MUTATIONS OF FUS CAUSE AGGREGATION OF RNA BINDING PROTEINS, DISRUPTIONS IN PROTEIN SYNTHESIS, AND DYSREGULATION OF NONSENSE MEDIATED DECAY

Amyotrophic lateral sclerosis (ALS) is a fatal neurodegenerative disease characterized by motor neuron death and subsequent muscle atrophy. Approximately 15% of ALS cases are inheritable, and mutations in the Fused in Sarcoma (FUS) gene contribute to approximately 5% of these cases, as well as about 2% of sporadic cases. FUS performs a diverse set of cellular functions, including being a major regulator of RNA metabolism. FUS undergoes liquid- liquid phase transition in vitro, allowing for its participation in stress granules and RNA transport granules. Phase transition also contributes to the formation of cytoplasmic inclusions found in the cell bodies of FUS ALS patients motor neurons. The nature of these inclusions has remained elusive, as the proteins localized to them have not been identified. Additionally, the functional consequence of the accumulation of cytoplasmic FUS inclusions has not been established, nor is it understood how they contribute to selective motor neuron death. We carried out two related, but independent studies to characterize the proteins that may be included in FUS-positive inclusions. In this first study, we utilized immunoprecipitation of wild-type and mutant FUS in the presence and absence of RNase, followed by LC MS/MS. The identified proteins represent those that directly or indirectly interact with FUS, with relatively high affinity that can be pulled down with immunoprecipitation. A wide variety of interacting proteins were identified and they are involved in a multitude of pathways including: chromosomal organization, transcription, RNA splicing, RNA transport, localized translation, and stress response. Their interaction with FUS varied greatly in their requirements for RNA. Most notably, FUS interacted with hnRNPA1 and Matrin-3, proteins also known to cause familial ALS. Immunofluorescent staining of proteins interacting with mutant FUS were localized to cytoplasmic inclusions. We concluded that mis-localization of these proteins potentially lead to their dysregulation or loss of function, thus contributing to FUS pathogenesis. In the second study, we developed a protocol to isolate dynamic FUS inclusions and employed LC MS/MS to identify all proteins associated with FUS inclusions. We identified a cohort of proteins involved in translation, splicing, and RNA export to be associated with the FUS inclusions. Further pathway and disease association analysis suggested that proteins associated with translation and RNA quality control pathways may be the most significant. Protein translation assays using both N2A and ALS patient fibroblasts demonstrated suppression of protein biosynthesis in mutant FUS expressing cells. However, translation initiation was not impaired. To understand how protein synthesis is suppressed by mutant FUS mediated defects in RNA metabolism, we examined changes in a well conserved RNA turnover pathway namely: nonsense mediated decay (NMD). We found that NMD is hyperactivated in cells expressing mutant FUS, likely due to chronic suppression of protein translation shifting the pathways autoregulatory circuit to allow for hyperactivation. We concluded that mutant FUS suppresses protein biosynthesis and disrupts NMD regulation. These defects together likely contribute to motor neuron death

ALS Mutations of FUS Suppress Protein Translation and Disrupt the Regulation of Nonsense-Mediated Decay

Amyotrophic lateral sclerosis (ALS) is an incurable neurodegenerative disease characterized by preferential motor neuron death. Approximately 15% of ALS cases are familial, and mutations in the fused in sarcoma (FUS) gene contribute to a subset of familial ALS cases. FUS is a multifunctional protein participating in many RNA metabolism pathways. ALS-linked mutations cause a liquid–liquid phase separation of FUS protein in vitro, inducing the formation of cytoplasmic granules and inclusions. However, it remains elusive what other proteins are sequestered into the inclusions and how such a process leads to neuronal dysfunction and degeneration. In this study, we developed a protocol to isolate the dynamic mutant FUS-positive cytoplasmic granules. Proteomic identification of the protein composition and subsequent pathway analysis led us to hypothesize that mutant FUS can interfere with protein translation. We demonstrated that the ALS mutations in FUS indeed suppressed protein translation in N2a cells expressing mutant FUS and fibroblast cells derived from FUS ALS cases. In addition, the nonsense-mediated decay (NMD) pathway, which is closely related to protein translation, was altered by mutant FUS. Specifically, NMD-promoting factors UPF1 and UPF3b increased, whereas a negative NMD regulator, UPF3a, decreased, leading to the disruption of NMD autoregulation and the hyperactivation of NMD. Alterations in NMD factors and elevated activity were also observed in the fibroblast cells of FUS ALS cases. We conclude that mutant FUS suppresses protein biosynthesis and disrupts NMD regulation, both of which likely contribute to motor neuron death

Clinical and Experimental Studies of a Novel P525R FUS Mutation in Amyotrophic Lateral Sclerosis

Objective: To describe the clinical features of a novel fused in sarcoma (FUS) mutation in a young adult female amyotrophic lateral sclerosis (ALS) patient with rapid progression of weakness and to experimentally validate the consequences of the P525R mutation in cellular neuronal models. Methods: We conducted sequencing of genomic DNA from the index patient and her family members. Immunocytochemistry was performed in various cellular models to determine whether the newly identified P525R mutant FUS protein accumulated in cytoplasmic inclusions. Clinical features of the index patient were compared with 19 other patients with ALS carrying the P525L mutation in the same amino acid position. Results: A novel mutation c.1574C\u3eG (p.525P\u3eR) in the in the FUS gene was identified in the index patient. The clinical symptoms are similar to those in familial ALS patients with the P525L mutation at the same position. The P525R mutant FUS protein showed cytoplasmic localization and formed large stress granule–like cytoplasmic inclusions in multiple cellular models. Conclusions: The clinical features of the patient and the cytoplasmic inclusions of the P525R mutant FUS protein strengthen the notion that mutations at position 525 of the FUS protein result in a coherent phenotype characterized by juvenile or young adult onset, rapid progression, variable positive family history, and female preponderance

Featured Review Article Cytoskeleton targeting value in prostate cancer treatment

Abstract: Prostate cancer is a disease that affects hundreds of thousands of men in the United States each year. In the early stages of advanced prostate cancer, the disease can be suppressed by androgen deprivation therapy (ADT). Eventually, however, most patients experience resistance to androgen deprivation, and their treatment transitions to alternative targeting of the androgen axis with abiraterone and enzalutamide, as well as taxane-based chemotherapy. Development of advanced castration-resistant prostate cancer (CRPC) is a consequence of lack of an apoptotic response by the tumor cells to treatment. Understanding the mechanisms contributing to prostate tumor therapeutic resistance and progression to metastasis requires dissection of the signaling mechanisms navigating tumor invasion and metastasis as mediated by cell-matrix interactions engaging components of the extracellular matrix (ECM), to form adhesion complexes. For a tumor call to metastasize from the primary tumor, it requires disruption of cell-cell interactions from the surrounding cells, as well as detachment from the ECM and resistance to anoikis (apoptosis upon cell detachment from ECM). Attachment, movement and invasion of cancer cells are functionally facilitated by the actin cytoskeleton and tubulin as the structural component of microtubules. Transforming growth factor (TGF)-β has tumor-inhibitory activity in the early stages of tumorigenesis, but it promotes tumor invasive characteristics in metastatic disease. Recent evidence implicates active (dephosphorylated) cofilin, an F-actin severing protein required for cytoskeleton reorganization, as an important contributor to switching TGF-β characteristics from a growth suppressor to a promoter of prostate cancer invasion and metastasis. Cancer cells eventually lose the ability to adhere to adjacent neighboring cells as well as ECM proteins, and via epithelial-mesenchymal transition (EMT), acquire invasive and metastatic characteristics. Microtubule-targeting chemotherapeutic agents, taxanes, are used in combination with antiandrogen strategies to increase the survival rate in patients with CRPC. This review addresses the development of therapeutic platform for targeting the integrity of actin cytoskeleton to impair prostate cancer progression