Amyotrophic lateral sclerosis (ALS) is a fatal, adult-onset neurodegenerative disease characterized by
progressive motor neuron (MN) loss, muscle denervation, and eventually, paralysis. Currently, no effective
treatments are available to stop or reverse ALS disease progression and the precise molecular mechanisms
underlie ALS pathogenesis remain elusive. Prior studies revealed decreased mitochondrial respiratory chain
activity, altered mitochondrial ultrastructure, and mitochondrial dysfunction in both MN and skeletal muscle (SM)
in ALS patients and mouse models. The first sign of ALS pathology occurs at the neuromuscular junction (NMJ),
where presynaptic MN axons connect with postsynaptic SM end plates. To date, whether signals resulting in the
initial NMJ damage are from MN or SM remain unclear. In this project, we aim to determine the tissue-specific
causative role of mitochondrial Ca2+ uptake in SM and MN in disease onset and progression, and the therapeutic
efficacy of reducing mitochondrial Ca2+ uptake on NMJ and SM function in ALS mice. We hypothesize that
mitochondrial Ca2+ mishandling in both SM and MN actively contribute to ALS disease pathogenesis and that
attenuating mitochondrial Ca2+ uptake mitigates mitochondrial damage and preserves NMJ/muscle function. To
test this hypothesis, we will use transgenic mice with inducible, SM or MN-specific expression of a dominant
negative form of the mitochondrial Ca2+ uniporter to specifically and selectively reduce mitochondrial Ca2+ uptake
in SM and MN in hSOD1G93A mice and C9-500 (C9orf72) mice, two mouse models associated with the most
prevalent genetic causes for ALS. The central hypothesis will be tested in two Specific Aims. Aim 1 will determine
the role of mitochondrial Ca2+ uptake in SM or MN in survival, motor function, NMJ function and in vivo muscle
performance in hSOD1G93A and C9-500 mice. Aim 2 will assess the impact of tissue-specific inhibition of
mitochondrial Ca2+ uptake in SM or MN on NMJ and muscle structure, MN survival, muscle intrinsic contractile
properties, mitochondrial structure and mitochondrial bioenergetics in SM of hSOD1G93A and C9-500 mice. This
project will: 1) provide a systematic, longitudinal characterization of SM and NMJ function from a cellular level to
whole animal level at different stages of disease progression in hSOD1G93A and C9-500 mice; 2) determine the
degrees to which defects in mitochondrial Ca2+ uptake in SM or MN contribute to altered NMJ structure/function,
disease onset and progression in hSOD1G93A and C9-500 mice; 3) provide the first detailed dissection on the
relative role of mitochondrial Ca2+ uptake in SM and MN in ALS phenotype using the same genetic models and
determine the origin of the signals that result in NMJ destruction (from SM or MN or both); 4) provide mechanistic
evidence for whether mitochondrial Ca2+ mishandling is a trigger or a target for disease progression in ALS mice,
regardless of the causing mutations (mitochondrial related or non-mitochondrial related); and most importantly,
5) test the validity of a potential new therapeutic target (mitochondrial Ca2+ uptake, or the mitochondrial Ca2+
uniporter) for the treatment of ALS.