Intracellular recording has been performed to examine whether any differences in apparent initial-segment voltage threshold exist between types F and S cat triceps surae motoneurons. Voltage threshold was estimated using orthodromic action potentials initiated by large, monosynaptic excitatory postsynaptic potentials (EPSPs) evoked by dorsal root stimulation. No significant differences in voltage threshold could be detected between types F and S motoneurons. Further, voltage thresholds did not covary with motoneuron input resistance, afterhyperpolarization duration, or the twitch contraction time of functionally isolated muscle units. Significant positive correlations were observed between voltage threshold and the motoneuron resting potential. Utilizing a compartmental neuron model, a theoretical analysis has been performed that examines the influence of specific passive membrane properties on current threshold for action potentials initiated by large, monosynaptic EPSPs. This analysis indicates that total membrane capacitance will be the primary determinant of these thresholds. Further analysis of available data suggests that active membrane properties will play a minimal role in setting these thresholds. Since specific membrane capacitance is likely to be similar among cat motoneurons, it is concluded that only size or surface area-related current threshold differences will exist among these cells for activation with brief currents such as those underlying large EPSPs. For motoneurons thus activated, it is suggested that variations in the excitatory/inhibitory balance or density of synaptic input would be the major mechanisms for producing differential recruitment thresholds among the motoneuron population. Other available evidence is discussed that indicates that factors intrinsic to the motoneurons themselves will contribute to the setting of functional recruitment thresholds for activation with longer duration currents.
Midbelly cross sections of the medial gastrocnemius muscle of young adult male laboratory mice were subjected to ATPase histochemistry with preincubation at pH 4.6. Through the use of a sampling grid and computer-assisted morphometric analysis, 26 to 35% of the total muscle fibers were sampled and classified as type I, IIa, or IIb. Photomicrographs (16 X 20 in.) of five muscles were divided into octants according to a standardized procedure. Total fiber counts and percent of fibers sampled were determined. Variability of sample size per octant was noted, but when averaged across entire muscles, it was in all instances greater than 33%. Fiber type frequency per octant was tested for goodness of fit to a random model by means of a chi-square statistic for equal expected frequencies. Deviation from random fiber type frequency was significant at the P = 0.001 level for every muscle. More importantly, when these data were pooled and again tested using the same method, the probability estimate was less than P = 0.001. This established that the variations in the fiber type proportions found in each mouse followed a common pattern. The systematic fiber type distribution confirmed by these morphometric and statistical methods supports the impression expressed by many muscle biologists that this muscle displays a consistent and complex intramuscular organization.
We noted that, unlike mammalian intestinal absorptive cells, cells of the winter flounder (Pseudopleuronectes americanus) displayed abundant gap junctions on the lateral plasma membrane. We compared the distribution of gap junctions in winter flounder to that in rabbit intestinal epithelium. We also examined for evidence of gap junction-mediated intercellular coupling by comparing the cell-to-cell variation of electrical potential difference across winter flounder intestinal cell apical membranes with that in rabbit small intestinal epithelium in which gap junctions are rare. Gap junctions were seen in 95% of flounder absorptive cells and were localized largely to the apical third of the lateral membrane. Individual gap junctions often contained several hundred uniform 9-nm intramembrane particles. Gap junction size and structure was independent of the position of individual absorptive cells on mucosal folds. These findings sharply contrasted flounder intestinal absorptive cells with rabbit small intestinal absorptive cells, in which gap junctions were rarely detected and when present consisted of few intramembrane particles. Correlating with this distribution of morphologically detectable gap junctions, rabbit small intestinal epithelial cells demonstrated marked variability in potential difference across their apical membranes, whereas those in flounder small intestine showed little variation in apical membrane potential difference. Thus, in contrast to intestinal epithelium of rabbits, flounder intestinal epithelium demonstrates morphological and functional characteristics, suggesting a substantial degree of electrical coupling.
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