-dependent ensemble plasticity by promoting the strengthening of excitatory synapses within functional cortical networks. We found that Syngap1 was required for spike-timing-dependent (STD) synaptic potentiation and experience-mediated synapse bouton formation in layer (L) 2/3 of somatosensory cortex (SSC) but not synaptic depression or synapse bouton elimination. Syngap1 heterozygosity in mice disrupted experience-dependent potentiation of neuronal activity within a subpopulation of L2/3 SSC neurons. Syngap1 loss of function had no effect on plasticity of neurons within the same ensemble that weakens with experience. These findings indicate that disruptions to synapse-level strengthening mechanisms in Syngap1 mice contribute to imbalanced cortical ensemble plasticity driven by novel sensory experience. We propose that a key function of Syngap1 is to promote complex network-level plasticity through the strengthening of excitatory connections within cortical circuits.     

Drosophila Orb2 targets genes involved in neuronal growth,synapse formation,and protein turnover

In the study of long-term memory, how memory persists is a fundamental and unresolved question. What are the molecular components of the long-lasting memory trace? Previous studies in Aplysia and Drosophila have found that a neuronal variant of a RNA-binding protein with a self-perpetuating prion-like property, cytoplasmic polyadenylation element binding protein, is required for the persistence of long-term synaptic facilitation in the snail and long-term memory in the fly. In this study, we have identified the mRNA targets of the Drosophila neuronal cytoplasmic polyadenylation element binding protein, Orb2. These Orb2 targets include genes involved in neuronal growth, synapse formation, and intriguingly, protein turnover. These targets suggest that the persistent form of the memory trace might be comprised of molecules that maintain a sustained, permissive environment for synaptic growth in an activated synapse.     

A synaptic basis for memory storage in the cerebral cortex

A cardinal feature of neurons in the cerebral cortex is stimulus selectivity, and experience-dependent shifts in selectivity are a common correlate of memory formation. We have used a theoretical “learning rule,” devised to account for experience-dependent shifts in neuronal selectivity, to guide experiments on the elementary mechanisms of synaptic plasticity in hippocampus and neocortex. These experiments reveal that many synapses in hippocampus and neocortex are bidirectionally modifiable, that the modifications persist long enough to contribute to long-term memory storage, and that key variables governing the sign of synaptic plasticity are the amount of NMDA receptor activation and the recent history of cortical activity.     

Distinct functional developments of surviving and eliminated presynaptic terminals

For neuronal circuits in the brain to mature, necessary synapses must be maintained and redundant synapses eliminated through experience-dependent mechanisms. However, the functional differentiation of these synapse types during the refinement process remains elusive. Here, we addressed this issue by distinct labeling and direct recordings of presynaptic terminals fated for survival and for elimination in the somatosensory thalamus. At surviving terminals, the number of total releasable vesicles was first enlarged, and then calcium channels and fast-releasing synaptic vesicles were tightly coupled in an experience-dependent manner. By contrast, transmitter release mechanisms did not mature at terminals fated for elimination, irrespective of sensory experience. Nonetheless, terminals fated for survival and for elimination both exhibited developmental shortening of action potential waveforms that was experience independent. Thus, we dissected experience-dependent and -independent developmental maturation processes of surviving and eliminated presynaptic terminals during neuronal circuit refinement.

The developmental maturation of neural circuits involves the initial formation of a surplus of synapses, followed by selective survival of strengthened synapses and elimination of others. This selective pruning occurs throughout the brain and is considered a fundamental event for the maturation of neuronal networks. Extensive studies have been performed to understand the underlying mechanisms (1, 2), and several model systems in the developing brain have been proposed (3–6). Such studies have shown that this refinement process is remarkably sensitive to sensory experience during postnatal development (5, 7), indicating that the strengthening of winner synapses and elimination of loser synapses occurs in an experience-dependent manner. However, it is not known if the transmitter release mechanism, crucial for synaptic transmission, develops differently at presynaptic terminals that are fated for survival and at those fated for elimination. Furthermore, how sensory experience affects presynaptic functional development is not clear because direct observations are lacking.To examine transmitter release kinetics, the most direct methods are capacitance measurements of presynaptic terminals or paired recordings from a presynaptic terminal and postsynaptic cell (8, 9). However, these require patch clamping directly on presynaptic terminals, which is often not possible because of their small size at most central nervous system synapses. These methods have been applied to large presynaptic structures (10–13), but presynaptic functional changes before circuit maturation have only been explored at the calyx of Held presynaptic terminal (14–20), and the transmitter release properties from terminals fated for elimination remain mostly unknown.To address these issues, we focused on the rodent whisker sensory pathway, in which sensory fiber synapses onto excitatory thalamocortical neurons of the somatosensory thalamus have been used to study experience-dependent circuit development. In rodents, whisker-mediated sensory information is transmitted via glutamatergic afferents (lemniscal fibers) from the V2 region of the principal trigeminal nucleus (PrV2) to the somatosensory thalamus (the ventral posteromedial nucleus [VPM]). It has been shown that VPM neurons also receive ectopic innervation from fibers originating from non-PrV2 regions, but these synapses are eliminated during circuit maturation (7). The elimination of these ectopic connections is prevented by whisker deprivation (WD), indicating that circuit refinement in the VPM is experience dependent (7). Therefore, transmitter release mechanisms of terminals fated for survival or elimination during development can be examined independently by recording from PrV2-originating lemniscal fiber terminals (whisker-LFTs) or non-PrV2-origin lemniscal fiber terminals (ectopic-LFTs), respectively. Furthermore, experience-dependent modulations of transmitter release mechanisms can be easily examined by employing WD (7).Here, we used genetic and viral approaches to fluorescently label whisker- and ectopic-LFTs. The labeling enabled us to perform direct patch-clamp recordings from small LFTs and measure capacitance. By also using paired recordings from an LFT and a target VPM neuron, we were able to extensively examine the kinetics of transmitter release at terminals fated for survival or for elimination. Our data show that the transmitter release kinetics at whisker-LFTs exhibited developmental and sensory experience-dependent maturation, whereas ectopic-LFTs remained immature and insensitive to sensory experience. Thus, we clarified the distinct functional developments between “surviving” and “to-be-pruned” presynaptic terminals during neural circuit refinement.     

Altered mRNA transport,docking, and protein translation in neurons lacking fragile X mental retardation protein

Fragile X syndrome is caused by the absence of functional fragile X mental retardation protein (FMRP), an RNA binding protein. The molecular mechanism of aberrant protein synthesis in fmr1 KO mice is closely associated with the role of FMRP in mRNA transport, delivery, and local protein synthesis. We show that GFP-labeled Fmr1 and CaMKIIα mRNAs undergo decelerated motion at 0–40 min after group I mGluR stimulation, and later recover at 40–60 min. Then we investigate targeting of mRNAs associated with FMRP after neuronal stimulation. We find that FMRP is synthesized closely adjacent to stimulated mGluR5 receptors. Moreover, in WT neurons, CaMKIIα mRNA can be delivered and translated in dendritic spines within 10 min in response to group I mGluR stimulation, whereas KO neurons fail to show this response. These data suggest that FMRP can mediate spatial mRNA delivery for local protein synthesis in response to synaptic stimulation.     

Mycoparasitic interaction relieves binding of the Cre1 carbon catabolite repressor protein to promoter sequences of the ech42 (endochitinase-encoding) gene in Trichoderma harzianum

The fungus Trichoderma harzianum is a potent mycoparasite of various plant pathogenic fungi. We have studied the molecular regulation of mycoparasitism in the host/mycoparasite system Botrytis cinerea/T. harzianum. Protein extracts, prepared from various stages of mycoparasitism, were used in electrophoretic mobility-shift assays (EMSAs) with two promoter fragments of the ech-42 (42-kDa endochitinase-encoding) gene of T. harzianum. This gene was chosen as a model because its expression is triggered during mycoparasitic interaction [Carsolio, C., Gutierrez, A., Jimenez, B., van Montagu, M. & Herrera-Estrella, A. (1994) Proc. Natl. Acad. Sci. USA 91, 10903–10907]. All cell-free extracts formed high-molecular weight protein–DNA complexes, but those obtained from mycelia activated for mycoparasitic attack formed a complex with greater mobility. Competition experiments, using oligonucleotides containing functional and nonfunctional consensus sites for binding of the carbon catabolite repressor Cre1, provided evidence that the complex from nonmycoparasitic mycelia involves the binding of Cre1 to both fragments of the ech-42 promoter. The presence of two and three consensus sites for binding of Cre1 in the two ech-42 promoter fragments used is consistent with these findings. In contrast, the formation of the protein–DNA complex from mycoparasitic mycelia is unaffected by the addition of the competing oligonucleotides and hence does not involve Cre1. Addition of equal amounts of protein of cell-free extracts from nonmycoparasitic mycelia converted the mycoparasitic DNA–protein complex into the nonmycoparasitic complex. The addition of the purified Cre1::glutathione S-transferase protein to mycoparasitic cell-free extracts produced the same effect. These findings suggest that ech-42 expression in T. harzianum is regulated by (i) binding of Cre1 to two single sites in the ech-42 promoter, (ii) binding of a “mycoparasitic” protein–protein complex to the ech-42 promoter in vicinity of the Cre1 binding sites, and (iii) functional inactivation of Cre1 upon mycoparasitic interaction to enable the formation of the mycoparasitic protein–DNA complex.     

Postsynaptic neural activity regulates neuronal addition in the adult avian song control system

A striking feature of the nervous system is that it shows extensive plasticity of structure and function that allows animals to adjust to changes in their environment. Neural activity plays a key role in mediating experience-dependent neural plasticity and, thus, creates a link between the external environment, the nervous system, and behavior. One dramatic example of neural plasticity is ongoing neurogenesis in the adult brain. The role of neural activity in modulating neuronal addition, however, has not been well studied at the level of neural circuits. The avian song control system allows us to investigate how activity influences neuronal addition to a neural circuit that regulates song, a learned sensorimotor social behavior. In adult white-crowned sparrows, new neurons are added continually to the song nucleus HVC (proper name) and project their axons to its target nucleus, the robust nucleus of the arcopallium (RA). We report here that electrical activity in RA regulates neuronal addition to HVC. Decreasing neural activity in RA by intracerebral infusion of the GABA_A receptor agonist muscimol decreased the number of new HVC neurons by 56%. Our results suggest that postsynaptic electrical activity influences the addition of new neurons into a functional neural circuit in adult birds.The ongoing birth and incorporation of neurons into functional neural circuits in the central nervous system of higher vertebrates was first demonstrated conclusively in songbirds and subsequently in rodents, nonhuman primates, and humans (reviewed in ref. 1). Because new neuron generation continues throughout adulthood, the fundamental importance and the clinical implications of neurogenesis are clear. The mechanisms by which new neurons integrate into functional neural circuits, however, are not well understood.Songbirds provide a tractable model for understanding the mechanisms that regulate new neuron addition into functional circuits. Song is a learned sensorimotor behavior that is important for songbird reproduction. Song learning and production are regulated by a discrete, well-characterized neural circuit that includes HVC (proper name) and its target nucleus, the robust nucleus of the arcopallium (RA), both located in the avian forebrain (Fig. 1A) (2). In the adult Gambel’s white-crowned sparrow (WCS), the song control system shows extreme seasonal neuroplasticity (reviewed in ref. 3). Early in the breeding season, HVC and RA of WCS nearly double in volume. The increase in HVC volume results largely from an increase in new neuron incorporation, whereas the increase in RA volume results from increases in neuron size and spacing, but not number. RA neurons also show increased spontaneous electrical activity in the breeding season (4, 5). WCS typically produce only one song type that is longer and more stereotyped in structure during the breeding season (6, 7).Open in a separate windowFig. 1.Inhibition of RA neural activity by muscimol infusion decreases HVC neuronal addition. Birds were injected with BrdU to label adult-born neurons, and muscimol, a GABA_A receptor agonist, was infused unilaterally near RA to inhibit its neural activity. (A) A coronal schematic of the song-control system showing major song system projections. Black arrows show projections in the motor output circuit; red arrows show bilateral projections; blue arrows show recursive projections; and green dashed arrow shows a weak projection from RA to HVC. (B) Experimental timeline. (C) A representative image of BrdU and Hu immunolabeling in HVC. BrdU is shown in red, and Hu, a neuronal marker, is shown in green. Arrows show BrdU-positive neurons. The arrowhead indicates a BrdU-positive cell that does not colabel with Hu. (D) The number of BrdU-positive neurons in HVC at time of death. The number of Hu- and BrdU-colabeled neurons in HVC is significantly lower in the hemisphere ipsilateral to muscimol infusion than in the contralateral, uninfused hemisphere and is lower than either hemisphere in vehicle-infused controls. *P ≤ 0.05. Contralateral hemispheres are shown in light gray, and ipsilateral are in black. All data are presented as mean ± SEM.HVC contains three types of neurons: HVC→RA and HVC→area X projection neurons and interneurons. During seasonal growth, most, if not all, neurons incorporated into HVC project to RA (ref. 8, but see ref. 9). Neural progenitor cells are born at the dorsal and ventral portion of the lateral ventricle and migrate from the ventricular zone (VZ) to HVC within 1 wk after birth (10). Over the next 2–3 wk, new neurons send axonal projections to RA (11). These new HVC→RA projection neurons are functional; they can fire action potentials in response to sound stimuli (12).Environment and experience play important roles in both brain development and adult neurogenesis. For example, during embryonic development, neural activity in the visual cortex is required for target selection by axons from the lateral geniculate nucleus (13). In adult rodents, voluntary exercise and hippocampal-dependent learning enhance neurogenesis in the dentate gyrus (reviewed in ref. 1). In adult songbirds, auditory experience and song production influence neuronal turnover in HVC (14–16). This literature suggests that adult neurogenesis in the vertebrate brain is activity-dependent. In vitro studies show that excitatory stimuli act directly on hippocampal neural progenitor cells and promote survival of new neurons (reviewed in ref. 17). Thus, activity-dependent mechanisms likely influence neuronal recruitment in vivo in both developing and adult brains.One factor that may influence the recruitment to and survival of new neurons in HVC is the electrical activity of their postsynaptic targets in RA (5). We hypothesized that inhibiting the electrical activity in RA neurons in vivo would reduce neuronal addition to adult HVC. We show that decreasing RA electrical activity does indeed reduce neuronal addition to HVC, indicating that target activity is essential for appropriate neuronal addition to HVC.     

Epibranchial ganglia orchestrate the development of the cranial neurogenic crest

The wiring of the nervous system arises from extensive directional migration of neuronal cell bodies and growth of processes that, somehow, end up forming functional circuits. Thus far, this feat of biological engineering appears to rely on sequences of pathfinding decisions upon local cues, each with little relationship to the anatomical and physiological outcome. Here, we uncover a straightforward cellular mechanism for circuit building whereby a neuronal type directs the development of its future partners. We show that visceral afferents of the head (that innervate taste buds) provide a scaffold for the establishment of visceral efferents (that innervate salivatory glands and blood vessels). In embryological terms, sensory neurons derived from an epibranchial placode—that we show to develop largely independently from the neural crest—guide the directional outgrowth of hindbrain visceral motoneurons and control the formation of neural crest–derived parasympathetic ganglia.     

Developmental emergence of different forms of neuromodulation in Aplysia sensory neurons

The capacity for neuromodulation and biophysical plasticity is a defining feature of most mature neuronal cell types. In several cases, modulation at the level of the individual neuron has been causally linked to changes in the functional output of a neuronal circuit and subsequent adaptive changes in the organism’s behavioral responses. Understanding how such capacity for neuromodulation develops therefore may provide insights into the mechanisms both of neuronal development and learning and memory. We have examined the development of multiple forms of neuromodulation triggered by a common neurotransmitter, serotonin, in the pleural sensory neurons of Aplysia californica. We have found that multiple signaling cascades within a single neuron develop sequentially, with some being expressed only very late in development. In addition, our data suggest a model in which, within a single neuromodulatory pathway, the elements of the signaling cascade are developmentally expressed in a “retrograde” manner with the ionic channel that is modulated appearing early in development, functional elements in the second messenger cascade appearing later, and finally, coupling of the second messenger cascade to the serotonin receptor appearing quite late. These studies provide the characterization of the development of neuromodulation at the level of an identified cell type and offer insights into the potential roles of neuromodulatory processes in development and adult plasticity.     

Embedded cholesterol in the nicotinic acetylcholine receptor

The nicotinic acetylcholine receptor (nAChR) is a cation-selective channel central to both neuronal and muscular processes and is considered the prototype for ligand-gated ion channels, motivating a structural determination effort that spanned several decades [Unwin N (2005) Refined structure of the nicotinic acetylcholine receptor at 4 Å resolution. J Mol Biol 346:967–989]. Purified nAChR must be reconstituted in a mixture containing cholesterol to function. Proposed modes of interaction between cholesterol and the protein range from specific binding to indirect membrane-mediated mechanisms. However, the underlying cause of nAChR sensitivity to cholesterol remains controversial, in part because the vast majority of functional studies were conducted before a medium resolution structure was reported. We show that the nAChR contains internal sites capable of containing cholesterol, whose occupation stabilizes the protein structure. We detect sites at the protein–lipid interface as conventionally predicted from functional data, as well as deeply buried sites that are not usually considered. Molecular dynamics simulations reveal that occupation of both superficial and deeply buried sites most effectively preserves the experimental structure; the structure collapses in the absence of bound cholesterol. In particular, we find that bound cholesterol directly supports contacts between the agonist-binding domain and the pore that are thought to be essential for activation of the receptor. These results likely apply to those other ion channels within the Cys-loop superfamily that depend on cholesterol, such as the GABA receptor.     

Characterization of epidermal growth factor receptors in astrocytic glial and neuronal cells in primary culture

Studies characterized the structure and function of epidermal growth factor (EGF) receptors in astrocytic glial cells and neuronal cells in primary culture from neonatal rat brain. [125I]EGF binding to membranes prepared from glial and neuronal cultures was specific and dependent on protein concentration; however, glial preparations bound 5-fold more [125I]EGF per mg protein. Unlabeled EGF competed for binding to both glial and neuronal membranes with an IC50 of 5 nM, whereas insulin, insulin-like growth factor I, and nerve growth factor failed to compete. Scatchard plot analysis of binding data for glial cells yielded a curvilinear plot with dissociation constants of 7.12 nM for high affinity and 6.2 microM for low affinity sites. The higher level of binding in glial compared to neuronal membranes reflected a greater number of binding sites rather than differences in receptor affinity. In glial membranes, [125I]EGF covalently cross-linked to one major protein with a mol wt of 170,000, and EGF stimulated the phosphorylation of a 170,000 protein which was half-maximal at 20 nM. In contrast, neither covalent cross-linking nor receptor autophosphorylation could be detected in neuronal membranes. Culture of glial cells in the presence of EGF stimulated [35S]methionine incorporation into both cellular and secreted proteins, whereas no effect of EGF was observed in neuronal cultures. The addition of EGF to glial cultures produced a dose-dependent stimulation of [3H]thymidine incorporation as well as the multiplication of cells over a 6-day period. These observations show that functional EGF receptors in the neonatal brain are predominantly localized in glial cells.     

Developmental synaptic regulator,TWEAK/Fn14 signaling,is a determinant of synaptic function in models of stroke and neurodegeneration

Identifying molecular mediators of neural circuit development and/or function that contribute to circuit dysfunction when aberrantly reengaged in neurological disorders is of high importance. The role of the TWEAK/Fn14 pathway, which was recently reported to be a microglial/neuronal axis mediating synaptic refinement in experience-dependent visual development, has not been explored in synaptic function within the mature central nervous system. By combining electrophysiological and phosphoproteomic approaches, we show that TWEAK acutely dampens basal synaptic transmission and plasticity through neuronal Fn14 and impacts the phosphorylation state of pre- and postsynaptic proteins in adult mouse hippocampal slices. Importantly, this is relevant in two models featuring synaptic deficits. Blocking TWEAK/Fn14 signaling augments synaptic function in hippocampal slices from amyloid-beta–overexpressing mice. After stroke, genetic or pharmacological inhibition of TWEAK/Fn14 signaling augments basal synaptic transmission and normalizes plasticity. Our data support a glial/neuronal axis that critically modifies synaptic physiology and pathophysiology in different contexts in the mature brain and may be a therapeutic target for improving neurophysiological outcomes.

Neural circuit patterning, refinement, and plasticity are enabled by the dynamic strengthening, weakening, and pruning of chemical synapses in response to circuit activity. However, synapse loss and reduced plasticity are early hallmarks of chronic neurological disorders such as autism, schizophrenia and Alzheimer’s disease (AD) (1–3). It is therefore hypothesized that the underlying molecular mechanisms of pruning, although normally balanced in health, are dysregulated in disease. Particularly interesting is the notion that the mechanisms responsible for the reduction in functional synapses in disease reflect the aberrant reactivation of pathways important for synapse elimination in development. For example, in an AD model, synapse elimination was shown to be mediated by the complement pathway in the hippocampus (HC), reflecting aberrant reactivation of complement-dependent synapse elimination that occurs in the dorsal lateral geniculate nucleus (dLGN) of the thalamus during visual development (4). In such a paradigm, the reactivation of developmental mechanisms enables pathways that can act universally across different ages, circuits, and brain regions. Thus, the mechanisms underlying normal circuit development and their potential reactivation as key contributors to neurological diseases are areas of deep interest.In addition to chronic neurological disorders, circuitry changes also occur in acute ischemic stroke, the second leading cause of death worldwide and a cause of debilitating long-term disability. Interruptions in blood flow that deprive neurons of oxygen and nutrients result in significant cell death, followed by deficits in neurophysiological activity that are associated with poor motor recovery (5). Remarkably, the adult brain can undergo some degree of spontaneous poststroke recovery, apparently by engaging neuroplasticity mechanisms including remapping, synaptogenesis, and synaptic strengthening (5, 6). Despite these adaptations, over half of ischemic stroke patients fail to recover completely and continue to experience persistent long-term disability (7). The underlying signaling pathways that regulate synaptic physiology after stroke are an active topic of investigation.TNF-like weak inducer of apoptosis (TWEAK) protein, originally discovered as a cytokine produced by macrophages (8), signals through its injury-inducible transmembrane receptor, FGF-inducible molecule-14 (Fn14) (9). Consequently, the function of TWEAK/Fn14 signaling was elucidated as a driver of tissue remodeling in contexts of injury and disease in a variety of organ systems (10). Recently, findings have suggested a role for the TWEAK/Fn14 pathway in the central nervous system (CNS). Namely, several compelling observations indicate that TWEAK signaling through Fn14 might be a key molecular modulator of synaptic function in contexts of neurological challenge. TWEAK and Fn14 are up-regulated in the CNS in AD (11, 12, 13 and SI Appendix, Fig. S6A) and after ischemic stroke in humans and mice (14–16). Importantly, TWEAK/Fn14 signaling was also recently shown to be a pathway necessary for synapse maturation during experience-dependent visual development. Light-induced up-regulation of Fn14 in thalamocortical excitatory neurons and corresponding up-regulation of TWEAK in microglia mediate the elimination of weak synapses and strengthening of remaining synapses in the dLGN (17, 18). Indeed, the communication between neurons and supporting microglia has emerged as a key mechanism regulating neuronal circuitry, with microglia deploying their ramified processes to continuously survey and refine synapses in response to neural activity. Interestingly, TWEAK expression has also been shown to be microglia-enriched in the mouse cortex (19), suggesting that it may play a role in multiple brain regions. Thus, like the complement pathway, the TWEAK/Fn14 pathway could be an important regulator of synapse biology in visual development which is re-engaged and acts generally in different ages and brain regions to contribute to pathology.The involvement of TWEAK/Fn14 signaling in synapse physiology or pathophysiology outside of the developing visual system is unknown. We considered it to be a strong candidate modifier of synaptic function in adults given that Fn14 is up-regulated and required for synaptic refinement in experience-dependent visual development, and TWEAK and Fn14 are up-regulated in contexts of neurological injury/disease, suggesting that the TWEAK/Fn14 system is tuned to periods of substantial change in neuronal activity levels or environment (e.g., eye opening, ischemic stroke). We employed HC slices to test the hypothesis that the TWEAK/Fn14 pathway regulates synaptic function in adult mice and in different disease contexts and delineate its mechanism of action. Herein, we reveal that TWEAK, through neuronal Fn14, mediates acute dampening of basal synaptic transmission and synaptic plasticity in hippocampal slices from mature mice. Furthermore, we demonstrate that TWEAK/Fn14 signaling broadly impacts the phosphorylation state of critical synaptic proteins, suggesting a general role in synapse modulation. Finally, we show that pathway deficiency or pharmacological inhibition of TWEAK/Fn14 signaling augments synaptic transmission and plasticity in amyloid-beta (Aβ)–overexpressing mice and post ischemic stroke animals, two model systems featuring synaptic functional deficits. Thus, our results support that TWEAK/Fn14 constitutes a synaptic regulatory pathway with therapeutic potential for CNS disorders in the adult brain.     

Tissue-specific regulation and function of Grb10 during growth and neuronal commitment

Growth-factor receptor bound protein 10 (Grb10) is a signal adapter protein encoded by an imprinted gene that has roles in growth control, cellular proliferation, and insulin signaling. Additionally, Grb10 is critical for the normal behavior of the adult mouse. These functions are paralleled by Grb10’s unique tissue-specific imprinted expression; the paternal copy of Grb10 is expressed in a subset of neurons whereas the maternal copy is expressed in most other adult tissues in the mouse. The mechanism that underlies this switch between maternal and paternal expression is still unclear, as is the role for paternally expressed Grb10 in neurons. Here, we review recent work and present complementary data that contribute to the understanding of Grb10 gene regulation and function, with specific emphasis on growth and neuronal development. Additionally, we show that in vitro differentiation of mouse embryonic stem cells into alpha motor neurons recapitulates the switch from maternal to paternal expression observed during neuronal development in vivo. We postulate that this switch in allele-specific expression is related to the functional role of Grb10 in motor neurons and other neuronal tissues.     

Neurulation and neurite extension require the zinc transporter ZIP12 (slc39a12)

Zn²⁺ is required for many aspects of neuronal structure and function. However, the regulation of Zn²⁺ in the nervous system remains poorly understood. Systematic analysis of tissue-profiling microarray data showed that the zinc transporter ZIP12 (slc39a12) is highly expressed in the human brain. In the work reported here, we confirmed that ZIP12 is a Zn²⁺ uptake transporter with a conserved pattern of high expression in the mouse and Xenopus nervous system. Mouse neurons and Neuro-2a cells produce fewer and shorter neurites after ZIP12 knockdown without affecting cell viability. Zn²⁺ chelation or loading in cells to alter Zn²⁺ availability respectively mimicked or reduced the effects of ZIP12 knockdown on neurite outgrowth. ZIP12 knockdown reduces cAMP response element-binding protein activation and phosphorylation at serine 133, which is a critical pathway for neuronal differentiation. Constitutive cAMP response element-binding protein activation restores impairments in neurite outgrowth caused by Zn²⁺ chelation or ZIP12 knockdown. ZIP12 knockdown also reduces tubulin polymerization and increases sensitivity to nocodazole following neurite outgrowth. We find that ZIP12 is expressed during neurulation and early nervous system development in Xenopus tropicalis, where ZIP12 antisense morpholino knockdown impairs neural tube closure and arrests development during neurulation with concomitant reduction in tubulin polymerization in the neural plate. This study identifies a Zn²⁺ transporter that is specifically required for nervous system development and provides tangible links between Zn²⁺, neurulation, and neuronal differentiation.     

Delayed plasticity of inhibitory neurons in developing visual cortex

During postnatal development, altered sensory experience triggers the rapid reorganization of neuronal responses and connections in sensory neocortex. This experience-dependent plasticity is disrupted by reductions of intracortical inhibition. Little is known about how the responses of inhibitory cells themselves change during plasticity. We investigated the time course of inhibitory cell plasticity in mouse primary visual cortex by using functional two-photon microscopy with single-cell resolution and genetic identification of cell type. Initially, local inhibitory and excitatory cells had similar binocular visual response properties, both favoring the contralateral eye. After 2 days of monocular visual deprivation, excitatory cell responses shifted to favor the open eye, whereas inhibitory cells continued to respond more strongly to the deprived eye. By 4 days of deprivation, inhibitory cell responses shifted to match the faster changes in their excitatory counterparts. These findings reveal a dramatic delay in inhibitory cell plasticity. A minimal linear model reveals that the delay in inhibitory cell plasticity potently accelerates Hebbian plasticity in neighboring excitatory neurons. These findings offer a network-level explanation as to how inhibition regulates the experience-dependent plasticity of neocortex.     

Activity-dependent phosphorylation of Ser187 is required for SNAP-25-negative modulation of neuronal voltage-gated calcium channels

Synaptosomal-associated protein of 25 kDa (SNAP-25) is a SNARE protein that regulates neurotransmission by the formation of a complex with syntaxin 1 and synaptobrevin/VAMP2. SNAP-25 also reduces neuronal calcium responses to stimuli, but neither the functional relevance nor the molecular mechanisms of this modulation have been clarified. In this study, we demonstrate that hippocampal slices from Snap25^+/− mice display a significantly larger facilitation and that higher calcium peaks are reached after depolarization by Snap25^−/− and Snap25^+/− cultured neurons compared with wild type. We also show that SNAP-25b modulates calcium dynamics by inhibiting voltage-gated calcium channels (VGCCs) and that PKC phosphorylation of SNAP-25 at ser187 is essential for this process, as indicated by the use of phosphomimetic (S187E) or nonphosphorylated (S187A) mutants. Neuronal activity is the trigger that induces the transient phosphorylation of SNAP-25 at ser187. Indeed, enhancement of network activity increases the levels of phosphorylated SNAP-25, whereas network inhibition reduces the extent of protein phosphorylation. A transient peak of SNAP-25 phosphorylation also is detectable in rat hippocampus in vivo after i.p. injection with kainate to induce seizures. These findings demonstrate that differences in the expression levels of SNAP-25 impact on calcium dynamics and neuronal plasticity, and that SNAP-25 phosphorylation, by promoting inhibition of VGCCs, may mediate a negative feedback modulation of neuronal activity during intense activation.     

Allostery in the ferredoxin protein motif does not involve a conformational switch

Regulation of protein function via cracking, or local unfolding and refolding of substructures, is becoming a widely recognized mechanism of functional control. Oftentimes, cracking events are localized to secondary and tertiary structure interactions between domains that control the optimal position for catalysis and/or the formation of protein complexes. Small changes in free energy associated with ligand binding, phosphorylation, etc., can tip the balance and provide a regulatory functional switch. However, understanding the factors controlling function in single-domain proteins is still a significant challenge to structural biologists. We investigated the functional landscape of a single-domain plant-type ferredoxin protein and the effect of a distal loop on the electron-transfer center. We find the global stability and structure are minimally perturbed with mutation, whereas the functional properties are altered. Specifically, truncating the L1,2 loop does not lead to large-scale changes in the structure, determined via X-ray crystallography. Further, the overall thermal stability of the protein is only marginally perturbed by the mutation. However, even though the mutation is distal to the iron–sulfur cluster (∼20 Å), it leads to a significant change in the redox potential of the iron–sulfur cluster (57 mV). Structure-based all-atom simulations indicate correlated dynamical changes between the surface-exposed loop and the iron–sulfur cluster-binding region. Our results suggest intrinsic communication channels within the ferredoxin fold, composed of many short-range interactions, lead to the propagation of long-range signals. Accordingly, protein interface interactions that involve L1,2 could potentially signal functional changes in distal regions, similar to what is observed in other allosteric systems.