Genetic and immunopathological analysis of CHCHD10 in Australian amyotrophic lateral sclerosis and frontotemporal dementia and transgenic TDP-43 mice.

OBJECTIVE: Since the first report of CHCHD10 gene mutations in amyotrophiclateral sclerosis (ALS)/frontotemporaldementia (FTD) patients, genetic variation in CHCHD10 has been inconsistently linked to disease. A pathological assessment of the CHCHD10 protein in patient neuronal tissue also remains to be reported. We sought to characterise the genetic and pathological contribution of CHCHD10 to ALS/FTD in Australia. METHODS: Whole-exome and whole-genome sequencing data from 81 familial and 635 sporadic ALS, and 108 sporadic FTD cases, were assessed for genetic variation in CHCHD10. CHCHD10 protein expression was characterised by immunohistochemistry, immunofluorescence and western blotting in control, ALS and/or FTD postmortem tissues and further in a transgenic mouse model of TAR DNA-binding protein 43 (TDP-43) pathology. RESULTS: No causal, novel or disease-associated variants in CHCHD10 were identified in Australian ALS and/or FTD patients. In human brain and spinal cord tissues, CHCHD10 was specifically expressed in neurons. A significant decrease in CHCHD10 protein level was observed in ALS patient spinal cord and FTD patient frontal cortex. In a TDP-43 mouse model with a regulatable nuclear localisation signal (rNLS TDP-43 mouse), CHCHD10 protein levels were unaltered at disease onset and early in disease, but were significantly decreased in cortex in mid-stage disease. CONCLUSIONS: Genetic variation in CHCHD10 is not a common cause of ALS/FTD in Australia. However, we showed that in humans, CHCHD10 may play a neuron-specific role and a loss of CHCHD10 function may be linked to ALS and/or FTD. Our data from the rNLS TDP-43 transgenic mice suggest that a decrease in CHCHD10 levels is a late event in aberrant TDP-43-induced ALS/FTD pathogenesis.

Pathogenic mutation in the ALS/FTD gene, CCNF, causes elevated Lys48-linked ubiquitylation and defective autophagy.

Amyotrophic lateral sclerosis (ALS) and frontotemporal dementia (FTD) are fatal neurodegenerative disorders that have common molecular and pathogenic characteristics, such as aberrant accumulation and ubiquitylation of TDP-43; however, the mechanisms that drive this process remain poorly understood. We have recently identified CCNF mutations in familial and sporadic ALS and FTD patients. CCNF encodes cyclin F, a component of an E3 ubiquitin-protein ligase (SCFcyclin F) complex that is responsible for ubiquitylating proteins for degradation by the ubiquitin-proteasome system. In this study, we examined the ALS/FTD-causing p.Ser621Gly (p.S621G) mutation in cyclin F and its effect upon downstream Lys48-specific ubiquitylation in transfected Neuro-2A and SH-SY5Y cells. Expression of mutant cyclin FS621G caused increased Lys48-specific ubiquitylation of proteins in neuronal cells compared to cyclin FWT. Proteomic analysis of immunoprecipitated Lys48-ubiquitylated proteins from mutant cyclin FS621G-expressing cells identified proteins that clustered within the autophagy pathway, including sequestosome-1 (p62/SQSTM1), heat shock proteins, and chaperonin complex components. Examination of autophagy markers p62, LC3, and lysosome-associated membrane protein 2 (Lamp2) in cells expressing mutant cyclin FS621G revealed defects in the autophagy pathway specifically resulting in impairment in autophagosomal-lysosome fusion. This finding highlights a potential mechanism by which cyclin F interacts with p62, the receptor responsible for transporting ubiquitylated substrates for autophagic degradation. These findings demonstrate that ALS/FTD-causing mutant cyclin FS621G disrupts Lys48-specific ubiquitylation, leading to accumulation of substrates and defects in the autophagic machinery. This study also demonstrates that a single missense mutation in cyclin F causes hyper-ubiquitylation of proteins that can indirectly impair the autophagy degradation pathway, which is implicated in ALS pathogenesis.

Theme 3 In vitro experimental models.

Background: Ongoing disease gene discoveries continue to drive our understanding of the molecular and cellular mechanisms underlying ALS. Causative genes from 60% of ALS families have been identified using modern genetic techniques, but the causal gene defect is yet to be identified in the remaining 40% of families. These remaining families often do not follow true Mendelian inheritance patterns and are challenging to solve using traditional genetic analysis alone. In vitro and in vivo studies have become critical in assessing and validating these ALS candidate genes.Objectives: In this study, we aim to develop and validate the utility of an in vitro functional pipeline for the discovery and validation of novel ALS candidate genes.Methods: A panel of cell based-assays were applied to candidate genes to examine the presence/absence of known ALS pathologies in cell lines as well as human autopsy tissues. These include immunofluorescence, flow cytometry and western blotting to study toxicity, neuronal inclusion formation, interaction with TDP-43, aberrant protein degradation and accumulation in detergent-insoluble cellular fractions. Immunohistochemistry and immunofluorescence were also used to examine if candidates were present in neuronal inclusions from ALS patient spinal cord tissues.Results: The in vitro pipeline was applied to five candidate genes from an ALS family that is negative for known ALS gene mutations. Two candidates were prioritized as top candidates based on their capacity to induce known ALS cellular pathologies. In transfected cells, the variants in these two genes caused a significantly higher toxicity than wild type, formed detergent insoluble inclusions and was able to co-aggregate with TDP-43 in neuronal cells. The variants have also led to protein degradation defects. One of the candidates also co-localised with TDP-43-positive neuronal inclusions in sporadic ALS patient post-mortem tissues, a signature pathology of ALS.Discussion and conclusions: We have demonstrated the utility of a functional prioritization pipeline and successfully prioritized two novel candidate ALS genes. These genes, and its associated pathways, will be further investigated through the development of animal models to establish if there is support for its role in ALS. New ALS genes offer fresh diagnostic and therapeutic targets and tools for the generation of novel animal models to better understand disease biology and offer preclinical testing of candidate treatments for ALS in the future.