Synaptic responses produced in lobster abdominal postural motor neurons by mechanical stimulation of the swimmeret

Interneurons involved in the control of multiple motor centers in crayfish

A number of studies have suggested that abdominal positioning interneurons (APIs) in the crayfish Procambarus clarkii can influence activity in multiple motor centers. Previous work on this population of neurons has demonstrated that they control the activity of tonic abdominal motor neurons (MNs) which generate postural movements of the abdomen and, to some extent, the activity of swimmeret MNs. This investigation demonstrates that many identified APIs also affect the activity of two populations of MNs which open and close the uropods and, in some cases, that of the swimmeret MNs as well. The majority (64%) of APIs examined in this study have an excitatory effect on both populations of uropod MNs. A smaller number (23%) increase the level of activity in one population of uropod MNs, and suppress, or have no effect on, the activity of the other population of uropod MNs. Approximately 25% of the APIs which were examined influence the output of swimmeret MNs, in addition to affecting the activity of uropod MNs. There are also indications that previous estimates of the number of APIs may have been too low. This is based on the observation that many APIs possess what appear to be similar morphologies but generate different patterns of motor output. Taken together, these findings support the idea that APIs influence the output of multiple motor centers which play a role in the control of general body posture and balance in crayfish.

Mechanosensory afferents innervating the swimmerets of the lobster. I. Afferents activated by cuticular deformation

The mechanosensory innervation of the lobster (Homarus americanus) swimmeret was examined by electrophysiologically recording afferent spike responses initiated by localized mechanical stimulation of the caudal surface of the swimmeret. Two functional groups of subcuticular hypodermal mechanoreceptors innervate the swimmeret. Afferents of one group innervate the small discrete "ridges" of calcified cuticle lining the margins of both swimmeret rami. Putative ridge receptors are bipolar sensory neurons responding phasically to deformation of the ridge cuticle with the number and frequency of impulses produced dependent on stimulus strength and velocity. Afferents of the second group, which innervate substantial areas of hypodermis underlying the soft, flexible cuticular regions of the swimmeret, were designated "wide-field" hypodermal mechanoreceptors. These neurons have multiterminal receptive fields and respond phaso-tonically to cuticular distortion. The response properties of both types of hypodermal mechanoreceptors imply that they are activated during the characteristic beating movements of the swimmerets.

Sensory inhibition of flexion producing interneurons in lobster abdomen

Mechanosensory stimulation of an abdominal swimmeret initiates a fictive extension which includes flexion inhibition. The role of flexion producing interneurons (FPIs) in this motor program was examined by recording from a pair of FPIs which excite flexor motor neuron f3. The afferent-FPI-f3 pathway includes at least 5 levels of neural activity. Since swimmeret stimulation hyperpolarizes the FPIs, and mechanosensory afferents are not known to be inhibitory, sensory interneurons must connect the afferent with the FPIs. The generalized receptive fields and long latencies of the FPI response support polysynaptic afferent-FPI connections. The poor correlation between f3FPI spikes and f3 EPSPs they evoke, and the 15 ms delay for initiation of these EPSPs, suggest that additional premotor interneurons are interposed between f3FPI and f3. Since restricted stimulation of swimmeret sensilla generates IPSPs in f3 without affecting f3FPI activity, f3FPI and f3 must be inhibited by different interneurons. Sensory evoked FPI inhibition contributes to the flexion inhibition component of the swimmeret evoked responses since hyperpolarization of f3FPI to block f3FPI spiking during spontaneous flexion activity decreases ongoing f3 spike discharge. Coupling between f3FPI and f3 activities during spontaneously initiated postural flexions supports this conclusion.

GABA mediated inhibition of abdominal postural flexion in lobster

Swimmeret mechanostimulation initiates an abdominal extension program which includes flexion inhibition. Agonists and antagonists were used to examine the GABAergic nature of inhibitory responses recorded intracellularly from a flexion producing interneuron (FPI 303) and flexor motor neuron (f3) pair, and extracellularly from the other flexor efferents. The GABA antagonist picrotoxin (PTX) enhanced spontaneous flexion. As PTX levels increased, the swimmeret evoked response shifted from inhibition of flexion (less than 10 microM), to inhibition followed by excitation (10-30 microM), to flexion excitation (greater than or equal to 50 microM). The irreversibility of PTX effects, and the absence of bicuculline or baclofen induced changes in flexion activity, suggests that the receptors differ from mammalian GABA receptors. Both GABA and its agonist muscimol suppressed flexion activity and reduced intracellular potential amplitudes. Proof that PTX acts by binding the GABA receptor was obtained by observing that the addition of GABA or muscimol to preparations pretreated with PTX did not affect either spontaneous or swimmeret evoked activities, or intracellular potential amplitudes. These results imply involvement of GABAergic interneurons in the abdominal motor programs which inhibit flexion.

Intersegmental modulation of abdominal postural responses initiated by mechanostimulation of the swimmeret in lobster

In a multiganglionic preparation of the lobster abdominal nerve cord, composed of the first through fifth ganglia (A1-A5) and attached second swimmeret, tactile stimulation of the cuticular surface of the swimmeret initiates a postural motor program in A2 for abdominal extension, whereas deflection of feathered hair sensilla that fringe the swimmeret rami does not affect postural motor activity recorded from A2 (Kotak and Page, 1986a). This report demonstrates that partial isolation of A2 from adjacent abdominal ganglia by sectioning the A1-A2 or the A2-A3 connectives both increases the strength of the extension response evoked by cuticular stimulation and disinhibits a postural flexion inhibition response initiated by feathered hair stimulation. Complete isolation of A2, by cutting the A1-A2 and the A2-A3 connectives, further increases the strength of these postural responses. Intersegmental inhibition of these responses originates in the ganglia adjacent to A2, since mechanoresponsiveness of A2 is not affected by resection of a more distant connective (A3-A4). These results provide evidence for the presence in adjacent abdominal ganglia of intersegmental interneurons that regulate the access of swimmeret sensory activity to the postural motor neurons in A2.