Dysregulation of persistent inward and outward currents in spinal motoneurons of symptomatic SOD1-G93A mice.

Persistent inward currents (PICs) and persistent outward currents (POCs) regulate the excitability and firing behaviours of spinal motoneurons (MNs). Given their potential role in MN excitability dysfunction in amyotrophic lateral sclerosis (ALS), PICs have been previously studied in superoxide dismutase 1 (SOD1)-G93A mice (the standard animal model of ALS); however, conflicting results have been reported on how the net PIC changes during disease progression. Also, individual PICs and POCs have never been examined before in symptomatic ALS. To fill this gap, we measured the net and individual PIC and POC components of wild-type (WT) and SOD MNs in current clamp and voltage clamp during disease progression (assessed by neuroscores). We show that SOD MNs of symptomatic mice experience a much larger net PIC, relative to WT cells from age-matched littermates. Specifically, the Na + and Ca 2+ PICs are larger, whereas the lasting SK-mediated (SK L ) POC is smaller than WT (Na + PIC is the largest and SK L POC is the smallest components in SOD MNs). We also show that PIC dysregulation is present at symptom onset, is sustained throughout advanced disease stages and is proportional to SOD MN cell size (largest dysregulation is in the largest SOD cells, the most vulnerable in ALS). Additionally, we show that studying disease progression using neuroscores is more accurate than using SOD mouse age, which could lead to misleading statistics and age-based trends. Collectively, this study contributes novel PIC and POC data, reveals ionic mechanisms contributing to the vulnerability differential among MN types/sizes, and provides insights on the roles PIC and POC mechanisms play in MN excitability dysfunction in ALS. KEY POINTS: Individual persistent inward currents (PICs) and persistent outward currents (POCs) have never been examined before in spinal motoneurons (MNs) of symptomatic amyotrophic lateral sclerosis (ALS) mice. Thus, we contribute novel PIC and POC data to the ALS literature. Male SOD MNs of symptomatic mice have elevated net PIC, with larger Na + and Ca 2+ PICs but reduced SK L POC vs. wild-type littermates. Na + PIC is the largest and SK L POC is the smallest current in SOD cells. The PIC/POC dysregulation is present at symptom onset. PIC dysregulation is sustained throughout advanced disease, and is proportional to SOD MN size (largest dysregulation is in the largest cells, the most vulnerable in ALS). Thus, we reveal ionic mechanisms contributing to the vulnerability differential among MN types/sizes in ALS. Studying disease progression using SOD mice neuroscores is more accurate than using age, which could distort the statistical differences between SOD and WT PIC/POC data and the trends during disease progression.