Schizophrenia as a disorder of disconnectivity

Schizophrenia is considered as a neurodevelopmental disorder with genetic and environmental factors playing a role. Animal models show that developmental hippocampal lesions are causing disconnectivity of the prefrontal cortex. Magnetic resonance imaging and postmortem investigations revealed deficits in the temporoprefrontal neuronal circuit. Decreased oligodendrocyte numbers and expression of oligodendrocyte genes and synaptic proteins may contribute to disturbances of micro- and macro-circuitry in the pathophysiology of the disease. Functional connectivity between cortical areas can be investigated with high temporal resolution using transcranial magnetic stimulation (TMS), electroencephalography (EEG), and magnetoencephalography (MEG). In this review, disconnectivity between different cortical areas in schizophrenia patients is described. The specificity and the neurobiological origin of these connectivity deficits and the relation to the symptom complex of schizophrenia and the glutamatergic and GABAergic system are discussed

Toward the language oscillogenome

Language has been argued to arise, both ontogenetically and phylogenetically, from specific patterns of brain wiring. We argue that it can further be shown that core features of language processing emerge from particular phasal and cross-frequency coupling properties of neural oscillations; what has been referred to as the language 'oscillome.' It is expected that basic aspects of the language oscillome result from genetic guidance, what we will here call the language 'oscillogenome,' for which we will put forward a list of candidate genes. We have considered genes for altered brain rhythmicity in conditions involving language deficits: autism spectrum disorders, schizophrenia, specific language impairment and dyslexia. These selected genes map on to aspects of brain function, particularly on to neurotransmitter function. We stress that caution should be adopted in the construction of any oscillogenome, given the range of potential roles particular localized frequency bands have in cognition. Our aim is to propose a set of genome-to-language linking hypotheses that, given testing, would grant explanatory power to brain rhythms with respect to language processing and evolution.Economic and Social Research Council scholarship 1474910Ministerio de Economía y Competitividad (España) FFI2016-78034-C2-2-

Adolescence in the Development of the Prefrontal Cortex and Mediodorsal Thalamus

Cognitive impairments are a hallmark of many, if not all, psychiatric disorders. They include deficits in working memory, attention, and cognitive flexibility. The prefrontal cortex (PFC) is essential for these cognitive functions and has been implicated in psychiatric disorders, including schizophrenia. The PFC receives reciprocal inputs from the thalamus, and this thalamo-PFC circuitry supports cognition. In patients with schizophrenia, who have impaired cognitive functioning, thalamo-PFC connectivity is disrupted. This finding is also seen in adolescents at high risk for the disorder, even before diagnosis.While impaired cortical maturation has been postulated as a mechanism in the etiology of schizophrenia, the postnatal development of thalamo-PFC circuitry is still poorly understood. In sensory cortex, activity relayed by the thalamus during a postnatal sensitive period is essential for proper cortical maturation. However, whether thalamic activity also shapes maturation of the PFC is unknown. Here, I will present evidence to support the hypothesis that adolescence represents a sensitive period, during which the PFC is susceptible to transient perturbations in thalamic input activity, resulting in persistent changes in circuitry. In Chapter 1, I present the existing literature on schizophrenia and our current understanding of its etiology. I then review the structure and connectivity of the PFC and its inputs, including the thalamus, in the context of schizophrenia and cognition. Next, I discuss the role of adolescence in the development of these structures and circuits. Finally, I introduce the concept of sensitive periods and outline the hypothesis that a similar process may occur in the context of the adolescent development of thalamo-PFC circuitry. To assess cognitive functioning in mouse models, I developed an operant-based working memory task. In Chapter 2, I describe this newly developed task and demonstrate that behavioral performance in the task is susceptible to PFC lesions. Thus, the task offers a new approach to studying PFC cognitive function. In Chapter 3, I discuss work done to address the hypothesis of adolescence as a sensitive period in the development of thalamo-PFC circuitry. I established an approach whereby I can transiently reduce activity in the thalamus during specific time windows. In this way, I compared the persistent effects of transient thalamic inhibition during adolescence and adulthood. I found that adolescent thalamic inhibition causes long-lasting deficits in cognitive behavioral performance, including the operant-based working memory task described in Chapter 2 and a cognitive flexibility task, decreased PFC cellular excitability, and reduced thalamo-PFC projection density. Meanwhile, adult thalamic inhibition has no persistent consequences on behavior or PFC excitability. Adolescent thalamic inhibition also results in disrupted PFC cellular cross-correlations and task outcome encoding during the cognitive flexibility task. Strikingly, exciting the thalamus in adulthood during the behavioral task rescues PFC cross-correlations, task outcome encoding, and the cognitive deficit. These data support the hypothesis that adolescence is a sensitive period in thalamo-PFC circuit maturation as adolescent thalamic inhibition has long-lasting consequences on PFC circuitry, while adult thalamic inhibition has no persistent effects. Moreover, these results highlight the role of the thalamus as a non-specific facilitator of PFC activity, expanding our understanding of this thalamic function to additional cognitive contexts. By supporting PFC network activity, boosting thalamic activity provides a potential therapeutic strategy for rescuing cognitive deficits in neurodevelopmental disorders. Finally, in Chapter 4, I conclude with a general discussion. I highlight major take-aways from this work as well as next steps in our exploration of these crucial neural circuits. Together, the findings outlined here offer new promise for early diagnosis and treatment options for patients with cognitive impairments and psychiatric disorders

Autonomous and non-autonomous requirements for the c-Jun N-terminal kinase signaling pathway in early forebrain development

The cerebral cortex is responsible for a wide variety of high-level functions including cognition, sensory perception, fine motor control, and the orchestration of body movements. The cortex is comprised of cortical excitatory neurons and inhibitory interneurons, which are arranged in a highly organized fashion into different layers and regions. These two types of cells operate in a delicate balance between excitation and inhibition, which is critical for proper cortical circuitry. In order for the cortex to execute its numerous functions, it must both send and receive input to other brain regions through axonal connections. The organization within the cortex and orchestration of connections with other brain regions is established from very early in development, and disruptions occurring even during embryogenesis can lead to lasting changes in cortical circuitry. Neurodevelopmental disorders such as autism, epilepsy, and schizophrenia are thought to arise from disturbances in the formation of cortical circuits, which can occur years before a disease physically manifests. Therefore, it is critical to understand the fundamental mechanisms responsible for early circuitry formation in order to gain better insight into the causes of these diseases. This dissertation explores the role of the c-Jun N-terminal kinase (JNK) signaling pathway in early forebrain development. A novel genetic knockout mouse model is used to eliminate all of JNK signaling in vivo from a population of cells that gives rise to cortical inhibitory interneurons. In Chapter 2, I provide evidence that JNK signaling is required for the proper migration of interneurons during embryonic development and their correct laminar allocation in the early postnatal cortical wall. This is demonstrated through both in vivo genetic approaches and ex vivo pharmacological inhibition of JNK signaling, and utilizes live-imaging techniques to assess the dynamic properties of migratory interneurons. In Chapter 3, I discovered a novel, non-autonomous requirement for JNK signaling in the pathfinding of thalamocortical axons. When JNK signaling is eliminated in the ventral telencephalon, it causes a misrouting of the thalamocortical axons that normally traverse through this territory. These are the first studies examining the complete loss of JNK function from cells located in the forebrain in vivo, and provide novel insight into the roles of JNK signaling in the development of cortical inhibitory interneurons and thalamocortical axons. Understanding the genetic regulation of forebrain development will help uncover potential causes of neurodevelopmental disorders, and can ultimately lead to better treatment of these devastating diseases

The biological origins of rituals: An interdisciplinary perspective

Ritual behavior is ubiquitous, marking animal motor patterns, normal and psychopathological behavior in human individuals as well as every human culture. Moreover, formal features of rituals appear to be highly conserved along phylogeny and characterized by a circular and spatio-temporal structure typical of habitual behavior with internal repetition of non-functional acts and redirection of attention to the "script" of the performance. A continuity, based on highly conserved cortico-striatal loops, can be traced from animal rituals to human individual and collective rituals with psychopathological compulsions at the crossing point. The transition from "routinization" to "ritualization" may have been promoted to deal with environmental unpredictability in non-social contexts and, through motor synchronization, to enhance intra-group cohesion and communication in social contexts. Ultimately, ritual, following its biological constraints exerts a "homeostatic" function on the environment (social and non-social) under conditions of unpredictability

Cortical GABAergic Neurons: Stretching it Remarks, Main Conclusions and Discussion

18 p., 1 figure and references.The articles in this Special Topic cover a range of issues concerning long-distance projecting cortical GABAergic neurons, in the context of interneuron diversity. As several authors report, these neurons are attracting renewed attention spurred by new techniques and markers which show great potential for deciphering their role in cortical organization and microcircuitry. Other authors have emphasized developmental origins of particular subpopulations and their roles in early cortical circuitry. Notable recurring themes are species-specifi c features and probable implications for normal and pathological cortical functioning. A corollary theme, evident in many of these articles, concerns nomenclature. Several terms are almost interchangeably used, but nevertheless distinct; that is: subplate, layer 7, layer VIB, pioneer and interstitial neuron (see comments to follow Clancy et al., below, among others). In this article the main conclusions, and some of what the host editors (Kathleen Rockland and Javier DeFelipe) consider the most interesting remarks, have been extracted from each of the individual articles. These commentaries are not necessarily directly derived from the original work of the authors, and may be the result of the collective work of several different laboratories. This is followed by a section dedicated to more general comments and a discussion of the issues raised. The authors who have participated in this article are listed in alphabetical order.Peer reviewe

On the role of parvalbumin interneurons in neuronal network activity in the prefrontal cortex

The prefrontal cortex (PFC) is an area important for executive functions, the initiation and temporal organization of goal-directed behavior, as well as social behaviors. Inhibitory interneurons expressing parvalbumin (PV) have a vital role in modulating PFC circuit plasticity and output, as inhibition by PV interneurons on excitatory pyramidal neurons regulates the excitability of the network. Thus, dysfunctions of prefrontal PV interneurons are implicated in the pathophysiology of a range of PFC-dependent neuropsychiatric disorders characterized by excitation and inhibition (E/I) imbalance and impaired gamma oscillations. In particular, the hypofunction of receptors important for neurotransmission and regulating cellular functions, such as the N-methyl-D-aspartate receptors (NMDARs) and the tyrosine receptor kinase B (trkB), has been implicated in PV dysfunction. Notably, this hypofunction is known to impair the normal development of PV interneurons. However, it can also affect adult brain activity. The effects of altered receptors on PV interneurons are multiple, from impaired morphological connectivity to disruption of intrinsic activity, but have not yet been fully characterized. Moreover, the effects of deficits of PV neuron-mediated inhibition on neuronal network activity are complex, involved with compensatory mechanisms, and not fully understood either. For instance, the E/I imbalance due to PV inhibition has been suggested to functionally disrupt the cortex, which can be observed through an abnormal increase in broadband gamma activity. But as the synchronous activity of cortical PV interneurons is necessary for the generation of cortical gamma oscillations, it is paradoxical that deficient PV inhibition is associated with increased broadband gamma power. This thesis aims to examine the role of PV interneurons in shaping neuronal network activity in the mouse PFC by investigating the microscopic to macroscopic functional effects of disrupting receptors necessary for the proper activity of PV interneurons. In paper I, we observed that the increase of broadband gamma power due to NMDAR hypofunction in PV neurons is associated with asynchronies of network activity, confirming that dysfunction of neuronal inhibition can cause desynchronization at multiple time scales (affecting entrainment of spikes by the LFP, as well as cross-frequency coupling and brain states fragmentation). In Paper II, we prompted and analyzed the rippling effect of PV dysfunction in the adult PFC by expressing a dominant-negative trkB receptor specifically in PV interneurons. Despite avoiding interfering with the development of the brain, we found pronounced morphological and functional alterations in the targeted PV interneurons. These changes were associated with unusual aggressive behavior coupled with gamma-band alterations and a decreased modulation of prefrontal excitatory neuronal populations by PV interneurons. Thus, the work presented in this thesis furthers our understanding of the role of PV function in PFC circuitry, particularly of two receptors that are central to the role of PV interneurons in coordinating local circuit activity. A better understanding of the potential mechanisms that could explain the neuronal changes seen in individuals with neuropsychiatric dysfunctions could lead to using gamma oscillations or BDNF-trkB levels as biomarkers in psychiatric disorders. It also presents possibilities for potential treatments designed around reestablishing E/I balance by modifying receptor levels in particular cell types

Understanding Neural Networks in Awake Rat by Resting-State Functional MRI: A Dissertation

Resting-state functional magnetic resonance imaging (rs-fMRI) is a non-invasive neuroimaging technique that utilizes spontaneous low-frequency fluctuations of blood-oxygenation-level dependent (BOLD) signals to examine resting-state functional connectivity in the brain. In the past two decades, this technique has been increasingly utilized to investigate properties of large-scale functional neural networks as well as their alterations in various cognitive and disease states. However, much less is known about large-scale functional neural networks of the rodent brain, particularly in the awake state. Therefore, we attempted to unveil local and global functional connectivity in awake rat through a combination of seed-based analysis, independent component analysis and graph-theory analysis. In the current studies, we revealed elementary local networks and their global organization in the awake rat brain. We further systematically compared the functional neural networks in awake and anesthetized states, revealing that the rat brain was locally reorganized while maintaining global topological properties from awake to anesthetized states. Furthermore, specific neural circuitries of the rat brain were examined using resting-state fMRI. First anticorrelated functional connectivity between infralimbic cortex and amygdala were found to be evident with different preprocessing methods (global signal regression, regression of ventricular and white matter signal and no signal regression). Secondly the thalamocortical connectivity was mapped for individual thalamic groups, revealing group-specific functional cortical connections that were generally consistent with known anatomical connections in rat. In conclusion, large-scale neural networks can be robustly and reliably studied using rs-fMRI in awake rat, and with this technique we established a baseline of local and global neural networks in the awake rat brain as well as their alterations in the anesthetized condition