Genome damage and defective repair are etiologically linked to Fused in Sarcoma (FUS)-associated amyotrophic lateral sclerosis (ALS) and frontotemporal dementia (FTD). However, the underlying mechanisms remain enigmatic, which is a roadblock for exploiting genome repair-targeted therapies for ALS/FTD. Our recent publication (Wang et al, Nature Communications, 2018) identified defects in DNA nick ligation and oxidative damage repair in a subset of ALS patients, caused by mutations in the RNA/DNA-binding protein FUS. In healthy neurons, FUS protects the genome by facilitating PARP1-dependent recruitment of XRCC1/DNA Ligase III? (LigIII) to oxidized genome sites and activates LigIII via direct interaction. We discovered that FUS toxicity caused significantly decreased recruitment of XRCC1/LigIII to DNA strand breaks. DNA ligation defects in ALS patient-derived iPSC lines carrying FUS mutations and in subsequently generated motor neurons were rescued by CRISPR/Cas9-mediated mutation correction. Moreover, our follow-up studies showed substantially reduced auto and total PARylation activity of PARP-1 both in vitro and in cell, after loss of FUS or mutant expression, which in addition to regulating LigIII/XRCC1 recruitment at damage sites, could impact neuronal energy metabolism by uncoupling NAD+/NADH levels and stress granule dynamics in motor neurons. Collectively these events may provide a recipe for neurodegeneration. These findings that uncovered a new pathway of defective DNA ligation and PARP-1 functions in FUS-linked ALS-FTD, raised three key questions that need to be investigated to understand their implications in neuronal death and to develop a comprehensive strategy of PARylation and LigIII targeted interventions for ameliorating FUS-associated ALS-FTD. These questions are: (1) How does FUS affect PARP-1's PARylation activity and what is its impact on genome maintenance and energy metabolism? (2) What is the effect of FUS-mediated LigIII inhibition on the mitochondrial genome and its functions? This is important as LigIII is the only DNA ligase for both replication and repair in mitochondria, and both FUS and PARP-1 localize in mitochondria. (3) What is the effect of FUS pathology on microhomology-mediated alternative end-joining (MMEJ) pathway of DNA double strand break repair, which involves LigIII, XRCC1 and PARP-1?. This project, will utilize human patient-derived iPSC lines harboring FUS mutations, their isogenic controls with mutation correction by CRISPR/Cas9 knock-in strategy, a transgenic FUS-?NLS mouse model and human ALS, FTD patient spinal cord/brain tissue, to test our novel hypothesis that FUS pathology-mediated DNA ligation defects via reduced PARylation inhibits oxidative genome damage repair and promotes neurodegeneration. We will further show that rescuing Ligase and PARP functions are promising avenues for neuroprotection. Our studies investigating the previously unexplored link between altered FUS-PARP-1-LigIII axis and ALS-FTD are both technically and conceptually innovative, have important immediate and long term goals and will strongly impact translational ALS-FTD research.

Public Health Relevance

Amyotrophic lateral sclerosis (ALS) and frontotemporal dementia (FTD) are rapidly progressing, fatal neurodegenerative diseases, for which no effective treatment is available even for slowing down the disease progression. Recent studies have etiologically linked genome damage and defective repair to FUS-linked ALS/FTD, however specific molecular mechanisms remained enigmatic, which is a roadblock to develop effective genome repair targeted avenues. Following up our recent publication, that identified a specific molecular insight into a previously undescribed DNA ligation defect in FUS-associated ALS/FTD, this project will establish that FUS is a key component of DNA strand break ligation machinery in both nuclear and mitochondrial genomes in motor neurons of healthy individuals and its loss of functions together with gain of toxicity in ALS/FTD due to familial mutations, leads to deficient DNA strand break repair. The resulting genome instability causes neuronal toxicity, senescence and death. Successful completion of our proposed studies will provide molecular insights into the role of FUS in nuclear and mitochondrial genome maintenance, as well as its functional implications in ALS/FTD affected neurons. This project will also evaluate the FUS-PARP-1-LigIII axis as a proof-of-concept therapeutic target in ALS/FTD. Thus this technically and conceptually innovative studies, have important immediate and long-term goals, and will strongly impact translational ALS/FTD research. In addition, our studies should also shed light on the broader perspective on the emerging role of diverse RNA/DNA binding proteins in genome maintenecane and their role in neurodegeneration.

Agency
National Institute of Health (NIH)
Institute
National Institute of Neurological Disorders and Stroke (NINDS)
Type
Multi-Year Funded Research Project Grant (RF1)
Project #
1RF1NS112719-01A1
Application #
9980670
Study Section
Neural Oxidative Metabolism and Death Study Section (NOMD)
Program Officer
Gubitz, Amelie
Project Start
2020-04-15
Project End
2025-03-31
Budget Start
2020-04-15
Budget End
2025-03-31
Support Year
1
Fiscal Year
2020
Total Cost
Indirect Cost
Name
Methodist Hospital Research Institute
Department
Type
DUNS #
185641052
City
Houston
State
TX
Country
United States
Zip Code
77030