Role of Mechanical Factors in the Morphology of the Primate Cerebral Cortex

The convoluted cortex of primates is instantly recognizable in its principal morphologic features, yet puzzling in its complex finer structure. Various hypotheses have been proposed about the mechanisms of its formation. Based on the analysis of databases of quantitative architectonic and connection data for primate prefrontal cortices, we offer support for the hypothesis that tension exerted by corticocortical connections is a significant factor in shaping the cerebral cortical landscape. Moreover, forces generated by cortical folding influence laminar morphology, and appear to have a previously unsuspected impact on cellular migration during cortical development. The evidence for a significant role of mechanical factors in cortical morphology opens the possibility of constructing computational models of cortical develoment based on physical principles. Such models are particularly relevant for understanding the relationship of cortical morphology to the connectivity of normal brains, and structurally altered brains in diseases of developmental origin, such as schizophrenia and autism

Cannabinoid CB1 Receptor: Role in Primate Prefrontal Circuitry and Schizophrenia

Schizophrenia is a complex and devastating psychiatric disorder that creates a substantial emotional and economic burden on individuals with the illness, their families, and society. Understanding the causes and identifying the molecular alterations in the brain that underlie the pathophysiology of core clinical features of schizophrenia are central to the development of new therapeutic interventions. In particular, schizophrenia is characterized by impairments in working memory, which are thought to result from a deficit in GABA neurotransmission in the dorsolateral prefrontal cortex (DLPFC). Interestingly, exposure to cannabis has been associated with an increased risk for developing schizophrenia and cannabis use is associated with DLPFC-related working memory impairments similar to those observed in schizophrenia. The effects of cannabis are mediated by the brain cannabinoid 1 (CB1) receptor, which in the rodent, is heavily localized to certain inhibitory axon terminals and, when activated, inhibits GABA release. Here, we have investigated the anatomical distribution of the CB1 receptor in the primate brain and characterized the cellular localization and synaptic targets of the CB1 receptor in the primate DLPFC. In addition, we explored the potential relationship between CB1 receptor signaling and altered GABA neurotransmission in schizophrenia by evaluating CB1 receptor mRNA and protein expression in the DLPFC of subjects with schizophrenia. We found that CB1 receptors are highly expressed in the primate DLPFC and that CB1 receptors are localized in the terminals of the subtype of perisomatic-targeting GABA interneurons that contain the neuropeptide cholecystokinin (CCK). We found that CB1 mRNA and protein are reduced in schizophrenia, which may represent a compensatory mechanism to increase GABA transmission from perisomatic-targeting CCK neurons with impaired GABA synthesis. We conclude that reductions in the expression of the CB1 receptor mRNA and protein in CCK neurons represent a novel neuropathological entity in the DLPFC of individuals with schizophrenia. These findings suggest a novel drug target for the treatment of cognitive dysfunction in schizophrenia

Dendritic vulnerability in neurodegenerative disease: insights from analyses of cortical pyramidal neurons in transgenic mouse models

Abstract In neurodegenerative disorders, such as Alzheimer's disease, neuronal dendrites and dendritic spines undergo significant pathological changes. Because of the determinant role of these highly dynamic structures in signaling by individual neurons and ultimately in the functionality of neuronal networks that mediate cognitive functions, a detailed understanding of these changes is of paramount importance. Mutant murine models, such as the Tg2576 APP mutant mouse and the rTg4510 tau mutant mouse have been developed to provide insight into pathogenesis involving the abnormal production and aggregation of amyloid and tau proteins, because of the key role that these proteins play in neurodegenerative disease. This review showcases the multidimensional approach taken by our collaborative group to increase understanding of pathological mechanisms in neurodegenerative disease using these mouse models. This approach includes analyses of empirical 3D morphological and electrophysiological data acquired from frontal cortical pyramidal neurons using confocal laser scanning microscopy and whole-cell patchclamp recording techniques, combined with computational modeling methodologies. These collaborative studies are designed to shed insight on the repercussions of dystrophic changes in neocortical neurons, define the cellular phenotype of differential neuronal vulnerability in relevant models of neurodegenerative disease, and provide a basis upon which to develop meaningful therapeutic strategies aimed at preventing, reversing, or compensating for neurodegenerative changes in dementia

Chronic Stress Effects on Prefrontal Cortical Structure and Function

Stressful life events have been implicated clinically in the pathogenesis of major depression, but the neural substrates that may account for this observation remain poorly understood. Attentional impairments symptomatic of depression are associated with structural and functional abnormalities in the prefrontal cortex. In three parallel rodent and human neuroimaging studies, this project assessed the effects of chronic stress on prefrontal cortical structure and function and the behavioral correlates of these changes. The first study used fMRI to elucidate the precise computational contributions of frontoparietal circuitry to attentional control in human subjects, using a task that could be adapted for rats. The results confirmed that the contributions of dorsolateral frontoparietal areas to visual attentional shifts could be dissociated from the regulatory influences of more ventrolateral areas on stimulus/response mappings, in a manner consistent with studies in animal models. They also indicated that anterior cingulate and posterior parietal cortex may act in concert to detect dissociable forms of information processing conflicts and signal to dorsolateral prefrontal cortex the need for increased attentional control. Stress-induced alterations in these regions and in the connections between them may therefore contribute to attentional impairments. The second study tested this hypothesis in rats by examining whether chronic stress effects on medial prefrontal (mPFC) and orbitofrontal (OFC) dendritic morphology underlie impairments in the behaviors that they subserve. Chronic stress induced a selective impairment in attentional control and a corresponding retraction of apical dendritic arbors in mPFC. By contrast, stress did not adversely affect reversal learning or OFC dendritic arborization. These results suggest that prefrontal dendritic remodeling may underlie the attentional deficits that are symptomatic of stress-related mental illness. The third study was designed to extend these findings to human subjects, using the techniques developed in Study 1. Accordingly, chronic stress predicted selective attentional impairments and alterations in prefrontal functional coupling that were reversible after four weeks. Together, these studies outline in broad strokes a mechanistic model by which chronic stress may predispose susceptible persons to the attentional impairments that are characteristic of major depression. Future studies will assess the roles of serotonin and neurotrophins in mediating these changes

Layer 3 pyramidal neurons of rhesus monkeys in aging and after ischemic injury

Layer 3 (L3) pyramidal neurons are involved in intrinsic and extrinsic corticocortical communications that are integral to area specific cortical functions. The functional and morphological properties of these neurons are altered in the lateral prefrontal cortex (LPFC) of aged rhesus monkeys, changes which parallel the decline of working memory (WM) function. What is not yet understood is the time course of these neuronal alternations during the aging process, or the impact of neuronal changes on the function of local networks that underlie WM. By comparing the properties of L3 pyramidal neurons from the LPFC of behaviorally characterized rhesus monkeys over the adult lifespan using whole cell patch clamp recordings and neuronal reconstructions, the present dissertation demonstrates that WM impairment, neuronal hyperexcitabilty and spine loss begin in middle age. We use bump attractor models to predict how empirically observed changes affect performance on the Delayed Response Task and Delayed Recognition Span Task (spatial). The performance of both models is affected much more by neuronal hyperexcitability than by synapse loss. In a separate study, we examine pathological changes of L3 pyramidal neurons in the perilesional ventral premotor cortex following acute ischemic injury to the primary motor cortex. Neurons from lesioned monkeys exhibit hyperexcitability and changes the excitatory:inhibitory synaptic balance in favor of inhibition. As oxidative stress and inflammation are known to exacerbate both age-related and injury-induced neuronal pathology, we characterize neuronal properties in both conditions after administering therapeutic interventions which target inflammatory pathways and which have previously been shown to ameliorate behavioral deficits. Chronic dietary curcumin treatment dampens neuronal hyperexcitability in middle-aged subjects, but the neuronal changes are not correlated with WM improvements. Treatment with mesenchymal-derived extracellular vesicles lowers firing rates and restores excitatory:inhibitory synaptic balance, and importantly, these changes correlate significantly with motor function

Social subordination alters estradiol-induced changes in cortico-limbic brain volumes in adult female rhesus monkeys

Women have a higher risk of developing stress-related disorders compared to men and the experience of a stressful life event is a potent risk-factor. The rodent literature suggests that chronic exposure to stressors as well as 17β-estradiol (E2) can result in alterations in neuronal structure in corticolimbic brain regions, however the translation of these data to humans is limited by the nature of the stressor experienced and issues of brain homology. To address these limitations, we used a well-validated rhesus monkey model of social subordination to examine effects of E2 treatment on subordinate (high stress) and dominant (low stress) female brain structure, including regional gray matter and white matter volumes using structural magnetic resonance imaging. Our results show that one month of E2 treatment in ovariectomized females, compared to control (no) treatment, decreased frontal cortex gray matter volume regardless of social status. In contrast, in the cingulate cortex, an area associated with stress-induced emotional processing, E2 decreased grey matter volume in subordinates but increased it in dominant females. Together these data suggest that physiologically relevant levels of E2 alter cortical gray matter volumes in females after only one month of treatment and interact with chronic social stress to modulate these effects on brain structure

Evolutionary appearance of von Economo's neurons in the mammalian cerebral cortex.

von Economo’s neurons (VENs) are large, spindle-shaped projection neurons in layer V of the frontoinsular (FI) cortex, and the anterior cingulate cortex. During human ontogenesis, the VENs can first be differentiated at late stages of gestation, and increase in number during the first eight postnatal months. VENs have been identified in humans, chimpanzee, bonobos, gorillas, orangutan and, more recently, in the macaque. Their distribution in great apes seems to correlate with human-like social cognitive abilities and self-awareness. VENs are also found in whales, in a number of different cetaceans, and in the elephant. This phylogenetic distribution may suggest a correlation among the VENs, brain size and the “social brain.” VENs may be involved in the pathogenesis of specific neurological and psychiatric diseases, such as autism, callosal agenesis and schizophrenia. VENs are selectively affected in a behavioral variant of frontotemporal dementia in which empathy, social awareness and self-control are seriously compromised, thus associating VENs with the social brain. However, the presence of VENs has also been related to special functions such as mirror self-recognition. Areas containing VENs have been related to motor awareness or sense-of-knowing, discrimination between self and other, and between self and the external environment. Along this line, VENs have been related to the “global Workspace” architecture: in accordance the VENs have been correlated to emotional and interoceptive signals by providing fast connections (large axons = fast communication) between salience-related insular and cingulate and other widely separated brain areas. Nevertheless, the lack of a characterization of their physiology and anatomical connectivity allowed only to infer their functional role based on their location and on the functional magnetic resonance imaging data. The recent finding of VENs in the anterior insula of the macaque opens the way to new insights and experimental investigations

The protracted maturation of associative layer IIIC pyramidal neurons in the human prefrontal cortex during childhood: a major role in cognitive development and selective alteration in autism

The human specific cognitive shift starts around the age of 2 years with the onset of self-awareness, and continues with extraordinary increase in cognitive capacities during early childhood. Diffuse changes in functional connectivity in children aged 2-6 years indicate an increase in the capacity of cortical network. Interestingly, structural network complexity does not increase during this time and, thus, it is likely to be induced by selective maturation of a specific neuronal subclass. Here, we provide an overview of a subclass of cortico-cortical neurons, the associative layer IIIC pyramids of the human prefrontal cortex. Their local axonal collaterals are in control of the prefrontal cortico-cortical output, while their long projections modulate inter-areal processing. In this way, layer IIIC pyramids are the major integrative element of cortical processing, and changes in their connectivity patterns will affect global cortical functioning. Layer IIIC neurons have a unique pattern of dendritic maturation. In contrast to other classes of principal neurons, they undergo an additional phase of extensive dendritic growth during early childhood, and show characteristic molecular changes. Taken together, circuits associated with layer IIIC neurons have the most protracted period of developmental plasticity. This unique feature is advanced but also provides a window of opportunity for pathological events to disrupt normal formation of cognitive circuits involving layer IIIC neurons. In this manuscript, we discuss how disrupted dendritic and axonal maturation of layer IIIC neurons may lead into global cortical disconnectivity, affecting development of complex communication and social abilities. We also propose a model that developmentally dictated incorporation of layer IIIC neurons into maturing cortico-cortical circuits between 2 to 6 years will reveal a previous (perinatal) lesion affecting other classes of principal neurons. This "disclosure" of pre-existing functionally silent lesions of other neuronal classes induced by development of layer IIIC associative neurons, or their direct alteration, could be found in different forms of autism spectrum disorders. Understanding the gene-environment interaction in shaping cognitive microcircuitries may be fundamental for developing rehabilitation and prevention strategies in autism spectrum and other cognitive disorders

The ACC is a critical hub for neuropathic pain- induced depression

Besides chronic stress, chronic pain is one of the prevalent determinants for depression. Indeed, around 50% of chronic pain patients develop mood disorders. Alterations in brain regions implicated in pain processing may also be involved in affective processing, thus potentially be responsible of mood disorders. However, the underlying mechanisms of this comorbidity are not yet elucidated. Here, we studied the role of the anterior cingulate cortex (ACC) in the somatosensory, aversive and anxiodepressive consequences of neuropathic pain. We showed that a permanent lesion or temporal inhibition of ACC pyramidal neurons blocked the development or suppressed the expression of an anxiodepressive phenotype in neuropathic mice. In addition, anxiodepressive-like behavior coincided with ACC hyperactivity. In conclusion we show that the ACC is a critical hub for neuropathic pain-induced depression

Alterations in GABA-related Transcripts in the Dorsolateral Prefrontal Cortex of Subjects with Schizophrenia

Alterations in GABA-related Transcripts in the Dorsolateral Prefrontal Cortex of Subjects with SchizophreniaHarvey M. Morris, Ph.D.University of Pittsburgh, 2009Besides the financial burden upon society, families undergo a substantial emotional burden when presented with a loved one affected by schizohprenia. Elucidation of the pathophysiology underlying the core features of schizophrenia is necessary for the development of more effective treatment targets. Cognitive deficits are regarded as a core feature of schizophrenia and are thought to arise from alterations in ã-aminobutyric acid (GABA)-containing interneurons in the dorsolateral prefrontal cortex (DLPFC). Specifically, postmortem studies have demonstrated decreased levels of the mRNA encoding the 67 kDa isoform of glutamic acid decarboxylase (GAD67), an enzyme that synthesizes GABA, and this alteration seems to be specific to certain subsets of GABA neurons. For example, parvalbumin and somatostatin mRNAs, which are expressed in separate subsets of GABA neurons, were decreased, whereas calretinin mRNA, expressed in a third subset of GABA neurons, was unchanged in schizophrenia. The studies in this thesis examined the compartmental and cellular expression of and the potential causal mechanisms of reductions in SST mRNA expression; furthermore, the disease and cellular specificity of and post-synaptic consequences of reductions in SST mRNA expression were examined. We found that reductions in the levels of SST mRNA appear to be restricted to SST interneurons that do not contain NPY mRNA in the gray matter and are due to reductions in expression per neuron. These alterations appear to be a consequence of impaired neurotrophin signaling through the trkB receptor. Also, the profile of alterations in GABA-related mRNA expression is specific to schizophrenia. Finally, a post-synaptic receptor of SST, SST receptor subtype 2 (SSTR2), mRNA is reduced in schizophrenia. Since the SST protein is putatively inhibitory and SST-containing interneurons target the distal dendrites of pyramidal neurons, these data suggest reduced inhibition of pyramidal neurons and may represent a compensatory mechanism to increase excitatory drive. We conclude that reductions in SST and SSTR2 mRNA represent a downstream consequence of a neuropathological entity in the DLPFC of individuals with schizophrenia and contribute to cognitive dysfunction in schizophrenia