Myosin heavy chain composition in normal and atrophic equine laryngeal muscle.

The myosin heavy chain (MHC) composition of a given muscle determines the contractile properties and, therefore, the fiber type distribution of the muscle. MHC isoform expression in the laryngeal muscle is modulated by neural input and function, and it represents the cellular level changes that occur with denervation and reinnervation of skeletal muscle. The objective of this study was to evaluate the pattern of MHC isoform expression in laryngeal muscle harvested from normal cadavers and cadavers with naturally occurring left laryngeal hemiplegia secondary to recurrent laryngeal neuropathy. Left and right thyroarytenoideus (TA) and cricoarytenoideus dorsalis (CAD) were obtained from 7 horses affected with left-sided intrinsic laryngeal muscle atrophy and from 2 normal horses. Frozen sections were evaluated histologically for degree of atrophy and fiber type composition. MHC isoform expression was determined by sodium dodecyl sulfate-polyacrylamide gel electrophoresis (SDS-PAGE) of muscle protein. Histologic atrophy was seen in all atrophic muscles and some right-sided muscles of 3 affected horses, as well as the left TA of 1 normal horse. Fiber type grouping or loss of type I muscle fibers was observed in the left-sided laryngeal muscles in all but 1 affected horse, as well as in the right muscles of 2 affected horses, and the left TA of 1 normal horse. SDS-PAGE showed 2 bands corresponding to the type I and type IIB myosin isoforms in the CAD and TA of the 2 normal horses. Affected horses demonstrated a trend toward increased expression of the type IIB isoform and decreased expression of the type I isoform in atrophic muscles. This study confirmed the presence of histologic abnormalities in grossly normal equine laryngeal muscle, and it demonstrated an increased expression of type IIB MHC with a concurrent decreased expression of type I MHC in affected muscles. Evaluation of muscle fiber changes at the cellular level under denervated and reinnervated conditions may aid in assessing future strategies for reinnervation or regeneration of atrophic laryngeal muscle.

Group III muscle afferents evoke reflex depressor responses to repetitive muscle contractions in rabbits.

Repetitive-twitch contraction of the hindlimb muscles in anesthetized rabbits consistently evokes a reflex depressor response, whereas this type of contraction in anesthetized cats evokes a reflex pressor response in about one-half of the preparations tested. Rapidly conducting group III fibers appear to comprise the afferent arm of the reflex arc, evoking the depressor response to twitch contraction in rabbits because electrical stimulation of their axons reflexly decreases arterial pressure. In contrast, electrical stimulation of the axons of slowly conducting group III and group IV afferents reflexly increases arterial pressure in rabbits. In the present study, we examined the discharge properties of group III and IV muscle afferents and found that the former (i.e., 13 of 20), but not the latter (i.e., 0 of 10), were stimulated by 5 min of repetitive-twitch contraction (1 Hz) of the rabbit triceps surae muscles. Moreover, most of the group III afferents responding to contraction appeared to be mechanically sensitive, discharging in synchrony with the muscle twitch. On average, rapidly conducting group III afferents responded for the 5-min duration of 1-Hz repetitive-twitch contraction, whereas slowly conducting group III afferents responded only for the first 2 min of contraction. We conclude that rapidly conducting group III afferents, which are mechanically sensitive, are primarily responsible for evoking the reflex depressor response to repetitive-twitch contractions in anesthetized rabbits.

Effect of arterial occlusion on responses of group III and IV afferents to dynamic exercise.

Our laboratory has shown previously that a low level of dynamic exercise induced by electrical stimulation of the mesencephalic locomotor region (MLR) stimulated group III and IV muscle afferents in decerebrate unanesthetized cats (C. M. Adreani, J. M. Hill, and M. P. Kaufman. J. Appl. Physiol. 83: 1811-1817, 1997). In the present study, we have extended these findings by examining the effect of occluding the arterial supply to the dynamically exercising muscles on the afferents' responses to MLR stimulation. In decerebrate cats, we found that arterial occlusion increased the responsiveness to a low level of dynamic exercise in 44% of the group III and 47% of the group IV afferents tested. Occlusion, compared with the freely perfused state, did not increase the concentrations of either hydrogen ion or lactate ion in the venous effluent from the exercising muscles. We conclude that arterial occlusion caused some unspecified substance to accumulate in the working muscles to increase the sensitivity of equal percentages of group III and IV afferents to dynamic exercise.

Responses of group III and IV muscle afferents to dynamic exercise.

Tetanic contraction of hindlimb skeletal muscle, induced by electrical stimulation of either ventral roots or peripheral nerves, is well known to activate group III and IV afferents. Nevertheless, the effect of dynamic exercise on the discharge of these thin fiber afferents is unknown. To shed some light on this question, we recorded in decerebrate cats the discharge of 24 group III and 10 group IV afferents while the mesencephalic locomotor region (MLR) was stimulated electrically. Each of the 34 afferents had their receptive fields in the triceps surae muscles. Stimulation of the MLR for 1 min caused the triceps surae muscles to contract rhythmically, an effect induced by an alpha-motoneuron discharge pattern and recruitment order almost identical to that occurring during dynamic exercise. Eighteen of the 24 group III and 8 of the 10 group IV muscle afferents were stimulated by MLR stimulation. The oxygen consumption of the dynamically exercising triceps surae muscles was increased by 2.5-fold over their resting levels. We conclude that low levels of dynamic exercise stimulate group III and IV muscle afferents.

Muscle reflex stimulates sympathetic postganglionic efferents innervating triceps surae muscles of cats.

Two neural mechanisms contribute to the cardiovascular responses to exercise. The first, central command, proposes a parallel activation of central locomotor and brain stem circuits controlling cardiovascular function. The second, the muscle reflex, proposes that contraction-activated group III and IV afferents increase cardiovascular function. In humans, whole nerve recordings of sympathetic discharge suggest that central command increases sympathetic outflow to skin but not to skeletal muscle and that the muscle reflex increases sympathetic outflow to skeletal muscle but not to skin. We therefore tested the hypothesis that the muscle reflex, but not central command, increases the discharge of single sympathetic postganglionic efferents innervating the triceps surae muscles of decerebrate unanesthetized cats. Central command was evoked by electrical stimulation of the mesencephalic locomotor region. The reflex was evoked by electrical stimulation of the tibial nerve, which in turn contracted the triceps surae muscles. Hexamethonium abolished spontaneous and evoked activity, verifying that the recordings were from sympathetic postganglionic fibers. The discharge of 13 efferents was increased by static contraction (from 0.6 +/- 0.2 to 1.0 +/- 0.3 imp/s; P < 0.05) but was not increased by central command (from 0.6 +/- 0.2 to 0.8 +/- 0.2 imp/s; P > 0.05). Nevertheless, the discharge of nine efferents, not increased by central command before alpha-adrenergic blockade (from 0.5 +/- 0.2 to 0.9 +/- 0.4 imp/s; P > 0.05), was increased after blockade (from 1.3 +/- 0.2 to 3.2 +/- 0.8 imp/s; P < 0.05). We conclude that the muscle reflex stimulates sympathetic postganglionic efferents innervating the vasculature of skeletal muscle. Furthermore, baroreceptors appear to buffer the central command-induced increases in the discharge of these efferents.

Intrathecal blockade of both NMDA and non-NMDA receptors attenuates the exercise pressor reflex in cats.

In decerebrate unanesthetized cats we tested the hypothesis that glutamatergic-receptor blockade in the lumbosacral spinal cord attenuated the reflex increases in mean arterial pressure, inspired minute ventilation, and renal sympathetic nerve activity (RSNA) evoked by static contraction of the triceps surae muscles. Blockade of N-methyl-D-aspartate (NMDA) receptors by intrathecal injection of DL-2-amino-5-phosphonovaleric acid had no effect on the initial phase of the pressor, ventilatory, and RSNA responses to contraction but did attenuate the secondary phase of these responses. Subsequent blockade of non-NMDA receptors in the lumbosacral spinal cord by intrathecal injection of 6-cyano-7-nitroquinoxaline-2,3-dione attenuated both the initial phase of the pressor, RSNA, and ventilatory responses to contraction and the secondary phase of these responses. In addition, NMDA-receptor blockade had no effect on the pressor or RSNA responses to tendon stretch, whereas non-NMDA-receptor blockade abolished these responses. We confirmed that our results were not related to the order of the antagonists injected by performing a series of experiments in which a non-NMDA-receptor antagonist was injected first. Our findings suggest that non-NMDA receptors mediate the spinal transmission of the initial and secondary phases of the pressor, RSNA, and ventilatory responses to contraction and tendon stretch. Therefore, non-NMDA receptors in the dorsal horn appear to be involved in the spinal processing of input from mechanoreceptors and metaboreceptors. Our findings also suggest that NMDA receptors mediate the spinal transmission of the secondary phase of the pressor, RSNA, and ventilatory responses to contraction but do not mediate the spinal transmission of the responses to tendon stretch. Therefore, NMDA receptors in the dorsal horn appear to be involved in the spinal processing of input from metaboreceptors.