Browsing by Author "Lee, Yu-Shang"

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    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 Medicine
    Human 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.
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    Traumatic brain injury in hTau model mice: Enhanced acute macrophage response and altered long-term recovery
    (Liebert, 2017) Kokiko-Cochran, Olga N.; Saber, Maha; Puntambekar, Shweta; Bemiller, Shane; Katsumoto, Atsuko; Lee, Yu-Shang; Bhaskar, Kiran; Ransohoff, Richard M.; Lamb, Bruce T.; Department of Medical and Molecular Genetics, School of Medicine
    TBI induces widespread neuroinflammation and accumulation of microtubule associated protein tau (MAPT) - two key pathological features of tauopathies. This study sought to characterize the microglial/macrophage response to TBI in genomic-based MAPT transgenic mice in a Mapt knockout background (called hTau). Two-month-old hTau and age-matched control male and female mice received a single lateral fluid percussion TBI or sham injury. Separate groups of mice were aged to an acute (3 days post-injury [DPI]) or chronic (135 DPI) post-injury time point. As judged by tissue immunostaining for macrophage markers, microglial/macrophage response to TBI was enhanced at 3 DPI in hTau mice compared to control TBI and sham mice. However, MAPT phosphorylation increased in hTau mice regardless of injury group. Flow cytometric analysis revealed distinct populations of microglia and macrophages within all groups at 135 DPI. Unexpectedly, microglial reactivity was significantly reduced in hTau TBI mice compared to all other groups. Instead, hTau TBI mice showed a persistent macrophage response. In addition, TBI enhanced MAPT pathology in the temporal cortex and hippocampus of hTau TBI mice compared to controls 135 DPI. A battery of behavioral test revealed that TBI in hTau mice resulted in compromised use of spatial search strategies to complete a water maze task despite lack of motor or visual deficits. Collectively, these data indicate that the presence of wild-type human tau alters the microglial/macrophage response to a single TBI, induces delayed, region-specific MAPT pathology, and alters cognitive recovery; however, the causal relationship between these events remains unclear. These results highlight the potential significance of communication between MAPT and microglia/macrophages following TBI and emphasize the role of neuroinflammation in post-injury recovery.