Loss of aly/ALYREF suppresses toxicity in both tau and TDP-43 models of neurodegeneration.

Neurodegenerative diseases with tau pathology, or tauopathies, include Alzheimer's disease and related dementia disorders. Previous work has shown that loss of the poly(A) RNA-binding protein gene sut-2/MSUT2 strongly suppressed tauopathy in Caenorhabditis elegans, human cell culture, and mouse models of tauopathy. However, the mechanism of suppression is still unclear. Recent work has shown that MSUT2 protein interacts with the THO complex and ALYREF, which are components of the mRNA nuclear export complex. Additionally, previous work showed ALYREF homolog Ref1 modulates TDP-43 and G4C2 toxicity in Drosophila melanogaster models. We used transgenic C. elegans models of tau or TDP-43 toxicity to investigate the effects of loss of ALYREF function on tau and TDP-43 toxicity. In C. elegans, three genes are homologous to human ALYREF: aly-1, aly-2, and aly-3. We found that loss of C. elegans aly gene function, especially loss of both aly-2 and aly-3, suppressed tau-induced toxic phenotypes. Loss of aly-2 and aly-3 was also able to suppress TDP-43-induced locomotor behavior deficits. However, loss of aly-2 and aly-3 had divergent effects on mRNA and protein levels as total tau protein levels were reduced while mRNA levels were increased, but no significant effects were seen on total TDP-43 protein or mRNA levels. Our results suggest that although aly genes modulate both tau and TDP-43-induced toxicity phenotypes, the molecular mechanisms of suppression are different and separated from impacts on mRNA and protein levels. Altogether, this study highlights the importance of elucidating RNA-related mechanisms in both tau and TDP-43-induced toxicity.

Human Ubiquilin 2 and TDP-43 copathology drives neurodegeneration in transgenic Caenorhabditis elegans.

Amyotrophic lateral sclerosis (ALS) is a debilitating, fatal neurodegenerative disease that causes rapid muscle wasting. It shares a spectrum of symptoms and pathology with frontotemporal lobar degeneration (FTLD). These diseases are caused by aberrant activity of a set of proteins including TDP-43 and UBIQUILIN-2 (UBQLN2). UBQLN2 encodes a ubiquitin-like adaptor protein involved in the ubiquitin-proteasome protein degradation pathway. Mutations in the PXX domain of UBQLN2 cause familial ALS. UBQLN2 aggregates in skein-like inclusions with other ALS and FTLD associated proteins including TDP-43 and ubiquitin. To facilitate further investigation of UBQLN2-mediated mechanisms of neurodegeneration, we made Caenorhabditis elegans transgenic lines pan-neuronally expressing human UBQLN2 cDNAs carrying either the wild-type UBQLN2 sequence or UBQLN2 with ALS causing mutations. Transgenic animals exhibit motor dysfunction accompanied by neurodegeneration of GABAergic motor neurons. At low levels of UBQLN2 expression, wild-type UBQLN2 causes significant motor impairment and neurodegeneration that is exacerbated by ALS associated mutations in UBQLN2. At higher levels of UBQLN2 expression, both wild-type and ALS mutated versions of UBQLN2 cause severe impairment. Molecular genetic investigation revealed that UBQLN2 dependent locomotor defects do not require the involvement of the endogenous homolog of TDP-43 in C. elegans (tdp-1). However, co-expression of wild-type human TDP-43 exacerbates UBQLN2 deficits. This model of UBQLN2-mediated neurodegeneration may be useful for further mechanistic investigation into the molecular cascades driving neurodegeneration in ALS and ALS-FTLD.

AlphaScreen Identifies MSUT2 Inhibitors for Tauopathy-Targeting Therapeutic Discovery.

Tauopathies are neurological disorders characterized by intracellular tau deposits forming neurofibrillary tangles, neuropil threads, or other disease-specific aggregates composed of the protein tau. Tauopathy disorders include frontotemporal lobar degeneration, corticobasal degeneration, Pick's disease, and the largest cause of dementia, Alzheimer's disease. The lack of disease-modifying therapeutic strategies to address tauopathies remains a critical unmet need in dementia care. Thus, novel broad-spectrum tau-targeted therapeutics could have a profound impact in multiple tauopathy disorders, including Alzheimer's disease. Here we have designed a drug discovery paradigm to identify inhibitors of the pathological tau-enabling protein, MSUT2. We previously showed that activity of the RNA-binding protein MSUT2 drives tauopathy, including tau-mediated neurodegeneration and cognitive dysfunction, in mouse models. Thus, we hypothesized that MSUT2 inhibitors could be therapeutic for tauopathy disorders. Our pipeline for MSUT2 inhibitory compound identification included a primary AlphaScreen, followed by dose-response validation, a secondary fluorescence polarization orthogonal assay, a tertiary specificity screen, and a preliminary toxicity screen. Our work here serves as a proof-of-principle methodology for finding specific inhibitors of the poly(A) RNA-binding protein MSUT2 interaction. Here we identify 4,4'-diisothiocyanostilbene-2,2'-sulfonic acid (DIDS) as a potential tool compound for future work probing the mechanism of MSUT2-induced tau pathology.

Distinct Poly(A) nucleases have differential impact on sut-2 dependent tauopathy phenotypes.

Aging drives pathological accumulation of proteins such as tau, causing neurodegenerative dementia disorders like Alzheimer's disease. Previously we showed loss of function mutations in the gene encoding the poly(A) RNA binding protein SUT-2/MSUT2 suppress tau-mediated neurotoxicity in C. elegans neurons, cultured human cells, and mouse brain, while loss of PABPN1 had the opposite effect (Wheeler et al., 2019). Here we found that blocking poly(A) tail extension with cordycepin exacerbates tauopathy in cultured human cells, which is rescued by MSUT2 knockdown. To further investigate the molecular mechanisms of poly(A) RNA-mediated tauopathy suppression, we examined whether genes encoding poly(A) nucleases also modulated tauopathy in a C. elegans tauopathy model. We found that loss of function mutations in C. elegans ccr-4 and panl-2 genes enhanced tauopathy phenotypes in tau transgenic C. elegans while loss of parn-2 partially suppressed tauopathy. In addition, loss of parn-1 blocked tauopathy suppression by loss of parn-2. Epistasis analysis showed that sut-2 loss of function suppressed the tauopathy enhancement caused by loss of ccr-4 and SUT-2 overexpression exacerbated tauopathy even in the presence of parn-2 loss of function in tau transgenic C. elegans. Thus sut-2 modulation of tauopathy is epistatic to ccr-4 and parn-2. We found that human deadenylases do not colocalize with human MSUT2 in nuclear speckles; however, expression levels of TOE1, the homolog of parn-2, correlated with that of MSUT2 in post-mortem Alzheimer's disease patient brains. Alzheimer's disease patients with low TOE1 levels exhibited significantly increased pathological tau deposition and loss of NeuN staining. Taken together, this work suggests suppressing tauopathy cannot be accomplished by simply extending poly(A) tails, but rather a more complex relationship exists between tau, sut-2/MSUT2 function, and control of poly(A) RNA metabolism, and that parn-2/TOE1 may be altered in tauopathy in a similar way.

Targeting Pathological Tau by Small Molecule Inhibition of the Poly(A):MSUT2 RNA-Protein Interaction.

Neurofibrillary tangles composed of aberrantly aggregating tau protein are a hallmark of Alzheimer's disease and related dementia disorders. Recent work has shown that mammalian suppressor of tauopathy 2 (MSUT2), also named ZC3H14 (Zinc Finger CCCH-Type Containing 14), controls accumulation of pathological tau in cultured human cells and mice. Knocking out MSUT2 protects neurons from neurodegenerative tauopathy and preserves learning and memory. MSUT2 protein functions to bind polyadenosine [poly(A)] tails of mRNA through its C-terminal CCCH type zinc finger domains, and loss of CCCH domain function suppresses tauopathy in Caenorhabditis elegans and mice. Thus, we hypothesized that inhibiting the poly(A):MSUT2 RNA-protein interaction would ameliorate pathological tau accumulation. Here we present a high-throughput screening method for the identification of small molecules inhibiting the poly(A):MSUT2 RNA-protein interaction. We employed a fluorescent polarization assay for initial small molecule discovery with the intention to repurpose hits identified from the NIH Clinical Collection (NIHCC). Our drug repurposing development workflow included validation of hits by dose-response analysis, specificity testing, orthogonal assays of activity, and cytotoxicity. Validated compounds passing through this screening funnel will be evaluated for translational effectiveness in future studies. This preclinical drug development pipeline identified diverse FDA approved drugs duloxetine, saquinavir, and clofazimine as potential repurposing candidates for reducing pathological tau accumulation.

Redefining transcriptional regulation of the APOE gene and its association with Alzheimer's disease.

The apolipoprotein E gene (APOE) is the strongest genetic risk factor for late-onset Alzheimer's disease (AD), yet the expression of APOE is not clearly understood. For example, it is unclear whether AD patients have elevated or decreased APOE expression or why the correlation levels of APOE RNA and the ApoE protein differ across studies. Likewise, APOE has a single CpG island (CGI) that overlaps with its 3'-exon, and this CGI's effect is unknown. We previously reported that the APOE CGI is highly methylated in human postmortem brain (PMB) and that this methylation is altered in AD frontal lobe. In this study, we comprehensively characterized APOE RNA transcripts and correlated levels of RNA expression with DNA methylation levels across the APOE CGI. We discovered the presence of APOE circular RNA (circRNA) and found that circRNA and full-length mRNA each constitute approximately one third of the total APOE RNA, with truncated mRNAs likely constituting some of the missing fraction. All APOE RNA species demonstrated significantly higher expression in AD frontal lobe than in control frontal lobe. Furthermore, we observed a negative correlation between the levels of total APOE RNA and DNA methylation at the APOE CGI in the frontal lobe. When stratified by disease status, this correlation was strengthened in controls but not in AD. Our findings suggest a possible modified mechanism of gene action for APOE in AD that involves not only the protein isoforms but also an epigenetically regulated transcriptional program driven by DNA methylation in the APOE CGI.

Genome wide analysis reveals heparan sulfate epimerase modulates TDP-43 proteinopathy.

Pathological phosphorylated TDP-43 protein (pTDP) deposition drives neurodegeneration in amyotrophic lateral sclerosis (ALS) and frontotemporal lobar degeneration (FTLD-TDP). However, the cellular and genetic mechanisms at work in pathological TDP-43 toxicity are not fully elucidated. To identify genetic modifiers of TDP-43 neurotoxicity, we utilized a Caenorhabditis elegans model of TDP-43 proteinopathy expressing human mutant TDP-43 pan-neuronally (TDP-43 tg). In TDP-43 tg C. elegans, we conducted a genome-wide RNAi screen covering 16,767 C. elegans genes for loss of function genetic suppressors of TDP-43-driven motor dysfunction. We identified 46 candidate genes that when knocked down partially ameliorate TDP-43 related phenotypes; 24 of these candidate genes have conserved homologs in the human genome. To rigorously validate the RNAi findings, we crossed the TDP-43 transgene into the background of homozygous strong genetic loss of function mutations. We have confirmed 9 of the 24 candidate genes significantly modulate TDP-43 transgenic phenotypes. Among the validated genes we focused on, one of the most consistent genetic modifier genes protecting against pTDP accumulation and motor deficits was the heparan sulfate-modifying enzyme hse-5, the C. elegans homolog of glucuronic acid epimerase (GLCE). We found that knockdown of human GLCE in cultured human cells protects against oxidative stress induced pTDP accumulation. Furthermore, expression of glucuronic acid epimerase is significantly decreased in the brains of FTLD-TDP cases relative to normal controls, demonstrating the potential disease relevance of the candidate genes identified. Taken together these findings nominate glucuronic acid epimerase as a novel candidate therapeutic target for TDP-43 proteinopathies including ALS and FTLD-TDP.

Sertraline, Paroxetine, and Chlorpromazine Are Rapidly Acting Anthelmintic Drugs Capable of Clinical Repurposing.

Parasitic helminths infect over 1 billion people worldwide, while current treatments rely on a limited arsenal of drugs. To expedite drug discovery, we screened a small-molecule library of compounds with histories of use in human clinical trials for anthelmintic activity against the soil nematode Caenorhabditis elegans. From this screen, we found that the neuromodulatory drugs sertraline, paroxetine, and chlorpromazine kill C. elegans at multiple life stages including embryos, developing larvae and gravid adults. These drugs act rapidly to inhibit C. elegans feeding within minutes of exposure. Sertraline, paroxetine, and chlorpromazine also decrease motility of adult Trichuris muris whipworms, prevent hatching and development of Ancylostoma caninum hookworms and kill Schistosoma mansoni flatworms, three widely divergent parasitic helminth species. C. elegans mutants with resistance to known anthelmintic drugs such as ivermectin are equally or more susceptible to these three drugs, suggesting that they may act on novel targets to kill worms. Sertraline, paroxetine, and chlorpromazine have long histories of use clinically as antidepressant or antipsychotic medicines. They may represent new classes of anthelmintic drug that could be used in combination with existing front-line drugs to boost effectiveness of anti-parasite treatment as well as offset the development of parasite drug resistance.

The phosphatase calcineurin regulates pathological TDP-43 phosphorylation.

Detergent insoluble inclusions of TDP-43 protein are hallmarks of the neuropathology in over 90 % of amyotrophic lateral sclerosis (ALS) cases and approximately half of frontotemporal dementia (FTLD-TDP) cases. In TDP-43 proteinopathy disorders, lesions containing aggregated TDP-43 protein are extensively post-translationally modified, with phosphorylated TDP-43 (pTDP) being the most consistent and robust marker of pathological TDP-43 deposition. Abnormally phosphorylated TDP-43 has been hypothesized to mediate TDP-43 toxicity in many neurodegenerative disease models. To date, several different kinases have been implicated in the genesis of pTDP, but no phosphatases have been shown to reverse pathological TDP-43 phosphorylation. We have identified the phosphatase calcineurin as an enzyme binding to and catalyzing the removal of pathological C-terminal phosphorylation of TDP-43 in vitro. In C. elegans models of TDP-43 proteinopathy, genetic elimination of calcineurin results in accumulation of excess pTDP, exacerbated motor dysfunction, and accelerated neurodegenerative changes. In cultured human cells, treatment with FK506 (tacrolimus), a calcineurin inhibitor, results in accumulation of pTDP species. Lastly, calcineurin co-localizes with pTDP in degenerating areas of the central nervous system in subjects with FTLD-TDP and ALS. Taken together, these findings suggest calcineurin acts on pTDP as a phosphatase in neurons. Furthermore, patient treatment with calcineurin inhibitors may have unappreciated adverse neuropathological consequences.