NMDA 2A receptors in parvalbumin cells mediate sex-specific rapid ketamine response on cortical activity.

Ketamine has emerged as a widespread treatment for a variety of psychiatric disorders when used at sub-anesthetic doses, but the neural mechanisms underlying its acute action remain unclear. Here, we identified NMDA receptors containing the 2A subunit (GluN2A) on parvalbumin (PV)-expressing inhibitory interneurons as a pivotal target of low-dose ketamine. Genetically deleting GluN2A receptors globally or selectively from PV interneurons abolished the rapid enhancement of visual cortical responses and gamma-band oscillations by ketamine. Moreover, during the follicular phase of the estrous cycle in female mice, the ketamine response was transiently attenuated along with a concomitant decrease of grin2A mRNA expression within PV interneurons. Thus, GluN2A receptors on PV interneurons mediate the immediate actions of low-dose ketamine treatment, and fluctuations in receptor expression across the estrous cycle may underlie sex-differences in drug efficacy.

Inactivation of the Dorsal Premotor Area Disrupts Internally Generated, But Not Visually Guided, Sequential Movements.

As skill on a sequence of movements is acquired through practice, each movement in the sequence becomes seamlessly associated with another. To study the neural basis of acquired skills, we trained two monkeys (Cebus apella) to perform two sequential reaching tasks. In one task, sequential movements were instructed by visual cues, whereas in the other task, movements were generated from memory after extended practice. Then, we examined neural activity in the dorsal premotor area (PMd) and the effects of its local inactivation during performance of each task. Comparable numbers of neurons in the PMd were active during the two tasks. However, inactivation of the PMd had a marked effect only on the performance of sequential movements that were guided by memory. These results emphasize the importance of the PMd in the internal generation of sequential movements, perhaps through maintaining arbitrary motor-motor associations. SIGNIFICANCE STATEMENT: The dorsal premotor cortex (PMd) has long been thought to be a critical node in the cortical networks responsible for visually guided reaching. Here we show that PMd neurons are active during both visually guided and internally generated sequential movements. In addition, we found that local inactivation of the PMd has a marked effect only on the performance of sequential movements that were internally generated. These observations suggest that, although the PMd may participate in the generation of visually guided sequences, it is more important for the generation of internally guided sequences.

Aberrant development and plasticity of excitatory visual cortical networks in the absence of cpg15.

During development, experience plays a crucial role in sculpting neuronal connections. Patterned neural activity guides formation of functional neural circuits through the selective stabilization of some synapses and the pruning of others. Activity-regulated factors are fundamental to this process, but their roles in synapse stabilization and maturation is still poorly understood. CPG15, encoded by the activity-regulated gene candidate plasticity gene 15, is a small, glycosylphosphatidylinositol (GPI)-linked, extracellular protein that promotes synapse stabilization. Here we show that global knock-out of cpg15 results in abnormal postnatal development of the excitatory network in visual cortex and an associated disruption in development of visual receptive field properties. In addition, whereas repeated stimulation induced potentiation and depression in wild-type mice, the depression was slower in cpg15 knock-out mice, suggesting impairment in short-term depression-like mechanisms. These findings establish the requirement for cpg15 in activity-dependent development of the visual system and demonstrate the importance of timely excitatory network development for normal visual function.

Multifaceted aspects of chunking enable robust algorithms.

Sequence production tasks are a standard tool to analyze motor learning, consolidation, and habituation. As sequences are learned, movements are typically grouped into subsets or chunks. For example, most Americans memorize telephone numbers in two chunks of three digits, and one chunk of four. Studies generally use response times or error rates to estimate how subjects chunk, and these estimates are often related to physiological data. Here we show that chunking is simultaneously reflected in reaction times, errors, and their correlations. This multimodal structure enables us to propose a Bayesian algorithm that better estimates chunks while avoiding overfitting. Our algorithm reveals previously unknown behavioral structure, such as an increased error correlations with training, and promises a useful tool for the characterization of many forms of sequential motor behavior.

Response-mode shifts during sequence learning of macaque monkeys.

Incidental sequence learning has been conceptualized as involving a shift from stimulus-based to plan-based performance (e.g., Tubauet et al. in Journal of Experimental Psychology: General 136:43-63, 2007). We analyzed the response time (RT) data of two macaque monkeys that were trained for thousands of trials on a sequential reaching task in a study by Matsuzaka et al. in Journal of Neurophysiology 97, 1819-1832 (2007). The animals learned to respond predictively to a repeating 3-element sequence. During a transitional period, RT distributions were bimodal, indicating that the animals alternated between two processing modes. An analysis of trial-to-trial mode shifting probabilities provided preliminary evidence for a strategic process.

Sequential Reaching Task for the Study of Motor Skills in Monkeys.

The ability to perform a sequence of movements is a key component of motor skills, such as typing or playing a musical instrument. How the brain binds elementary movements together into meaningful actions has been a topic of much interest. Here, we describe two sequential reaching tasks that we use to investigate the neural substrate of skilled sequential movements in monkeys after long-term practice. The movement elements performed in these tasks are essentially identical, but are generated in two different contexts. In one task, monkeys perform reaching movements that are instructed by visual cues. In the other, the monkeys perform reaching movements that are generated from memory after extended practice. With this behavioral paradigm, we can dissociate the neural processes related to the acquisition and retention of motor skills from those related to movement execution.

Phosphorylation of activation function-1 regulates proteasome-dependent nuclear mobility and E6-associated protein ubiquitin ligase recruitment to the estrogen receptor beta.

The ubiquitin-proteasome pathway has been recognized as an important regulator in the hormonal response by estrogen receptor (ER) alpha, but its impact on ERbeta function is poorly characterized. In the current study, we investigated the role of the ubiquitin-proteasome pathway in regulating ERbeta activity and identified regulatory sites within the activation function (AF)-1 domain that modulate ERbeta ubiquitination and nuclear dynamics in a hormone-independent manner. Although both ERalpha and ERbeta were dependent on proteasome function for their maximal response to estrogen, they were regulated differently by proteasome inhibition in the absence of hormone, an effect shown to be dependent on their respective AF-1 domain. Given the role of AF-1 phosphorylation to regulate ER activity, we found that sequential substitutions of specific serine residues contained in MAPK consensus sites conferred transcriptional activation of ERbeta in a proteasome-dependent manner through reduced ubiquitination and enhanced accumulation of mutant receptors. Specifically, serines 94 and 106 within ERbeta AF-1 domain were found to modulate subnuclear mobility of the receptor to transit between inactive clusters and a more mobile state in a proteasome-dependent manner. In addition, cellular levels of ERbeta were regulated through these sites by facilitating the recruitment of the ubiquitin ligase E6-associated protein in a phosphorylation-dependent manner. These findings suggest a role for ERbeta AF-1 in contributing to the activation-degradation cycling of the receptor through a functional clustering of phosphorylated serine residues that cooperate in generating signals to the ubiquitin-proteasome pathway.

MeCP2: an epigenetic regulator of critical periods.

Complex adult behaviors arise from the integration of sequential and often overlapping critical periods (CPs) early in life and adolescence. These processes rely on a subtle interplay between the set of genes inherited from the parents, the surrounding environment and epigenetic regulation. Methyl-CpG-binding protein 2 (MeCP2) has been shown to recognize epigenetic states and regulate gene expression by reading methylated DNA. Here, we will review the recent findings revealing the role of MeCP2 during postnatal CPs of development using mouse models of Rett (RTT) syndrome.

Oral treatment with desipramine improves breathing and life span in Rett syndrome mouse model.

Rett syndrome is a neurodevelopmental disease due to Mecp2 gene mutations that is associated to complex neurological symptoms, with bioaminergic deficits and life-threatening apneas related to sudden and unexpected death. In male mice, Mecp2-deficiency similarly induces medullary bioaminergic deficits, severe apneas and short life span. Here, we show that long-term oral treatment of Mecp2-deficient male mice with desipramine, an old drug of clinical use known to block norepinephrine uptake and to strengthen its synaptic effects, significantly alleviates their breathing symptoms and prolongs their life span. Although these mouse results identify desipramine as the first oral pharmacological treatment potentially able to alleviate breathing symptoms of Rett syndrome, we recommend further studies of desipramine effects in Mecp2-deficient mice before attempting any clinical trials in Rett patients.

Consequences of prenatal exposure to diazepam on the respiratory parameters, respiratory network activity and gene expression of alpha1 and alpha2 subunits of GABA(A) receptor in newborn rat.

Diazepam (DZP) enhances GABA action at GABA(A) receptor. Chronic prenatal administration of DZP delays the appearance of neonatal reflexes. We examined whether maternal intake of DZP might affect respiratory control system in newborn rats (0-3 day-old). This study was conducted on unrestrained animals and medulla-spinal cord preparations. In addition, the level of expression of the genes encoding for the alpha1 and alpha2 subunits of the GABA(A) receptor was assessed by quantitative real-time RT-PCR. In rats exposed to DZP, the respiratory frequency was significantly lower and the tidal volume higher than in controls with no significant alteration of the minute ventilation. The recovery from moderate hypoxia was delayed compared to controls. The respiratory-like frequency of medullary spinal cord preparation from DZP-exposed neonates was higher than in the control group. Acute applications of DZP (1 microM) to these preparations increased respiratory-like frequency in both groups, but this facilitation was attenuated following prenatal DZP exposure. The present data indicate that prenatal exposure to DZP alters both eupneic breathing and the respiratory response to hypoxia. These effects might partly be ascribed to the down-regulation of the expression of genes encoding GABA(A) receptor subunits. On the other hand, the effects of DZP exposure on reduced preparations suggested changes in the GABA(A) receptor efficiency and/or disruption of the normal development of the medullary respiratory network.

The circadian regulation of Presenilin-2 gene expression.

Circadian rhythms are generated by a molecular clock composed of clock genes and their protein products. Other genes are regulated in a rhythmic way by this molecular clockwork, but are not themselves constituents of the clock. This study shows that one of these clock-controlled genes encodes the signalling protein Presenilin-2. Indeed, evidence is presented that the promoter of the mouse Presenilin-2 gene is bound and activated by CLOCK and BMAL1, transcription factors of the mammalian circadian clock. Quantification of Presenilin-2 RNA shows that its expression is non-rhythmic in many peripheral tissues (heart, muscle, kidney, spleen, and thymus). Note, though, that careful analysis of the liver data shows that Presenilin-2 RNA exists in distinct isoforms in this tissue, and that rhythmicity is restricted to only a subset of these RNA isoforms. These data indicate a unique mode of regulation of Presenilin-2 transcripts, the circadian control of which appears to happen at the transcriptional and post-transcriptional levels.

Cortical Feedback Regulates Feedforward Retinogeniculate Refinement.

According to the prevailing view of neural development, sensory pathways develop sequentially in a feedforward manner, whereby each local microcircuit refines and stabilizes before directing the wiring of its downstream target. In the visual system, retinal circuits are thought to mature first and direct refinement in the thalamus, after which cortical circuits refine with experience-dependent plasticity. In contrast, we now show that feedback from cortex to thalamus critically regulates refinement of the retinogeniculate projection during a discrete window in development, beginning at postnatal day 20 in mice. Disrupting cortical activity during this window, pharmacologically or chemogenetically, increases the number of retinal ganglion cells innervating each thalamic relay neuron. These results suggest that primary sensory structures develop through the concurrent and interdependent remodeling of subcortical and cortical circuits in response to sensory experience, rather than through a simple feedforward process. Our findings also highlight an unexpected function for the corticothalamic projection.

Chronic Administration of the N-Methyl-D-Aspartate Receptor Antagonist Ketamine Improves Rett Syndrome Phenotype.

BACKGROUND: Rett syndrome (RTT) is a neurological disorder caused by mutation of the X-linked MECP2 gene, which results in the progressive disruption of excitatory and inhibitory neuronal circuits. To date, there is no effective treatment available for the disorder. Studies conducted in RTT patients and murine models have shown altered expression of N-methyl-D-aspartate receptors (NMDARs). Genetic deletion of the NMDAR subunit, GluN2A, in mice lacking Mecp2 is sufficient to prevent RTT phenotypes, including regression of vision. METHODS: We performed a systematic, randomized preclinical trial of chronic administration of low-dose (8 mg/kg, intraperitoneal) ketamine, an NMDAR antagonist, starting either early in development or at the onset of RTT phenotype in Mecp2-null mice. RESULTS: Daily exposure to ketamine ameliorated RTT symptoms and extended the life span of treated Mecp2-null mice without adverse side effects. Furthermore, significant improvement was observed in cortical processing and connectivity, which were fully restored to a wild-type level, particularly when treatment was started at the onset of regression. CONCLUSIONS: Our findings provide strong evidence that targeting NMDA receptors can be a safe and effective treatment for RTT.

Extended practice of a motor skill is associated with reduced metabolic activity in M1.

How does long-term training and the development of motor skills modify the activity of the primary motor cortex (M1)? To address this issue, we trained monkeys for ~1-6 years to perform visually guided and internally generated sequences of reaching movements. Then, we used [(14)C]2-deoxyglucose (2DG) uptake and single-neuron recording to measure metabolic and neuron activity in M1. After extended practice, we observed a profound reduction of metabolic activity in M1 for the performance of internally generated compared to visually guided tasks. In contrast, measures of neuron firing displayed little difference during the two tasks. These findings suggest that the development of skill through extended practice results in a reduction in the synaptic activity required to produce internally generated, but not visually guided, sequences of movements. Thus, practice leading to skilled performance results in more efficient generation of neuronal activity in M1.

Identification of estrogen receptor ß as a SUMO-1 target reveals a novel phosphorylated sumoylation motif and regulation by glycogen synthase kinase 3ß.

SUMO conjugation has emerged as a dynamic process in regulating protein function. Here we identify estrogen receptor ß (ERß) to be a new target of SUMO-1. ERß SUMO-1 modification occurs on a unique nonconsensus sumoylation motif which becomes fully competent upon phosphorylation of its contained serine residue, which provides the essential negative charge for sumoylation. This process is further regulated by phosphorylation of additional adjacent serine residues by glycogen synthase kinase 3ß (GSK3ß), which maximizes ERß sumoylation in response to hormone. SUMO-1 attachment prevents ERß degradation by competing with ubiquitin at the same acceptor site and dictates ERß transcriptional inhibition by altering estrogen-responsive target promoter occupancy and gene expression in breast cancer cells. These findings uncovered a novel phosphorylated sumoylation motif (pSuM), which consists of the sequence ψKXS (where ψ represents a large hydrophobic residue) and which is connected to a GSK3-activated extension that functions as a SUMO enhancer. This extended pSuM offers a valuable signature to predict SUMO substrates under protein kinase regulation.

Neurological principles and rehabilitation of action disorders: computation, anatomy, and physiology (CAP) model.

This chapter outlines the basic computational, anatomical, and physiological (CAP) principles underlying upper-limb actions, such as reaching for a cup and grasping it or picking up a key, inserting it into a lock, and turning it.

Challenging estrogen receptor beta with phosphorylation.

From classical gland-based endocrinology to nuclear hormone receptor biology, tremendous progress has been made in our understanding of hormone responses underlying cellular communication. Estrogen elicits a myriad of biological processes in reproductive and peripheral target tissues through its interaction with the estrogen receptors ERalpha and ERbeta. However, our knowledge of estrogen-dependent and independent action has mainly focused on ERalpha, leaving the role of ERbeta obscure. This review discusses our current understanding of ERbeta function and the emerging role of intracellular signals that act upon and achieve estrogen-like effects through phosphorylation of ERbeta protein. Improving our understanding of how cellular determinants impact estrogen receptor actions will likely lead to treatment strategies for related endocrine diseases affecting women's health.

Bromines on N-allyl position of cationic porphyrins affect both radio- and photosensitizing properties.

With the aim to develop improved dual-action sensitizers suitable for both photodynamic therapy (PDT) and radiotherapy, we prepared a series of metal and metal-free cationic porphyrins, brominated either on beta- or N-allyl positions. Photo- and radiosensitizing efficacy was evaluated in MDA-MB-231 breast cancer cells incubated with 1 muM porphyrin and treated with graded doses of visible light or 0-6 Gy of 60Co gamma irradiation. Metabolic activity after PDT or cell survival after gamma irradiation were estimated by a colorimetric (MTT) or clonogenicity assay, respectively. The highest photo- and radiosensitizing activities were observed with the porphyrins substituted with bromines on N-allyl positions. The non-metalated N-allyl bromoporphyrin exhibited the highest photocytotoxicity (LD50=4.1+/-0.6 J cm(-2), compared to 15.3+/-2.2 J cm(-2) for the non-brominated analog). The radiosensitizing capacity of the cationic porphyrins was also affected by these substitutions with the non-metalated N-allyl bromo analog showing the best improvement (LD50=1.2+/-0.4 Gy vs. 3.6+/-0.9 Gy for the non-brominated analog). The increased photodynamic and radiosensitizing potencies due to bromine addition hold potential for the development of new, improved drugs for cancer treatment in combination with photodynamic and radiation therapy.

Prenatal diazepam exposure alters respiratory control system and GABAA and adenosine receptor gene expression in newborn rats.

In experimental animals, prenatal diazepam exposure has clearly been associated with behavioral disturbances. Its impact on newborn breathing has not been documented despite potential deleterious consequences for later brain development. We addressed this issue in neonatal rats (0-2 d) born from dams, which consumed 2 mg/kg/d diazepam via drinking fluid throughout gestation. In vivo, prenatal diazepam exposure significantly altered the normoxic-breathing pattern, lowering breathing frequency (105 vs. 125 breaths/min) and increasing tidal volume (16.2 vs. 12.7 mL/kg), and the ventilatory response to hypoxia, inducing an immediate and marked decrease in tidal volume (-30%) absent in controls. In vitro, prenatal diazepam exposure significantly increased the respiratory-like frequency produced by pontomedullary and medullary preparations (+38% and +19%, respectively) and altered the respiratory-like response to application of nonoxygenated superfusate. Both in vivo and in vitro, the recovery from oxygen deprivation challenges was delayed by prenatal diazepam exposure. Finally, real-time PCR showed that prenatal diazepam exposure affected mRNA levels of alpha1 and alpha2 GABAA receptor subunits and of A1 and A2A adenosine receptors in the brainstem. These mRNA changes, which are region-specific, suggest that prenatal diazepam exposure interferes with developmental events whose impact on the respiratory system maturation deserves further studies.

Skill representation in the primary motor cortex after long-term practice.

The acquisition of motor skills can lead to profound changes in the functional organization of the primary motor cortex (M1). For example, performance of movement sequences after prolonged practice is associated with an expansion of the effector representation in M1. Paradoxically, there is little evidence that the activity of M1 neurons reflects acquired skills, especially sequences of movements. We examined the activity of M1 neurons during skilled movement sequences in macaques trained to successively hit targets on a monitor. The targets appeared either pseudorandomly (Random mode) or in one of two repeating sequences (Repeating mode). With practice, response times for repeating sequences substantially declined and the monkeys performed the task predictively. Highly trained animals retained the acquired skill after long gaps in practice. After >2 yr of training, 40% of M1 neurons were differentially active during the two task modes. Variations in movement kinematics did not fully explain the task-dependent modulation of neuron activity. Differentially active neurons were more strongly influenced by task mode than by kinematics. Our results suggest that practice sculpts the response properties of M1 neurons. M1 may be a site of storage for the internal representation of skilled sequential movements.