The upregulation of proinflammatory factors during early presymptomatic stages as well as the expansion of immune activation as disease progresses in mutant SOD1 transgenic mice suggest that immune-inflammatory mechanisms could contribute to disease progression.
The factors contributing to selective motoneuron loss in amyotrophic lateral sclerosis (ALS) remain undefined. To investigate whether calcium-binding proteins contribute to selective motoneuron vulnerability in ALS, we compared calbindin-D28K and parvalbumin immunoreactivity in motoneuron populations in human ALS, and in a ventral spinal cord hybrid cell line selectively vulnerable to the cytotoxic effects of ALS IgG. In human autopsy specimens, immunoreactive calbindin-D28k and parvalbumin were absent in motoneuron populations lost early in ALS (i.e., cortical and spinal motoneurons, lower cranial nerve motoneurons), while motoneurons damaged late or infrequently in the disease (i.e., Onuf's nucleus motoneurons, oculomotor, trochlear, and abducens nerve neurons) expressed markedly higher levels of immunoreactive calbindin-D28K and/or parvalbumin. Motoneuron-neuroblastoma VSC 4.1 hybrid cells lost immunoreactive calbindin-D28k and parvalbumin following dibutyryl-cyclic AMP-induced differentiation and were killed by IgG from ALS patients. Undifferentiated calbindin/parvalbumin-reactive VSC 4.1 cells were not killed, nor were other cell lines expressing high levels of calbindin-D28K and parvalbumin immunoreactivity (substantia nigra-neuroblastoma hybrid cells and N18TG2 neuroblastoma parent cells). These studies suggest that decreased calbindin-D28K and parvalbumin immunoreactivity may help explain the selective vulnerability of motoneurons in ALS.
Transgenic mice with Cu,Zn superoxide dismutase (SOD-1) mutations provide a unique model to examine altered Ca homeostasis in selectively vulnerable and resistant motoneurons. In degenerating spinal motoneurons of G93 A SOD-1 mice, developing vacuoles were filled with calcium, while calcium was gradually depleted from the cytoplasm and intact mitochondria. In oculomotor neurons, no degenerative changes, vacuolization, or increased calcium were noted. Motor axon terminals of interosseus muscle gradually degenerated and intracellular calcium was depleted. Oculomotor terminals of mutant SOD-1 mice were smaller and exhibited no degenerative changes, but did exhibit unique membrane-enclosed organelles containing calcium. Spinal motoneurons of SOD-1 mice were shown to have fewer calcium binding proteins, such as parvalbumin, compared with oculomotor neurons. These data suggest that the SOD-1 mutation is associated with impaired calcium homeostasis in motoneurons in vivo, with increased likelihood of degeneration associated with higher levels of intracellular calcium and lower to absent levels of calbindin-D28K and/or parvalbumin, and decreased likelihood of degeneration associated with minimally changed calcium and ample calbindin-D28K and/or parvalbumin.
Intracellular calcium is increased in vulnerable spinal motoneurons in immune-mediated as well as transgenic models of amyotrophic lateral sclerosis (ALS). To determine whether intracellular calcium levels are in¯uenced by the calciumbinding protein parvalbumin, we developed transgenic mice overexpressing parvalbumin in spinal motoneurons. ALS immunoglobulins increased intracellular calcium and spontaneous transmitter release at motoneuron terminals in control animals, but not in parvalbumin overexpressing transgenic mice. Parvalbumin transgenic mice interbred with mutant SOD1 (mSOD1) transgenic mice, an animal model of familial ALS, had signi®cantly reduced motoneuron loss, and had delayed disease onset (17%) and prolonged survival (11%) when compared with mice with only the mSOD1 transgene. These results af®rm the importance of the calcium binding protein parvalbumin in altering calcium homeostasis in motoneurons. The increased motoneuron parvalbumin can signi®-cantly attenuate the immune-mediated increases in calcium and to a lesser extent compensate for the mSOD1-mediated toxic-gain-of-function' in transgenic mice.
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