Size‐Dependence of Mitochondrial Density & Morphology in Phrenic Motor Neurons

Neuromotor control of diaphragm muscle is dependent on the orderly recruitment of phrenic motor neurons (PhMNs) in a size‐dependent manner. Type S and FR motor units comprise smaller, more easily recruited PhMNs that innervate fatigue resistant, lower force‐producing type I and type IIa muscle fibers. Type FInt and FF motor units, comprise larger, rarely recruited PhMNs innervating the more fatigable, higher force‐producing type IIx and/or IIb muscle fibers. The activity and energy demand upon PhMNs of type S and FR motor units is greater than that of PhMNs from type FInt and FF units, due to the high duty cycle (~35%) of ventilation. Accordingly, activity of type FInt and FF motor units is required for higher force behaviors that are performed intermittently over much shorter durations. These include the expulsive/straining maneuvers during coughing, sneezing, defecation and parturition. The energy demand in both PhMNs and diaphragm muscle fibers is met by mitochondria. To preserve homeostasis, mitochondrial functions are regulated by dynamic, continuous cycles of fusion and fragmentation. We hypothesized that mitochondrial density and mitochondrial fusion will be greater in smaller PhMNs, due to their more frequent activation during ventilation. In six adult (6‐month old) Fischer 344 rats, PhMNs were retrogradely labeled by intrapleural injection of Alexa488‐conjugated CTB. Three days later, cervical transdural infusion of MitoTracker Red was performed every 10 min for 1.5 h under anesthesia. Spinal cord tissue was collected following transcardial perfusion with 4% paraformaldehyde, sectioned longitudinally at 70 μm, and mounted onto slides. Two‐channel sequential confocal z‐stack (0.50 μm step size) mosaics of PhMNs and mitochondria were acquired using a 60x oil immersion objective and analyzed using Elements software (Nikon). The surface areas of PhMNs were measured and divided into tertiles. The lower tertile of PhMNs (comprising type S and FR motor units) had greater mitochondrial volume densities, greater mitochondrial aspect ratios and form factors and greater mean individual mitochondrial volumes than upper tertile PhMNs (comprising type FInt and FF motor units). We further characterized the differences in mRNA expression of mitochondrial dynamics associated proteins (Mfn2 and Drp1) in large vs. small PhMNs using fluorescent in‐situ hybridization techniques. Our results suggest that PhMNs of type S and FR motor units have increased mitochondrial density, supporting their high energy demand to sustain ventilation. Their increased mitochondrial fusion may underlie their resilience to PhMN loss in aging and disease. Support or Funding Information Supported by a National Institutes of Health grants R01‐AG044615