Project description:Dominant mutations in profilin-1 (PFN1) are associated with amyotrophic lateral sclerosis (ALS), a fatal neurodegenerative disease characterized by motor neuron loss, paralysis, and death from respiratory failure. Our lab recently demonstrated that PFN1 mutant proteins are destabilized—they unfold at milder conditions during thermal and chemical denaturation. Furthermore, we and others have shown that mutant PFN1 is more prone to misfold and aggregate. This misfolding alters the protein-protein interactions of PFN1, as demonstrated by an immunoprecipitation-mass spectrometry (IP-MS) screen of wild-type and ALS-associated PFN1 variants. While ALS-associated mutants do not show loss of interaction, several variants have altered interactions with one or several formin family proteins, a group of proteins that interact with profilins to regulate actin polymerization.

Project description:Amyotrophic Lateral Sclerosis (ALS) is a rare neurodegenerative disease characterized by motor neuron dysfunction and loss, leading to progressive paralysis and death. A portion of ALS cases is caused by mutation of the proteasome shuttle factor Ubiquilin 2 (UBQLN2), but the molecular pathway leading from UBQLN2 dysfunction to neurodegenerative disease remains unclear. Here, we demonstrate a major function of UBQLN2 in regulating activity of the domesticated gag-pol retrotransposon ‘paternally expressed gene 10’ (PEG10) in human cells and tissues. UBQLN2 exclusively facilitates degradation of the frameshifted gag-pol form of PEG10 through recognition of a unique polyproline repeat. In cells, the PEG10 gag-pol protein cleaves itself in a mechanism reminiscent of retrotransposon self-processing to generate a liberated ‘nucleocapsid’ fragment, which uniquely localizes to the nucleus. Overexpression of the nucleocapsid fragment upregulates transcription of neuronal genes involved in axon remodeling, which were also affected in sporadic ALS (sALS) patient tissues. Finally, proteomics of spinal cords from ALS patients revealed that PEG10 gag-pol is significantly elevated in disease compared to healthy controls. These findings implicate the retrotransposon-like activity of PEG10 as a contributing mechanism in ALS through regulation of neuronal gene expression, and restraint of PEG10 as a primary function of UBQLN2.

Project description:In our study, we found that profilin 1 (PFN1) promoted non-small cell lung cancer (NSCLC) metastasis.For further investigate the mechanisms of PFN1's roles in NSCLC metastasis, we constructed PFN1 overxpression H1299 cell lines(H1299 PFN1 OE cells). And we sent samples of H1299 PFN1 OE cells and EV cells for TMT based quantative proteome profiling.

Project description:Amyotrophic lateral sclerosis (ALS) is a neurodegenerative disease characterized by progressive motor neuron loss, with additional pathophysiological involvement of non-neuronal cells such as microglia. The commonest ALS-associated genetic variant is a hexanucleotide repeat expansion (HRE) mutation in C9orf72. Here, we study its consequences for microglial function using human iPSC-derived microglia. By RNA-sequencing, we identify enrichment of pathways associated with immune cell activation and cyto-/chemokines in C9orf72 HRE mutant microglia versus healthy controls, most prominently after LPS priming. Specifically, LPS-primed C9orf72 HRE mutant microglia show consistently increased expression and release of matrix metalloproteinase-9 (MMP9). LPS-primed C9orf72 HRE mutant microglia are toxic to co-cultured healthy motor neurons, which is ameliorated by concomitant application of an MMP9 inhibitor. Finally, we identify release of dipeptidyl peptidase-4 (DPP4) as a marker for MMP9-dependent microglial dysregulation in co-culture. These results demonstrate cellular dysfunction of C9orf72 HRE mutant microglia, and a non-cell-autonomous role in driving C9orf72-ALS pathophysiology in motor neurons through MMP9 signaling.

Project description:Microglia, the immune cells of the central nervous system (CNS), play critical roles in brain physiology and pathology. We report a novel approach that produces within ten days the differentiation of human induced pluripotent stem cells (hiPSCs) into microglia (iMG) by forced expression of both SPI1 and CEBPA. High-level expression of the main microglial markers and the purity of the iMG cells were confirmed by RT-qPCR, immunostaining and flow cytometry analyses. Whole transcriptome analysis demonstrated that these iMGs resemble human fetal/adult microglia but not human monocytes. Moreover, these iMGs exhibited appropriate physiological functions, including various inflammatory responses, ADP/ATP-evoked migration and phagocytic ability. When co-cultured with hiPSC-derived neurons (iNs), the iMGs respond and migrate toward injured neurons. This study has established a protocol for the rapid conversion of hiPSCs into functional iMGs, which should facilitate functional studies of human microglia using different disease models and also help with drug discovery.

Project description:We used a model to induce patient-derived microglia-like cells (iMGs) to clarify the molecular characteristics and function of Panic disorder patient-iMGs (PD-iMGs). We established iMGs from 14 PD patients and 10 healthy controls (non-psychiatric controls, HC). We analyzed the phenotype of the PD-iMGs by RNA sequencing. The PD-iMGs clustered together distinct from HC-iMGs. Gene set enrichment analysis revealed the involvement of cholesterol biosynthesis and steroid metabolism in PD-iMGs.

Project description:Amyotrophic Lateral Sclerosis (ALS) is a fatal neurodegenerative disease that leads to the loss of motor neurons. The molecular mechanisms of motor neuron degeneration are largely unknown and there are currently no effective therapies to treat this disease. Cases of familial ALS have been linked to mutations in the profilin1 gene (PFN1) and here we utilize the in vivo mouse model of PFN1-related motor neuron disease, hPFN1G118V. We conducted whole transcriptome profiling of spinal cords of mutant transgenic hPFN1G118V mice and their wildtype transgenic hPFN1WT controls at 50 days, a presymptomatic stage and the earliest known time point at which aggregation of PFN1G118V occurs, and at end stage of disease, beginning around 180 days. The overall transcriptome profiles of spinal cord were highly similar while end stage hPFN1G118V mice had gene expression that clustered away from hPFN1WT and presymptomatic hPFN1G118V mice. Differential expression analysis revealed that end stage hPFN1G118V mice had 890 differentially expressed genes (747 up and 143 down) when compared to pre-symptomatic hPFN1G118V mice, and they had 836 differentially expressed genes (742 up and 94 down) when compared to their age-matched hPFN1WT controls. 50 day old hPFN1G118V mice were not significantly different from their age matched hPFN1WT controls. This is the first study that has utilized next generation RNA-sequencing to measure gene expression in pre-symptomatic and end-stage hPFN1G118V mice, and may lead to identification of molecular features that could become therapeutic targets for ALS.

Project description:Burgeoning evidence highlights seminal roles for microglia in the pathogenesis of neurodegenerative diseases including amyotrophic lateral sclerosis (ALS). The receptor for advanced glycation end products (RAGE) binds ligands relevant to ALS that accumulate in the diseased spinal cord and RAGE has been previously implicated in the progression of ALS pathology. We generated a novel mouse model to temporally delete Ager from microglia in the murine SOD1G93A model of ALS. Microglia Ager deficient SOD1G93A mice and controls were examined for changes in survival, motor function, gliosis, motor neuron numbers, and transcriptomic analyses of lumbar spinal cord. Furthermore, we examined bulk-RNA-sequencing transcriptomic analyses of human ALS cervical spinal cord. Transcriptomic analysis of human cervical spinal cord reveals a range of AGER expression in ALS patients, which was negatively correlated with age at disease onset and death or tracheostomy. The degree of AGER expression related to differential expression of pathways involved in extracellular matrix, lipid metabolism, and intercellular communication. Microglia display increased RAGE immunoreactivity in the spinal cords of high AGER expressing patients and in the SOD1G93A murine model of ALS vs. respective controls. We demonstrate that microglia Ager deletion at the age of symptomatic onset, day 90, in SOD1G93A mice extends survival in male but not female mice. Critically, many of the pathways identified in human ALS patients that accompanied increased AGER expression were significantly ameliorated by microglia Ager deletion in male SOD1G93A mice. Our results indicate that microglia RAGE disrupts communications with cell types including astrocytes and neurons, intercellular communication pathways that divert microglia from a homeostatic to an inflammatory and tissue-injurious program. In totality, microglia RAGE contributes to the progression of SOD1G93A murine pathology in male mice and may be relevant in human disease.

Project description:To compare the proteome between PFN1 mutant and PFN1 WT iPSC-microglia under baseline conditions

Project description:Amyotrophic lateral sclerosis (ALS) is a neurodegenerative disease in which motor neurons throughout the brain and spinal cord progressively degenerate resulting in muscle atrophy, paralysis and death. Recent studies using animal models of ALS implicate multiple cell-types (e.g., astrocytes and microglia) in ALS pathogenesis in the spinal motor systems. To ascertain cellular vulnerability and cell-type specific mechanisms of ALS in the brainstem that orchestrates oral-motor functions, we conducted parallel single cell RNA sequencing (scRNA-seq) analysis using the high-throughput Drop-seq method. We isolated 1894 and 3199 cells from the brainstem of wildtype and mutant SOD1 symptomatic mice respectively, at postnatal day 100. We recovered major known cell types and neuronal subpopulations, such as interneurons and motor neurons, and trigeminal ganglion (TG) peripheral sensory neurons, as well as, previously uncharacterized interneuron subtypes. We found that the majority of the cell types displayed transcriptomic alterations in ALS mice. Differentially expressed genes (DEGs) of individual cell populations revealed cell-type specific alterations in numerous pathways, including previously known ALS pathways such as inflammation (in microglia), stress response (ependymal and an uncharacterized cell population), neurogenesis (astrocytes, oligodendrocytes, neurons), synapse organization and transmission (microglia, oligodendrocyte precursor cells, and neuronal subtypes), and mitochondrial function (uncharacterized cell populations). Other cell-type specific processes altered in SOD1 mutant brainstem include those from motor neurons (axon regeneration, voltage-gated sodium and potassium channels underlying excitability, potassium ion transport), trigeminal sensory neurons (detection of temperature stimulus involved in sensory perception), and cellular response to toxic substances (uncharacterized cell populations). DEGs consistently altered across cell types (e.g., Malat1), as well as cell-type specific DEGs, were identified. Importantly, DEGs from various cell types overlapped with known ALS genes from the literature and with top hits from an existing human ALS genome-wide association study (GWAS), implicating the potential cell types in which the ALS genes function with ALS pathogenesis. Our molecular investigation at single cell resolution provides comprehensive insights into the cell types, genes and pathways altered in the brainstem in a widely used ALS mouse model.