Role played by purinergic receptors on muscle afferents in evoking the exercise pressor reflex.

The exercise pressor reflex is believed to be evoked, in part, by multiple metabolic stimuli that are generated when blood supply to exercising muscles is inadequate to meet metabolic demand. Recently, ATP, which is a P2 receptor agonist, has been suggested to be one of the metabolic stimuli evoking this reflex. We therefore tested the hypothesis that blockade of P2 receptors within contracting skeletal muscle attenuated the exercise pressor reflex in decerebrate cats. We found that popliteal arterial injection of pyridoxal phosphate-6-azophenyl-2',4'-disulfonic acid (PPADS; 10 mg/kg), a P2 receptor antagonist, attenuated the pressor response to static contraction of the triceps surae muscles. Specifically, the pressor response to contraction before PPADS averaged 36 +/- 3 mmHg, whereas afterward it averaged 14 +/- 3 mmHg (P < 0.001; n = 19). In addition, PPADS attenuated the pressor response to postcontraction circulatory occlusion (P < 0.01; n = 11). In contrast, popliteal arterial injection of CGS-15943 (250 micro g/kg), a P1 receptor antagonist, had no effect on the pressor response to static contraction of the triceps surae muscles. In addition, popliteal arterial injection of PPADS but not CGS-15943 attenuated the pressor response to stretch of the calcaneal (Achilles) tendon. We conclude that P2 receptors on the endings of thin fiber muscle afferents play a role in evoking both the metabolic and mechanoreceptor components of the exercise pressor reflex.     

Acid-sensing ion and epithelial sodium channels do not contribute to the mechanoreceptor component of the exercise pressor reflex

Amiloride, injected into the popliteal artery, has been reported to attenuate the reflex pressor response to static contraction of the triceps surae muscles. Both mechanical and metabolic stimuli arising in contracting skeletal muscle are believed to evoke this effect, which has been named the exercise pressor reflex. Amiloride blocks both acid-sensing ion channels, as well as epithelial sodium channels. Nevertheless, amiloride is thought to block the metabolic stimulus to the reflex, because this agent has been shown to attenuate the reflex pressor response to injection of lactic acid into the arterial supply of skeletal muscle. The possibility exists, however, that amiloride may also block mechanical stimuli evoking the exercise pressor reflex. The mechanical component of the reflex can be assessed by measuring renal sympathetic nerve activity during the first 2-5 s of contraction. During this period of time, the sudden tension developed by contraction onset briskly discharges mechanoreceptors, whereas it has little effect on the discharge of metaboreceptors. We, therefore, examined the effect of amiloride (0.5 microg/kg) injected into the popliteal artery on the renal sympathetic and pressor responses to static contraction of the triceps surae muscles in decerebrated cats. We found that amiloride significantly attenuated the pressor and renal sympathetic responses to contraction; for the latter variable, the attenuation started 10 s after the onset of contraction. Our findings lead us to conclude that acid-sensing ion channels and epithelial sodium channels play little, if any, role in evoking the mechanical component of the exercise pressor reflex.     

Gadolinium attenuates exercise pressor reflex in cats

The exercise pressor reflex, which arises from the contraction-induced stimulation of group III and IV muscle afferents, is widely believed to be evoked by metabolic stimuli signaling a mismatch between blood/oxygen demand and supply in the working muscles. Nevertheless, mechanical stimuli may also play a role in evoking the exercise pressor reflex. To determine this role, we examined the effect of gadolinium, which blocks mechanosensitive channels, on the exercise pressor reflex in both decerebrate and alpha-chloralose-anesthetized cats. We found that gadolinium (10 mM; 1 ml) injected into the femoral artery significantly attenuated the reflex pressor responses to static contraction of the triceps surae muscles and to stretch of the calcaneal (Achilles) tendon. In contrast, gadolinium had no effect on the reflex pressor response to femoral arterial injection of capsaicin (5 microg). In addition, gadolinium significantly attenuated the responses of group III muscle afferents, many of which are mechanically sensitive, to both static contraction and to tendon stretch. Gadolinium, however, had no effect on the responses of group IV muscle afferents, many of which are metabolically sensitive, to either static contraction or to capsaicin injection. We conclude that mechanical stimuli arising in contracting skeletal muscles contribute to the elicitation of the exercise pressor reflex.     

alpha,beta-Methylene ATP elicits a reflex pressor response arising from muscle in decerebrate cats.

In part, the exercise pressor reflex is believed to be evoked by chemical stimuli signaling that blood supply to exercising muscles is not adequate to meet its metabolic demands. There is evidence that either ATP or adenosine may function as one of these chemical stimuli. For example, muscle interstitial concentrations of both substances have been found to increase during exercise. This finding led us to test the hypothesis that popliteal arterial injection of alpha,beta-methylene ATP (5, 20, and 50 microg/kg), which stimulates P2X receptors, and 2-chloroadenosine (25 microg/kg), which stimulates P1 receptors, evokes reflex pressor responses in decerebrate, unanesthetized cats. We found that popliteal arterial injection of the two highest doses of alpha,beta-methylene ATP evoked pressor responses, whereas popliteal arterial injection of 2-chloroadenosine did not. In addition, the pressor responses evoked by alpha,beta-methylene ATP were blocked either by section of the sciatic nerve or by prior popliteal arterial injection of pyridoxal phosphate-6-azophenyl-2',4'-disulfonic acid (10 mg/kg), a selective P2-receptor antagonist. We conclude that the stimulation of P2 receptors, which are accessible through the vascular supply of skeletal muscle, evokes reflex pressor responses. In addition, our findings are consistent with the hypothesis that the stimulation of P2 receptors comprises part of the metabolic error signal evoking the exercise pressor reflex.     

P2 antagonist PPADS attenuates responses of thin fiber afferents to static contraction and tendon stretch

Injection into the arterial supply of skeletal muscle of pyridoxal phosphate-6-azophenyl-2',4'-disulfonic acid (PPADS), a P2 receptor antagonist, has been shown previously to attenuate the reflex pressor responses to both static contraction and to tendon stretch. In decerebrated cats, we tested the hypothesis that PPADS attenuated the responses of groups III and IV muscle afferents to static contraction as well as to tendon stretch. We found that injection of PPADS (10 mg/kg) into the popliteal artery attenuated the responses of both group III (n = 16 cats) and group IV afferents (n = 14 cats) to static contraction. Specifically, static contraction before PPADS injection increased the discharge rate of the group III afferents from 0.1 +/- 0.05 to 1.6 +/- 0.5 impulses/s, whereas contraction after PPADS injection increased the discharge of the group III afferents from 0.2 +/- 0.1 to only 1.0 +/- 0.5 impulses/s (P < 0.05). Likewise, static contraction before PPADS injection increased the discharge rate of the group IV afferents from 0.3 +/- 0.1 to 1.0 +/- 0.3 impulses/s, whereas contraction after PPADS injection increased the discharge of the group IV afferents from 0.2 +/- 0.1 to only 0.3 +/- 0.1 impulses/s (P < 0.05). In addition, PPADS significantly attenuated the responses of group III afferents to tendon stretch but had no effect on the responses of group IV afferents. Our findings suggest that both groups III and IV afferents are responsible for evoking the purinergic component of the exercise pressor reflex, whereas only group III afferents are responsible for evoking the purinergic component of the muscle mechanoreflex that is evoked by tendon stretch.     

VR-1 receptor blockade attenuates the pressor response to capsaicin but has no effect on the pressor response to contraction in cats

Vanilloid type 1 (VR-1) receptors are stimulated by capsaicin and hydrogen ions, the latter being a by-product of muscular contraction. We tested the hypothesis that activation of VR-1 receptors during static contraction contributes to the exercise pressor reflex. We established a dose of iodoresinaferatoxin (IRTX), a VR-1 receptor antagonist, that blocked the pressor response to capsaicin injected into the arterial supply of muscle. Specifically, in eight decerebrated cats, we compared pressor responses to capsaicin (10 mug) injected into the right popliteal artery, which was subsequently injected with IRTX (100 mug), with those to capsaicin injected into the left popliteal artery, which was not injected with IRTX. The pressor response to capsaicin injected into the right popliteal artery averaged 49 +/- 9 mmHg before IRTX and 9 +/- 2 mmHg after IRTX (P < 0.05). In contrast, the pressor response to capsaicin injected into the left popliteal artery averaged 46 +/- 10 mmHg "before" and 43 +/- 6 mmHg "after" (P > 0.05). We next determined whether VR-1 receptors mediated the pressor response to contraction of the triceps surae. During contraction without circulatory occlusion, the pressor response before IRTX (100 mug) averaged 26 +/- 3 mmHg, whereas it averaged 22 +/- 3 mmHg (P > 0.05) after IRTX (n = 8). In addition, during contraction with occlusion, the pressor responses averaged 35 +/- 3 mmHg before IRTX injection and 49 +/- 7 mmHg after IRTX injection (n = 7). We conclude that VR-1 receptors play little role in evoking the exercise pressor reflex.     

Muscle pressor reflex: potential role of vanilloid type 1 receptor and acid-sensing ion channel.

Reflex cardiovascular responses to muscle contraction are mediated by mechanical and metabolic stimulation of thin muscle afferent fibers. Metabolic stimulants and receptors involved in responses are uncertain. Capsaicin depolarizes thin sensory afferent nerves that have vanilloid type 1 receptors (VR1). Among potential endogenous ligands of thin fibers, H+ has been suggested as a metabolite mediating the reflex muscle response as well as a potential stimulant of VR1. It has also been suggested that acid-sensing ion channels (ASIC) mediate H+, evoking afferent nerve excitation. We have examined the roles of VR1 and ASIC in mediating cardiovascular reflex responses to acid stimulation of muscle afferents in a rat model. In anesthetized rats, injections of capsaicin into the arterial blood supply of triceps surae muscles evoked a biphasic response (n = 6). An initial fall in mean arterial pressure (from baseline of 95.8 +/- 9.5 to 70.4 +/- 4.5 mmHg, P < 0.05 vs. baseline) was followed by an increase (to 131.6 +/- 11.3 mmHg, P < 0.05 vs. baseline). Anandamide (an endogenous substance that activates VR1) induced the same change in blood pressure as did capsaicin. The pressor (but not depressor) component of the response was blocked by capsazepine (a VR1 antagonist) and section of afferent nerves. In decerebrate rats (n = 8), H+ evoked a pressor response that was not blocked by capsazepine but was attenuated by amiloride (an ASIC blocker). In rats (n = 12) pretreated with resiniferatoxin to destroy muscle afferents containing VR1, capsaicin and H+ responses were blunted. We conclude that H+ stimulates ASIC, evoking the reflex response, and that ASIC are likely to be frequently found on afferents containing VR1. The data also suggest that VR1 and ASIC may play a role in processing of muscle afferent signals, evoking the muscle pressor reflex.     

PPADS does not block contraction-induced prostaglandin E2 synthesis in cat skeletal muscle

Pyridoxal-phosphate-6-azophenyl-2'-4-disulfonate (PPADS), a purinergic 2 (P2) receptor antagonist, has been shown to attenuate the exercise pressor reflex in cats. In vitro, however, PPADS has been shown to block the production of prostaglandins, some of which play a role in evoking the exercise pressor reflex. Thus the possibility exists that PPADS blocks the exercise pressor reflex through a reduction in prostaglandin synthesis rather than through the blockade of P2 receptors. Using microdialysis, we collected interstitial fluid from skeletal muscle to determine prostaglandin E2 (PGE2) concentrations during the intermittent contraction of the triceps surae muscle before and after a popliteal arterial injection of PPADS (10 mg/kg). We found that the PGE2 concentration increased in response to the intermittent contraction before and after the injection of PPADS (both, P < 0.05). PPADS reduced the pressor response to exercise (P < 0.05) but had no effect on the magnitude of PGE2 production during contraction (P = 0.48). These experiments demonstrate that PPADS does not block the exercise pressor reflex through a reduction in PGE2 synthesis. We suggest that PGE2 and P2 receptors play independent roles in stimulating the exercise pressor reflex.     

Role played by P2X and P2Y receptors in evoking the muscle chemoreflex.

The role played by purinergic 2Y receptors in evoking the muscle chemoreflex is not well defined. To shed light on this issue, we compared the pressor responses with popliteal arterial injection of UTP (1 mg/kg), a selective P2Y agonist, with those to popliteal arterial injection of ATP (1 mg/kg), a P2X and P2Y agonist, and to alpha,beta-methylene ATP (50 mug/kg), a selective P2X1 and P2X3 agonist, in decerebrate unanesthetized cats. We found that injection of ATP and alpha,beta-methylene ATP increased mean arterial pressure by 19 +/- 2 and 15 +/- 4 mmHg, whereas UTP had no affect on arterial pressure. In addition, the pressor responses to injection of ATP and alpha,beta-methylene ATP were abolished by section of the sciatic nerve, demonstrating that they were reflex in origin. We conclude that P2Y receptors on thin fiber muscle afferents play no role in evoking the muscle chemoreflex.     

A perspective on the muscle reflex: implications for congestive heart failure.

In this review we examine the exercise pressor reflex in health and disease. The role of metabolic and mechanical stimulation of thin fiber muscle afferents is discussed. The role ATP and lactic acid play in stimulating and sensitizing these afferents is examined. The role played by purinergic receptors subdivision 2, subtype X, vanilloid receptor subtype 1, and acid-sensing ion channels in mediating the effects of ATP and H+ are discussed. Muscle reflex activation in heart failure is then examined. Data supporting the concept that the metaboreflex is attenuated and that the mechanoreflex is accentuated are presented. The role the muscle mechanoreflex plays in evoking renal vasoconstriction is also described.     

Attenuation of reflex pressor and ventilatory responses to static contraction by an NK-1 receptor antagonist.

The chemical messengers released onto second-order dorsal horn neurons from the spinal terminals of contraction-activated group III and IV muscle afferents have not been identified. One candidate is the tachykinin substance P. Related to substance P are two other tachykinins, neurokinin A (NKA) and neurokinin B (NKB), which, like substance P, have been isolated in the dorsal horn of the spinal cord and have receptors there. Whether NKA or NKB plays a transmitter/modulator role in the spinal processing of the exercise pressor reflex is unknown. Therefore, we tested the following hypotheses. After the intrathecal injection of a highly selective NK-1 (substance P) receptor antagonist onto the lumbosacral spinal cord, the reflex pressor and ventilatory responses to static muscular contraction will be attenuated. Likewise, after the intrathecal injection either of an NK-2 (NKA) receptor antagonist or an NK-3 (NKB) receptor antagonist onto the lumbrosacral spinal cord, the reflex pressor and ventilatory responses to static contraction will be attenuated. We found that, 10 min after the intrathecal injection of 100 micrograms of the NK-1 receptor antagonist, the pressor and ventilatory responses to contraction were significantly (P < 0.05) attenuated. Mean arterial pressure was attenuated by 13 +/- 3 mmHg (48%) and minute volume of ventilation by 120 +/- 38 ml/min (34%). The cardiovascular and ventilatory responses to contraction before either 100 micrograms of the NK-2 receptor antagonist or 100 micrograms of the NK-3 receptor antagonist were not different (P > 0.05) from those after the NK-2 or the NK-3 receptor antagonists.(ABSTRACT TRUNCATED AT 250 WORDS)     

Thin-fiber mechanoreceptors reflexly increase renal sympathetic nerve activity during static contraction

The renal vasoconstriction induced by the sympathetic outflow during exercise serves to direct blood flow from the kidney toward the exercising muscles. The renal circulation seems to be particularly important in this regard, because it receives a substantial part of the cardiac output, which in resting humans has been estimated to be 20%. The role of group III mechanoreceptors in causing the reflex renal sympathetic response to static contraction remains an open question. To shed some light on this question, we recorded the renal sympathetic nerve responses to static contraction before and after injection of gadolinium into the arterial supply of the statically contracting triceps surae muscles of decerebrate unanesthetized and chloralose-anesthetized cats. Gadolinium has been shown to be a selective blocker of mechanogated channels in thin-fiber muscle afferents, which comprise the afferent arm of the exercise pressor reflex arc. In decerebrate (n = 15) and chloralose-anesthetized (n = 12) cats, we found that gadolinium (10 mM; 1 ml) significantly attenuated the renal sympathetic nerve and pressor responses to static contraction (60 s) after a latent period of 60 min; both responses recovered after a latent period of 120 min. We conclude that thin-fiber mechanoreceptors supplying contracting muscle are involved in some of the renal vasoconstriction evoked by the exercise pressor reflex.     

Increasing gracilis muscle interstitial potassium concentrations stimulate group III and IV afferents

Static muscular contraction reflexly increases arterial blood pressure and heart rate. One possible mechanism evoking this reflex is that potassium accumulates in the interstitial space of a working muscle to stimulate group III and IV afferents whose activation in turn evokes a pressor response. The responses of group III and IV muscle afferents to increases in interstitial potassium concentrations within the range evoked by static contraction are unknown. Thus we injected potassium chloride into the gracilis artery of anesthetized dogs while we measured both gracilis muscle interstitial potassium concentrations with potassium-selective electrodes and the impulse activity of afferents in the gracilis nerve. We found that increasing interstitial potassium concentrations to levels similar to those seen during static contraction stimulated 14 of 16 group III and 29 of 31 group IV afferents. The responses of the afferents to potassium were concentration dependent. The typical response to potassium consisted of a burst of impulses, an effect that returned to control firing rates within 26 s, even though interstitial potassium concentrations remained elevated for several minutes. Although our results suggest that potassium may play a role in initiating the reflex cardiovascular responses to static muscular contraction, the accumulation of this ion does not appear to be solely responsible for maintaining the pressor response for the duration of the contraction.     

Blockade of purinergic 2 receptors attenuates the mechanoreceptor component of the exercise pressor reflex

The finding that pyridoxalphosphate-6-azophenyl-2,4-disulfonic acid (PPADS), a P2 antagonist, attenuated the pressor response to calcaneal tendon stretch, a purely mechanical stimulus, raises the possibility that P2 receptors sensitize mechanoreceptors to static contraction of the triceps surae muscles. The mechanical component of the exercise pressor reflex, which is evoked by static contraction, can be assessed by measuring renal sympathetic nerve activity during the first 2-5 s of this maneuver. During this period of time, group III mechanoreceptors often discharge explosively in response to the sudden tension developed at the onset of contraction. In decerebrated cats, we, therefore, examined the effect of PPADS (10 mg/kg) injected into the popliteal artery on the renal sympathetic and pressor responses to contraction and stretch. We found that PPADS significantly attenuated the renal sympathetic response to contraction, with the effect starting 2 s after its onset and continuing throughout its 60-s period. PPADS also significantly attenuated the renal sympathetic nerve response to stretch, but did so after a latency of 10 s. Our findings lead us to conclude that P2 receptors sensitize group III muscle afferents to contraction. The difference in the onset latency between the PPADS-induced attenuation of the renal sympathetic response to contraction and the renal sympathetic response to stretch is probably due to the sensitivities of different populations of group III afferents to ATP released during contraction and stretch.     

Comparison between the effect of static contraction and tendon stretch on the discharge of group III and IV muscle afferents.

The exercise pressor reflex is evoked by both mechanical and metabolic stimuli. Tendon stretch does not increase muscle metabolism and therefore is used to investigate the mechanical component of the exercise pressor reflex. An important assumption underlying the use of tendon stretch to study the mechanical component of the exercise pressor reflex is that stretch stimulates the same group III mechanosensitive muscle afferents as does static contraction. We have tested the veracity of this assumption in decerebrated cats by comparing the responses of group III and IV muscle afferents to tendon stretch with those to static contraction. The tension-time indexes as well as the peak tension development for both maneuvers did not significantly differ. We found that static contraction of the triceps surae muscles stimulated 18 of 30 group III afferents and 8 of 11 group IV afferents. Similarly, tendon stretch stimulated 14 of 30 group III afferents and 3 of 11 group IV afferents. However, of the 18 group III afferents that responded to static contraction and the 14 group III afferents that responded to tendon stretch, only 7 responded to both stimuli. On average, the conduction velocities of the 18 group III afferents that responded to static contraction (11.6 +/- 1.6 m/s) were significantly slower (P = 0.03) than those of the 14 group III afferents that responded to tendon stretch (16.7 +/- 1.5 m/s). We have concluded that tendon stretch stimulated a different population of group III mechanosensitive muscle afferents than did static contraction. Although there is some overlap between the two populations of group III mechanosensitive afferents, it is not large, comprising less than half of the group III afferents responding to static contraction.     

Muscle mechanosensitive receptors close to the myotendinous junction of the Achilles tendon elicit a pressor reflex.

Feedback regulation by activation of mechanosensitive afferents in the exercising muscle causes the cardiovascular and sympathetic nerve responses, which follow tension development and are almost identical between static contraction and passive stretch. The precise location of the mechanoreceptors contributing to the exercise pressor reflex, however, remained unknown. To test the hypothesis that the mechanoreceptors will be located around the myotendinous junction to monitor a change in muscle tension than a change in muscle length, we examined the reflex cardiovascular responses to passive stretch of the triceps surae muscle in anesthetized rats with three interventions; systemic injection of gadolinium, cutting the Achilles tendon, and local injection of lidocaine into the myotendinous junction. Gadolinium (42 micromol/kg iv) blunted the increases in heart rate and mean arterial blood pressure during passive stretch by 36 and 22-26%, respectively, suggesting that the reflex cardiovascular responses were evoked by stimulation of muscle mechanosensitive receptors. The cardiovascular responses to passive stretch were not different between the cut Achilles tendon and the intact tendon in the same rats, suggesting that any mechanoreceptors, terminated in the more distal part of the tendon, did not contribute to the reflex cardiovascular responses. Lidocaine (volume, 0.04-0.1 ml) injected into the myotendinous junction blunted the stretch-induced increases in heart rate and mean arterial blood pressure by 37-49 and 27-34%, respectively. We conclude that the muscle mechanosensitive receptors evoking the reflex cardiovascular responses at least partly locate at or close to the myotendinous junction of the Achilles tendon.     

Central integration of muscle reflex and arterial baroreflex in midbrain periaqueductal gray: roles of GABA and NO

It has been suggested that the midbrain periaqueductal gray (PAG) is a neural integrating site for the interaction between the muscle pressor reflex and the arterial baroreceptor reflex. The underlying mechanisms are poorly understood. The purpose of this study was to examine the roles of GABA and nitric oxide (NO) in modulating the PAG integration of both reflexes. To activate muscle afferents, static contraction of the triceps surae muscle was evoked by electrical stimulation of the L7 and S1 ventral roots of 18 anesthetized cats. In the first group of experiments (n = 6), the pressor response to muscle contraction was attenuated by bilateral microinjection of muscimol (a GABA receptor agonist) into the lateral PAG [change in mean arterial pressure (DeltaMAP) = 24 +/- 5 vs. 46 +/- 8 mmHg in control]. Conversely, the pressor response was significantly augmented by 0.1 mM bicuculline, a GABAA receptor antagonist (DeltaMAP = 65 +/- 10 mmHg). In addition, the effect of GABAA receptor blockade on the reflex response was significantly blunted after sinoaortic denervation and vagotomy (n = 4). In the second group of experiments (n = 8), the pressor response to contraction was significantly attenuated by microinjection of L-arginine into the lateral PAG (DeltaMAP = 26 +/- 4 mmHg after L-arginine injection vs. 45 +/- 7 mmHg in control). The effect of NO attenuation was antagonized by bicuculline and was reduced after denervation. These data demonstrate that GABA and NO within the PAG modulate the pressor response to muscle contraction and that NO attenuation of the muscle pressor reflex is mediated via arterial baroreflex-engaged GABA increase. The results suggest that the PAG plays an important role in modulating cardiovascular responses when muscle afferents are activated.     

Spinal vasopressin modulates the reflex cardiovascular response to static contraction.

Recent evidence has demonstrated that arginine vasopressin (AVP) may modulate primary afferent activity of nociceptors in the dorsal horn of the spinal cord. Because nociceptors are group III and IV afferents, spinal AVP also may modulate the activity of group III and IV afferents that cause reflex cardiovascular responses to muscle contraction. Thus, we compared the pressor (mean arterial pressure), myocardial contractile (dP/dt), and heart rate (HR) responses to electrically induced static contraction of the cat hindlimb before and after lumbar intrathecal (IT) injection (L1-L7) of AVP (n = 9), the V1 receptor antagonist d(CH2)5Tyr(Me)AVP (n = 6), the V2 receptor antagonist d(CH2)5[D-Ile2,Ile4,Ala-NH2(9)]AVP (n = 6), and the V2 agonist [Val4,D]AVP (n = 8). After IT injection of AVP (0.1 or 1 nmol) the pressor and contractile responses to static contraction were attenuated by 55 and 44%, respectively. HR was unchanged. Forty-five to 60 min after AVP injection, the contraction-induced pressor and contractile responses were restored to control levels. V1 receptor blockade augmented contraction-induced increases in mean arterial pressure (36%) and dP/dt (49%) but not HR. V2 receptor blockade had no effect on the cardiovascular response to contraction, whereas selective V2 stimulation attenuated the dP/dt (-20%) and HR (-33%) responses but not the pressor response. These results suggest that AVP attenuates the reflex cardiovascular response to contraction by modulating sensory nerve transmission from contracting muscle primarily via a V1 receptor mechanism in the lumbar spinal cord.     

Vanilloid type 1 receptor and the acid-sensing ion channel mediate acid phosphate activation of muscle afferent nerves in rats.

Reflex cardiovascular responses to contracting skeletal muscle are mediated by mechanical and metabolic stimulation of thin-fiber muscle afferents. Diprotonated phosphate (H2PO4-) excites those thin-fiber nerves and evokes the muscle pressor reflex. The receptors mediating this response are unknown. Thus we examined the role played by purinergic receptors, vanilloid type 1 receptors (VR1), and acid-sensing ion channels (ASIC) in mediating H2PO4- -evoked pressor responses. Phosphate and blocking agents were injected into the arterial blood supply of the hindlimb muscles of 53 decerebrated rats. H2PO4- (86 mM, pH 6.0) increased mean arterial pressure by 25 +/- 2 mmHg, whereas monoprotonated phosphate (HPO4(2-), pH 7.5) had no effect. Pyridoxalphosphate-6-azophenyl-2',4'-disulfonic acid (a purinergic receptor antagonist, 2 mM) did not block the response. However, capsazepine (a VR1 antagonist, 1 mg/kg) attenuated the reflex by 60% and amiloride (an ASIC blocker, 6 microg/kg) by 52%. Of note, the H2PO4- -induced pressor response was attenuated by 87% when both capsazepine and amiloride were injected before the H2PO4-. In conclusion, VR1 and ASIC mediate the pressor response due to H2PO4-. The H2PO4- -evoked response was greater when VR1 and ASIC blockers were given simultaneously than when the respective blockers were given separately. Our laboratory's previous study has shown that H+ stimulates ASIC (but not VR1) on thin-fiber afferent nerves in evoking the reflex response. Thus VR1 and ASIC are likely to play a coordinated and interactive role in processing the muscle afferent response to H2PO4-. Furthermore, the physiological mechanisms mediating the response to H+ and H2PO4- are likely to be different.     

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.