Morphological Alterations In Hippocampus Research Articles

Genetically Predicted Brain C4A Expression Is Associated With TSPO and Hippocampal Morphology

BackgroundAlterations in the immune system, particularly C4A, have been implicated in the pathophysiology of schizophrenia. C4A promotes synapse elimination by microglia in preclinical models; however, it is unknown whether this process is also present in living humans and how it affects brain morphology. MethodsParticipants (N = 111; 33 patients with psychosis, 37 individuals at clinical high risk, and 41 healthy control subjects) underwent a TSPO [18F]FEPPA positron emission tomography scan and a magnetic resonance imaging scan. Brain C4A expression was genetically predicted as a function of the dosage of each of 4 structural elements (C4AL, C4BL, C4AS, C4BS). ResultsHigher genetically predicted brain C4A expression was associated with higher brain microglial marker (TSPO) and altered hippocampal morphology, including reduced surface area and medial displacement in the CA1 area. This study is the first to quantify genetically predicted brain C4A expression in individuals at clinical high risk, showing significantly lower C4A in individuals at clinical high risk compared with healthy control subjects. We also showed a robust effect of sex on genetically predicted brain C4A expression and effects of both sex and cannabis use on brain TSPO. ConclusionsThis study shows for the first time complement system (C4A) coupling with a microglial marker (TSPO) and hippocampal morphology in living human brain. These findings pave the way for future research on the interaction between C4A and glial cell function, which has the potential to inform the disease mechanism underlying psychosis and schizophrenia.

Metabolomic profiling on rat brain of prenatal malnutrition: implicated for oxidative stress and schizophrenia.

Schizophrenia is a kind of neurodevelopmental disease. Epidemiological data associates schizophrenia with prenatal exposure to famine. Relevant prenatal protein deprivation (PPD) rodent models support this result by observing decreasing prepulse inhibition, altered hippocampal morphology and impaired memory in offspring. All these abnormalities are highly consistent with the pathophysiology of schizophrenia. We developed a prenatal famine rat model by restricting daily diet of the pregnant rat to 50% of low protein diet. A metabolomics study of prefrontal cortex was performed to integrate GC-TOFMS and UPLC-QTOFMS. Thirteen controls and thirteen famine offspring were used to differentiate in PLS-DA (partial least squares-discriminate analysis) model. Furthermore, metabolic pathways and diseases were enriched via KEGG and HMDB databases, respectively. A total of 67 important metabolites were screened out according to the multivariate analysis. Schizophrenia was the most statistical significant disease (P = 0.0016) in our famine model. These metabolites were enriched in key metabolic pathways related to energy metabolism and glutamate metabolism. Based on these important metabolites, further discussion speculated famine group was characterized by higher level of oxidized damage compared to control group. We proposed that oxidative stress might be the pathogenesis of prenatal undernutrition which is induced schizophrenia.

S169. MICROGLIAL ACTIVATION AND MORPHOLOGICAL BRAIN ALTERATIONS IN PSYCHOSIS AND PSYCHOSIS RISK

BackgroundAbnormal brain structural alterations and microglial activation are implicated in the pathophysiology of psychosis. However, the connection between these two pathologies is not yet well understood. Although previous studies suggested a link between the level of proinflammatory cytokines and abnormalities in brain structure in patients with schizophrenia, there is no in-vivo study investigating whether microglial activation is also linked to morphological brain alterations previously reported in individuals with psychosis and psychosis risk.MethodsIn order to address the current gap in the literature, we investigated microglial activation and structural brain abnormalities in key brain regions affected in psychosis (i.e. hippocampus and dorsolateral prefrontal cortex) of a large group of participants (N = 90) including 35 individuals at clinical high risk (CHR) for psychosis, 27 first-episode psychosis (mostly antipsychotic naïve) patients, and 28 healthy volunteers. All the participants underwent a [18F]FEPPA positron emission tomography (PET) targeting mitochondrial 18 kDa translocator protein (TSPO) to determine microglial activation and a T1 MRI scan to study structural brain characteristics including brain volume, cortical thickness, and hippocampal shape.ResultsUsing a vertex-wise analysis, we observed a significant microglial activation-by-diagnostic group interaction in morphological measures across the left hippocampus. We observed associations between microglial activation and outward and inward morphological alterations in the dorsal and ventro-medial portions of the left hippocampus, respectively. These associations were only observed in first-episode psychosis group. There was no association between [18F]FEPPA binding and other structural brain characteristics.DiscussionOur results, for the first time, suggest a connection between microglial activation and morphological alterations in hippocampus of first-episode psychosis.

The hippocampi of children with chromosome 22q11.2 deletion syndrome have localized anterior alterations that predict severity of anxiety

Individuals with 22q11.2 deletion syndrome (22q11.2DS) have an elevated risk for schizophrenia, which increases with history of childhood anxiety. Altered hippocampal morphology is a common neuroanatomical feature of 22q11.2DS and idiopathic schizophrenia. Relating hippocampal structure in children with 22q11.2DS to anxiety and impaired cognitive ability could lead to hippocampus-based characterization of psychosis-proneness in this at-risk population. We measured hippocampal volume using a semiautomated approach on MRIs collected from typically developing children and children with 22q11.2DS. We then analyzed hippocampal morphology with Localized Components Analysis. We tested the modulating roles of diagnostic group, hippocampal volume, sex and age on local hippocampal shape components. Lastly, volume and shape components were tested as covariates of IQ and anxiety. We included 48 typically developing children and 69 children with 22q11.2DS in our study. Hippocampal volume was reduced bilaterally in children with 22q11.2DS, and these children showed greater variation in the shape of the anterior hippocampus than typically developing children. Children with 22q11.2DS had greater inward deformation of the anterior hippocampus than typically developing children. Greater inward deformation of the anterior hippocampus was associated with greater severity of anxiety, specifically fear of physical injury, within the 22q11.2DS group. Shape alterations are not specific to hippocampal subfields. Alterations in the structure of the anterior hippocampus likely affect function and may impact limbic circuitry. We suggest these alterations potentially contribute to anxiety symptoms in individuals with 22q11.2DS through modulatory pathways. Altered hippocampal morphology may be uniquely linked to anxiety risk factors for schizophrenia, which could be a powerful neuroanatomical marker of schizophrenia risk and hence protection.

Adult Hippocampal Neurogenesis and mRNA Expression are Altered by Perinatal Arsenic Exposure in Mice and Restored by Brief Exposure to Enrichment

Arsenic is a common and pervasive environmental contaminant found in drinking water in varying concentrations depending on region. Exposure to arsenic induces behavioral and cognitive deficits in both human populations and in rodent models. The Environmental Protection Agency (EPA) standard for the allotment of arsenic in drinking water is in the parts-per-billion range, yet our lab has shown that 50 ppb arsenic exposure during development can have far-reaching consequences into adulthood, including deficits in learning and memory, which have been linked to altered adult neurogenesis. Given that the morphological impact of developmental arsenic exposure on the hippocampus is unknown, we sought to evaluate proliferation and differentiation of adult neural progenitor cells in the dentate gyrus after 50 ppb arsenic exposure throughout the perinatal period of development in mice (equivalent to all three trimesters in humans) using a BrdU pulse-chase assay. Proliferation of the neural progenitor population was decreased by 13% in arsenic-exposed mice, but was not significant. However, the number of differentiated cells was significantly decreased by 41% in arsenic-exposed mice compared to controls. Brief, daily exposure to environmental enrichment significantly increased proliferation and differentiation in both control and arsenic-exposed animals. Expression levels of 31% of neurogenesis-related genes including those involved in Alzheimer’s disease, apoptosis, axonogenesis, growth, Notch signaling, and transcription factors were altered after arsenic exposure and restored after enrichment. Using a concentration previously considered safe by the EPA, perinatal arsenic exposure altered hippocampal morphology and gene expression, but did not inhibit the cellular neurogenic response to enrichment. It is possible that behavioral deficits observed during adulthood in animals exposed to arsenic during development derive from the lack of differentiated neural progenitor cells necessary for hippocampal-dependent learning. This study is the first to determine the impact of arsenic exposure during development on adult hippocampal neurogenesis and related gene expression.

Detection of altered hippocampal morphology in multiple sclerosis-associated depression using automated surface mesh modeling

Depression is very common in multiple sclerosis (MS) but the underlying biological mechanisms are poorly understood. The hippocampus plays a key role in mood regulation and is implicated in the pathogenesis of depression. This study utilizes volumetric and shape analyses of the hippocampus to characterize neuroanatomical correlates of depression in MS. A cross-section of 109 female patients with MS was evaluated. Bilateral hippocampi were segmented from MRI scans (volumetric T1 -weighted, 1 mm(3) ) using automated tools. Shape analysis was performed using surface mesh modeling. Depression was assessed using the Center for Epidemiologic Studies-Depression (CES-D) scale. Eighty-three subjects were classified as low depression (CES-D 0-20) versus 26 subjects with high depression (CES-D ≥ 21). Right hippocampal volumes (P = 0.04) were smaller in the high depression versus the low depression groups, but there was no significant difference in left hippocampal volumes. Surface rendering analysis revealed that hippocampal shape changes in depressed patients with MS were clustered in the right hippocampus. Significant associations were found between right hippocampal shape and affective symptoms but not vegetative symptoms of depression. Our results suggested that regionally clustered reductions in hippocampal thickness can be detected by automated surface mesh modeling and may be a biological substrate of MS depression in female patients.

Effects of risperidone treatment in adolescence on hippocampal neurogenesis, parvalbumin expression, and vascularization following prenatal immune activation in rats

Maternal infection in pregnancy is an environmental risk factor for the development of schizophrenia and related disorders in the offspring, and this association is recapitulated in animal models using gestational infection or immune stimulation. We have recently shown that behavioral abnormalities and altered hippocampal morphology emerging in adult offspring of dams treated with the viral mimic polyriboinosinic-polyribocytidilic acid (poly I:C) are prevented by treatment with the atypical antipsychotic drug risperidone (RIS) in adolescence. Here we used a battery of cellular markers and Nissl stain to morphometrically analyze different hippocampal cell populations in the offspring of poly I:C and saline-treated mothers that received saline or RIS in adolescence, at different time points of postnatal development. We report that impaired neurogenesis, disturbed micro-vascularization and loss of parvalbumin-expressing hippocampal interneurons, are found in the offspring of poly I:C-treated dams. Most, but not all, of these neuropathological changes are not present in poly I:C offspring that had been treated with RIS. These effects may be part of the complex processes underlying the capacity of RIS treatment in adolescence to prevent structural and behavioral abnormalities deficits in the poly I:C offspring.

Serial analysis of gene expression in the hippocampus of patients with mesial temporal lobe epilepsy

Hippocampal sclerosis constitutes the most frequent neuropathological finding in patients with medically intractable mesial temporal lobe epilepsy. Serial analysis of gene expression was used to get a global view of the gene profile in human hippocampus in control condition and in epileptic condition associated with hippocampal sclerosis. Libraries were generated from control hippocampus, obtained by rapid autopsy, and from hippocampal surgical specimens of patients with mesial temporal lobe epilepsy and the classical pattern of hippocampal sclerosis. More than 50,000 tags were analyzed (28,282, control hippocampus; 25,953, hippocampal sclerosis) resulting in 9206 (control hippocampus) and 9599 (hippocampal sclerosis) unique tags (genes), each representing a specific mRNA transcript. Comparison of the two libraries resulted in the identification of 143 transcripts that were differentially expressed. These genes belong to a variety of functional classes, including basic metabolism, transcription regulation, protein synthesis and degradation, signal transduction, structural proteins, regeneration and synaptic plasticity and genes of unknown identity of function. The database generated by this study provides an extensive inventory of genes expressed in human control hippocampus, identifies new high-abundant genes associated with altered hippocampal morphology in patients with mesial temporal lobe epilepsy and serves as a reference for future studies aimed at detecting hippocampal transcriptional responses under various pathological conditions.

Cytoskeletal, synaptic, and nuclear protein changes associated with rat interface organotypic hippocampal slice culture development

Although organotypic hippocampal slice cultures (OHSCs) are used to study function within the hippocampus, the effect of maintenance in vitro upon protein expression is not fully understood. Therefore, we examined developmental changes in cultures prepared from P8 rats and maintained on porous membranes between medium and atmosphere. Between 7 and 28 days following explantation, altered hippocampal morphology could not be detected despite a significant decrease in both MAP-2c and a mid-range tau isoform by 21 DIV. During the same period, lower GFAP expression was observed, and GFAP labeling suggested a migration of astrocytes to the slice–atmosphere interface. In contrast, levels of the synaptic proteins synaptophysin and PSD-95 were significantly increased, but GAP-43 was not. The preservation of myelinated axons and synapses, along with glial and endothelial cells, was confirmed by ultrastructural analysis. Furthermore, intranuclear inclusion bodies, which are associated with normal aging in vivo, were detected in the CA1 pyramidal layer in cultures older than 14 DIV. When OHSCs were maintained for approximately 3, 4, and 10 weeks, a rise and then fall in the expression of synaptophysin and, especially, PSD-95 were found, and the biphasic trend paralleled by significant changes in Schaffer collateral-evoked excitatory post-synaptic potentials from CA1 neurons. Our data not only describe changes in cytoskeletal, synaptic, and nuclear proteins related to the maintenance of interface OHSCs, but also emphasize the potential of the model for the study of age-related phenomena within the hippocampus.

A neurogenic theory of depression gains momentum.

The rate of adult neurogenesis fluctuates in response to several environmental factors. Chronic stress, which can lead to neuronal apoptosis and dendritic atrophy, certainly affects the overall rate of neurogenesis in the adult brain. Depression, which arises from several causes, including chronically stressful situations, is known to correlate with altered hippocampal morphology. But is the link between depression and neuronal regeneration merely coincidental? Recent studies indicate that ingestion of antidepressants leads to increased neurogenesis in the hippocampus. However, the hippocampus is generally thought important for learning and memory-not for "mood" state-thus, there is much more to the story that requires clarification. Also, caveats abound in the interpretation of neurogenesis in the amelioration of depression; nonetheless, these results are quite intriguing and might point to better design and prediction of new-generation antidepressants.

Serial analysis of gene expression predicts structural differences in hippocampus of long attack latency and short attack latency mice

The genetically selected long attack latency (LAL) and short attack latency (SAL) mice differ in a wide variety of behavioural traits and display differences in the serotonergic system and the hypothalamus-pituitary-adrenocortical (HPA)-axis. Serial analysis of gene expression (SAGE) was used to generate a hippocampal expression profile of almost 30 000 genes in LAL and SAL mice. Using SAGE, we found differential expression of 191 genes. Among these were genes involved in growth, signal transduction, and cell metabolism. The SAGE study was supported by GeneChip analysis (Affymetrix). Strikingly, both SAGE and GeneChips showed a higher expression of numerous cytoskeleton genes, such as cofilin and several tubulin isotypes in LAL mice. LAL mice also showed a higher expression of several calmodulin-related genes and genes encoding components of a MAPK cascade, namely raf-related oncogene and ERK2. The findings were confirmed by in situ hybridization. Our results of differential expression of cytoskeleton and signal transduction genes therefore suggest differential regulation of the raf/ERK pathway that may be related to structural differences in the hippocampus of LAL and SAL mice. As stress-related disorders, such as depression, are also linked to differential regulation of the HPA-axis and the serotonergic system and are associated with altered hippocampal morphology, differential regulation of these genes may be involved in the pathogenesis of these diseases.

A Twin Study of Genetic Contributions to Hippocampal Morphology in Schizophrenia

Our goal was to establish whether altered hippocampal morphology represents a trait marker for genetic vulnerability in schizophrenia. We outlined the hippocampi on high-resolution MR images obtained from matched samples of control and discordant monozygotic and dizygotic co-twins ( N = 40 pairs). Hippocampal measures were used in statistical tests specifically designed to identify disease-associated genetic and nongenetic influences on morphology. 3D surface average maps of the hippocampus were additionally compared in biological risk groups. Smaller hippocampal volumes were confirmed in schizophrenia. Dizygotic affected co-twins showed smaller left hippocampi compared to their healthy siblings. Disease-associated effects were not present between monozygotic discordant co-twins. Monozygotic, but not dizygotic, unaffected co-twins exhibited smaller left hippocampi compared to control twins, supporting genetic influences. Surface areas and posterior volumes similarly revealed schizophrenia and genetic liability effects. Results suggest that hippocampal volume reduction may be a trait marker for identifying individuals possessing a genetic predisposition for schizophrenia.

Adult neurogenesis: implications for psychiatry

The fields of psychiatry and neuroscience have formed a close relationship over the past decades. Hypotheses about the neurochemical basis of behavioral dysfunction helped in part to develop promising treatments for several psychiatric disorders, including depression, addiction and schizophrenia. In addition to advancing the neurochemical approach to psychiatric disorders, the relationship between psychiatry and neuroscience also fostered an appreciation for the role neuroanatomy plays in brain function and dysfunction. The productivity of this marriage between the brain structure and brain function approaches is evident in the large literature on neuroanatomical alterations associated with psychiatric disorders. In particular, altered morphology of limbic structures, such as the prefrontal cortex and hippocampus, has been associated with many psychiatric disorders. Depression, post-traumatic stress disorder (PTSD), dementia, schizophrenia and drug dependence have all been linked to decreased volume of limbic-related structures and altered hippocampal morphology (Carlen and Wilkinson, 1987; McEwen and Sapolsky, 1995; Sheline et al., 1996; Bartzokis et al., 2000; Benes and Berretta, 2000). Clini-

Morphological alterations in hippocampus after long-term alcohol consumption in mice.

Golgi methods were used to examine the hippocampus of laboratory mice that received alcohol-containing or control diets for 4 months followed by a 2-month alcohol-free period. Long-term alcohol consumption resulted in a significant loss of dendritic spines on hippocampal pyramidal cells and dentate granule cells. This study provides evidence that long-term alcohol consumption, in the absence of malnutrition, produces morphological damage to the central nervous system.