ALS mutations in TLS/FUS disrupt target gene expression

Ryu

et al. 2017

Sci Rep

Mutations in fused in sarcoma (FUS), a DNA/RNA binding protein, are associated with familial amyotrophic lateral sclerosis (ALS). However, little is known about how ALS-causing mutations alter protein-protein and protein-RNA complexes and contribute to neurodegeneration. In this study, we identified protein arginine methyltransferase 1 (PRMT1) as a protein that more avidly associates with ALS-linked FUS-R521C than with FUS-WT (wild type) or FUS-P525L using co-immunoprecipitation and LC-MS analysis. Abnormal association between FUS-R521C and PRMT1 requires RNA, but not methyltransferase activity. PRMT1 was sequestered into cytosolic FUS-R521C-positive stress granule aggregates. Overexpression of PRMT1 rescued neurite degeneration caused by FUS-R521C upon oxidative stress, while loss of PRMT1 further accumulated FUS-positive aggregates and enhanced neurite degeneration. Furthermore, the mRNA of Nd1-L, an actin-stabilizing protein, was sequestered into the FUS-R521C/PRMT1 complex. Nd1-L overexpression rescued neurite shortening caused by FUS-R521C upon oxidative stress, while loss of Nd1-L further exacerbated neurite shortening. Altogether, these data suggest that the abnormal stable complex of FUS-R521C/PRMT1/Nd1-L mRNA could contribute to neurodegeneration upon oxidative stress. Overall, our study provides a novel pathogenic mechanism of the FUS mutation associated with abnormal protein-RNA complexes upon oxidative stress in ALS and provides insight into possible therapeutic targets for this pathology.

Section: Discussionsupporting

confidence: 91%

Sequestration of PRMT1 and Nd1-L mRNA into ALS-linked FUS mutant R521C-positive aggregates contributes to neurite degeneration upon oxidative stress

Ryu

et al. 2017

Sci Rep

“…The mRNA was found to be present with mutant FUS in cytoplasmic aggregates by both biochemical analysis and FISH, suggesting that the transcript is sequestered. These results suggest that mutant FUS aggregation can affect the stability and translation of mRNA targets through direct sequestration of RNAs as well as pre-mRNA splicing through sequestration of splicing factors (Coady and Manley 2015).…”

Section: Fusmentioning

confidence: 95%

“…DNA FUS-responsive elements were later found enriched within promoter regions of genes shown to respond transcriptionally to FUS levels (Tan et al 2012). One such gene, MECP2, biologically interesting due to its relationship to the neuroregressive disease Rett syndrome, was found to be misspliced in cells transfected with mutant, but not wild-type, FUS (Coady and Manley 2015). Interestingly, the splice isoform of MECP2 promoted by mutant FUS was found to have increased RNA stability yet express lower protein levels.…”

Section: Fusmentioning

confidence: 99%

RNA-binding proteins in neurodegeneration: mechanisms in aggregate

2017

Self Cite

Neurodegeneration is a leading cause of death in the developed world and a natural, albeit unfortunate, consequence of longer-lived populations. Despite great demand for therapeutic intervention, it is often the case that these diseases are insufficiently understood at the basic molecular level. What little is known has prompted much hopeful speculation about a generalized mechanistic thread that ties these disparate conditions together at the subcellular level and can be exploited for broad curative benefit. In this review, we discuss a prominent theory supported by genetic and pathological changes in an array of neurodegenerative diseases: that neurons are particularly vulnerable to disruption of RNA-binding protein dosage and dynamics. Here we synthesize the progress made at the clinical, genetic, and biophysical levels and conclude that this perspective offers the most parsimonious explanation for these mysterious diseases. Where appropriate, we highlight the reciprocal benefits of cross-disciplinary collaboration between disease specialists and RNA biologists as we envision a future in which neurodegeneration declines and our understanding of the broad importance of RNA processing deepens.

“…Dysregulation of RNA and protein expression in neurons has deleterious consequences and contributes to numerous neurological and psychiatric diseases (Darnell, 2013; Pilaz and Silver, 2015). For example, expression of variants of the TLS/ FUS RNA binding protein found in amyotrophic lateral sclerosis patients causes aberrant gene expression in human cells, including of MECP2 (Coady and Manley, 2015). Similarly, copy-number variations in the NUDT21 gene found in patients with neurological disease increase the fraction of MECP2 mRNA molecules with long 3′ UTRs (Gennarino et al, 2015).…”

Section: Discussionmentioning

confidence: 99%

“…Similarly, copy-number variations in the NUDT21 gene found in patients with neurological disease increase the fraction of MECP2 mRNA molecules with long 3′ UTRs (Gennarino et al, 2015). Total MECP2 mRNA levels are elevated in patient-derived cells (Gennarino et al, 2015) or human cells expressing TLS/FUS variants (Coady and Manley, 2015), but MeCP2 protein levels are decreased in both cases. Thus, measuring translation changes in the manner described here that can detect and quantify alternative transcripts and 3′ UTRs is essential when studying diseases involving genetic alterations to post-transcriptional control factors.…”

Section: Discussionmentioning

confidence: 99%

Widespread Translational Remodeling during Human Neuronal Differentiation

et al. 2017

Summary Faithful cellular differentiation requires temporally precise activation of gene expression programs, which are coordinated at the transcriptional and translational levels. Neurons express the most complex set of mRNAs of any human tissue, but translational changes during neuronal differentiation remain incompletely understood. Here, we induced forebrain neuronal differentiation of human embryonic stem cells (hESCs) and measured genome-wide RNA and translation levels with transcript-isoform resolution. We find that thousands of genes change translation status during differentiation without a corresponding change in RNA level. Specifically, we identify mTOR signaling as a key driver for elevated translation of translation-related genes in hESCs. In contrast, translational repression in active neurons is mediated by regulatory sequences in 3′ UTRs. Together, our findings identify extensive translational control changes during human neuronal differentiation, and a crucial role of 3′ UTRs in driving cell-type specific translation.