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Browsing by Author "Lamb, Bruce"
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Item APOE4 Drives Impairment in Astrocyte-Neuron Coupling in Alzheimer's Disease and Works Through Mechanisms in Early Disease to Influence Pathology(2023-05) Brink, Danika Marie Tumbleson; Lamb, Bruce; Bissel, Stephanie; Herbert, Brittney-Shea; Landreth, Gary; Puntambekar, Shweta; Saykin, Andrew; Zhang, ChiAlzheimer’s disease (AD) is a neurodegenerative disorder resulting in progressive memory loss, brain atrophy, and eventual death. AD pathology is characterized by the accumulation of neurotoxic amyloid-beta (Aβ) plaques, synapse loss, neurofibrillary tangles (NFTs), and neurodegeneration. The APOE4 allele is associated with a 3-fold increased risk for AD and results in increased Aβ plaque deposition, reduced Aβ clearance, and reduced synaptic plasticity. Although APOE expression is upregulated in microglia in AD, APOE is expressed primarily by astrocytes in the CNS. It is not well understood how astrocytic APOE drives the mechanisms that result in worsened AD outcomes. Here, digital spatial profiling and bioinformatics data suggest that APOE4 causes transcriptional dysregulation in early AD and may disrupt neuronal processes via astrocytes. Whole transcriptome data from plaque and non-plaque regions in the cortices and hippocampus of 4- and 8-month-old AD model mice expressing humanized APOE4/4 or APOE3/3 (control) were analyzed. Transcriptional dysregulation was increased in APOE4/4 AD mice compared to that in APOE3/3 at 4 but not 8 months of age, suggesting that early dysregulation of APOE4-driven disease mechanisms may shape degenerative outcomes in late-stage AD. Additionally, APOE4/4 potentially functions via plaque-independent mechanisms to influence neuronal function in early AD before the onset of pathology. Single-nuclei RNA sequencing data were obtained from human post-mortem astrocytes and the bioinformatic analyses revealed a novel astrocyte subtype that highly expresses several top genes involved in functional alterations associated with APOE4, including neuronal generation, development, and differentiation, and synaptic transmission and organization. Overall, our findings indicate that APOE4 may drive degenerative outcomes through the presented astrocyte candidate pathways. These pathways represent potential targets for investigations into early intervention strategies for APOE4/4 patients.Item Neuron-Specific HuR-Deficient Mice Spontaneously Develop Motor Neuron Disease(The American Association of Immunologists, 2018-07-01) Sun, Kevin; Li, Xiao; Chen, Xing; Bai, Ying; Zhou, Gao; Kokiko-Cochran, Olga N.; Lamb, Bruce; Hamilton, Thomas A.; Lin, Ching-Yi; Lee, Yu-Shang; Herjan, Tomasz; Neuroscience, IU School of MedicineHuman Ag R (HuR) is an RNA binding protein in the ELAVL protein family. To study the neuron-specific function of HuR, we generated inducible, neuron-specific HuR-deficient mice of both sexes. After tamoxifen-induced deletion of HuR, these mice developed a phenotype consisting of poor balance, decreased movement, and decreased strength. They performed significantly worse on the rotarod test compared with littermate control mice, indicating coordination deficiency. Using the grip-strength test, it was also determined that the forelimbs of neuron-specific HuR-deficient mice were much weaker than littermate control mice. Immunostaining of the brain and cervical spinal cord showed that HuR-deficient neurons had increased levels of cleaved caspase-3, a hallmark of cell apoptosis. Caspase-3 cleavage was especially strong in pyramidal neurons and α motor neurons of HuR-deficient mice. Genome-wide microarray and real-time PCR analysis further indicated that HuR deficiency in neurons resulted in altered expression of genes in the brain involved in cell growth, including trichoplein keratin filament-binding protein, Cdkn2c, G-protein signaling modulator 2, immediate early response 2, superoxide dismutase 1, and Bcl2. The additional enriched Gene Ontology terms in the brain tissues of neuron-specific HuR-deficient mice were largely related to inflammation, including IFN-induced genes and complement components. Importantly, some of these HuR-regulated genes were also significantly altered in the brain and spinal cord of patients with amyotrophic lateral sclerosis. Additionally, neuronal HuR deficiency resulted in the redistribution of TDP43 to cytosolic granules, which has been linked to motor neuron disease. Taken together, we propose that this neuron-specific HuR-deficient mouse strain can potentially be used as a motor neuron disease model.Item Orbitofrontal Cortex and Social Processing in Rodent Models(2019-05) Andrews, Katharine DiAnn; Xu, Xiao-Ming; Lamb, Bruce; McAllister, Thomas; McDonald, Brenna; Truitt, William; Wu, Yu-ChienSocial processing is the reception, interpretation, and reciprocation of social information and is critical for mental health. The neural structures, circuits, and substrates regulating these complex mechanisms are not well understood. Social processing in the form of social safety learning, as measured by a rat model of social familiarity-induced anxiolysis (SoFiA), was impaired following mild blast traumatic brain injury (mbTBI). Initial findings indicated that mbTBI altered resting state network activity in the orbitofrontal cortex (OFC) and was associated with accumulation of neurotoxin marker, acrolein, in lateral prefrontal cortex (PFC) (including OFC), indicating OFC as a brain region of interest that may contribute to social processing. Measuring GABA and Glutamate-related gene expression in OFC of mbTBI or sham-exposed rat brain revealed specific elevations of metabotropic glutamate receptor type 1 and 5 (mGluR1/5) expression in mbTBI but not sham OFC. Exposure-naïve rats intracranially injected with mGluR1/5 agonist demonstrated attenuated SoFiA, and this coincided with an impairment of social recognition (SR) behavior. Additionally, inactivation of OFC by local intracranial injection of GABAA agonist, muscimol, impaired two different measures of SR in which two conspecifics, or members of the same species, one novel and one familiar, were presented and required discrimination. Novelty seeking, decision-making, memory, and gregariousness were tested in isolation to determine OFC contributions to these specific behavioral contributions to SR test performance. OFC inactivation did not impair novelty seeking, non-social decision-making, or non-social memory as measured by novel object recognition (NOR) test, or gregariousness or social decision-making as measure by social preference (SP) test. When measuring SR behavior via consecutive presentation of two different conspecifics, OFC inactivation did not impact SR. Therefore, OFC is not directly responsible for social recognition, but rather the discrimination or ability to act upon discrimination of two simultaneously present conspecifics. These data suggest a novel role for OFC in high order processing or execution of action based on social information.