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Local interneurons in the terminal abdominal ganglion of the crayfish (1982)

Reichert, Heinrich ; Plummer, Mark R. ; Hagiwara, Grace ; [et al.]

Springer

Journal of comparative physiology 149 (1982), S. 145-162

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ISSN: 1432-1351

Source: Springer Online Journal Archives 1860-2000

Topics: Biology , Medicine

Notes: Summary 1. On the basis of comparisons between total cell counts and cell counts of cobalt backfills of all roots and connectives leaving the ganglion, we estimate that 38–50% of the approximately 650 neurons in the last abdominal ganglion of the crayfish are local interneurons. 2. The soma size distributions for all of the neurons and for projecting neurons were compared. The comparison indicates that most local neurons are small. All neurons larger than 40 μm (n = 121) have axons that leave the ganglion, while 77 % of neurons smaller than 21 μm (n = 140) are local interneurons (Figs. 1,2). 3. We have recorded and filled with Lucifer yellow 63 local interneurons from which 15 unambiguously different types could be recognized. Five criteria were used in our initial classification. In addition to structure, we noted if each local interneuron was spiking or nonspiking, and, in our most complete experiments, if it was capable of affecting motor activity or projecting interneuron activity when depolarized. We also tried to determine its optimal sensory modality and receptive field. 4. Of the 15 interneuron types we encountered, 5 types (represented by 11 fills) were unilateral, nonspiking, premotor interneurons in the uropod motor circuits (Figs. 3–6). 5. Two types of local premotor interneurons were bilateral and spiking. One excited exopodite motor neurons on one side only. Our evidence suggests that the cells had a nonspiking input region on one side and a spiking output region on the other (Figs. 7–9). 6. Six other types of interneuron were encountered for which we have no evidence of motor effects. All of these neurons had bilateral but asymmetric processes, and were spiking on the putative output side. Some of these neurons appear to be part of sensory processing circuits on the basis of clear modality, distinct receptive field, and short-latency response to sensory input (Figs. 10–12). 7. Two nonspiking, bilateral interneurons were found (Fig. 13). These cells had very large processes which permitted them to be penetrated repeatedly and studied in detail. Although nonspiking, these neurons had separate input and output sides. They are involved in lateral inhibition within the sensory circuits (Reichert et al., submitted). 8. Our results indicate considerable heterogeneity in the properties and functions of local interneurons. Three basic modes of operation were found: (i) five types of interneurons functioned without spikes and may have diffuse input and output; (ii) eight types of bilateral interneurons had properties suggestive of nonspiking input and spiking output sides; and (iii) two bilateral neurons were nonspiking but had distinct input and output sides.

Type of Medium: Electronic Resource

URL: http://dx.doi.org/10.1007/BF00619210

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Reversible uncoupling of inactivation in N-type calcium channels (1991)

Plummer, Mark R. ; Hess, Peter

[s.l.] : Nature Publishing Group

Nature 351 (1991), S. 657-659

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ISSN: 1476-4687

Source: Nature Archives 1869 - 2009

Topics: Biology , Chemistry and Pharmacology , Medicine , Natural Sciences in General , Physics

Notes: [Auszug] A widely used criterion to distinguish neuronal N-type Ca2+ channels from L-type Ca2+ channels sensitive to dihydropyridine (DHP) has been the assignment of inactivating (transient) components of high-threshold-activated inward Ca2+ current to N-type channels and of maintained current components to ...

Type of Medium: Electronic Resource

URL: http://dx.doi.org/10.1038/351657a0

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Identified nonspiking local interneurons mediate nonrecurrent, lateral inhibition of crayfish mechanosensory interneurons (1983)

Reichert, Heinrich ; Plummer, Mark R. ; Wine, Jeffrey J.

Springer

Journal of comparative physiology 151 (1983), S. 261-276

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ISSN: 1432-1351

Source: Springer Online Journal Archives 1860-2000

Topics: Biology , Medicine

Notes: Summary 1. We have used intracellular neuropil recordings and dye injection to identify a pair of nonspiking, Local, Directionally Selective (LDS) interneurons in the terminal ganglion of the crayfish,Procambarus clarkii. The neurons have bilateral but asymmetric processes connected by a thick (ca. 17 μm) segment in the dorsal neuropil. The processes ipsilateral to the soma are smooth while those on the other side have numerous varicosities (Figs. 1, 2). 2. We found headward water movement to be the best natural stimulus for depolarizing the LDS interneurons (Fig. 3). Neither water movement nor any combination of electrical stimulation of afferents and current injection into the LDS interneurons ever caused them to spike. 3. The receptive field of the LDS interneuron is mainly restricted to the uropods ipsilateral to its cell body, and within that field the afferents from the endopodite provide the strongest excitation. The afferent-produced PSPs are chemically mediated and are probably monosynaptic; they occur with an estimated synaptic delay of approximately 1 ms (Figs. 4, 5). 4. The output of the LDS interneuron is contralateral to the input side and is associated with the processes having varicosities. Thus, although the neuron is nonspiking, it is functionally polarized to receive input on one side of the ganglion and convey it to the other side. 5. All known output connections of the LDS interneuron are inhibitory and highly specific. The LDS interneuron exclusively inhibits projection interneurons excited by headward afferents on the output side. Not all headward projection interneurons are inhibited equally (Fig. 6 and Table 1). 6. The inhibitory effect of the LDS interneuron is mediated postsynaptically by chemical IPSPs (Fig. 7). The LDS cell does not cause inhibition at rest potential, and the threshold for causing inhibition in at least one postsynaptic interneuron was 10 mV of depolarization of the LDS cell. The inhibitory pathway between the LDS interneuron and the postsynaptic neurons is stable (Figs. 8, 9). 7. The LDS interneurons mediate lateral inhibition that is both nonrecurrent and reciprocal. Because the LDS interneurons are nonspiking, once above threshold they deliver a precise but inverted copy of the afference on one side to the projecting interneurons on the other side. These features have many consequences, including the ability to attenuate common signals that arise from ambient water movement, and conversely to accentuate the different afference produced by laterally asymmetric signals.

Type of Medium: Electronic Resource

URL: http://dx.doi.org/10.1007/BF00623903

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Frequency coding of waterborne vibrations by abdominal mechanosensory interneurons in the crayfish,Procambarus clarkii (1986)

Plummer, Mark R. ; Tautz, Jürgen ; Wine, Jeffrey J.

Springer

Journal of comparative physiology 158 (1986), S. 751-764

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ISSN: 1432-1351

Source: Springer Online Journal Archives 1860-2000

Topics: Biology , Medicine

Notes: Summary 1. Nine identified interneurons that originate in the 6th abdominal ganglion were studied with intracellular techniques while activating the receptors presynaptic to them with coherent water vibrations of precisely controlled amplitude and frequency. Each of the interneurons showed a characteristic response to different stimulus frequencies that was consistent from animal to animal. As a first approximation, the cells were categorized as low pass, broad band, and high pass interneurons. 2. Two interneurons classified as low pass interneurons (LPIs) have low thresholds to waterborne vibrations below 100 Hz, are inhibited by stimuli above 100 Hz, and respond maximally to 30 Hz stimuli. 3. Three interneurons classified as broad band interneurons (BBIs) respond maximally to stimuli from 30–60 Hz, but also respond well to oscillations as low as 1 Hz and as high as 80 Hz. This class is heterogeneous, spanning the range between low pass and high pass interneurons. 4. Two interneurons classified as high pass interneurons (HPIs) have very high thresholds to water oscillations below 6 Hz. They respond best to 60 Hz oscillations, above which their responsiveness sharply declines, although they continue to respond weakly up to 400 Hz. 5. Two other neurons, also classified as HPIs, responded with relatively few spikes to the stimuli we used. As a result, they do not show a clear peak responsiveness to a particular stimulus frequency. 6. All of the LPIs are strongly inhibited by high frequency oscillations and at least one of the phasic HPIs is inhibited at low frequencies. High frequency inhibition of LPIs can block excitatory responses to root shock, current injection and waterborne stimuli, and is due in part to postsynaptic inhibition. 7. Although we grouped the interneurons for analytical convenience, the frequency responses of interneurons within the groups were usually sufficiently different to allow their identification as individuals. We conclude that each interneuron's properties are precise, idiosyncratic and reproducible. These cells may be used by crayfish to analyze waterborne stimuli on the basis of frequency components.

Type of Medium: Electronic Resource

URL: http://dx.doi.org/10.1007/BF01324819

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Discrimination of sensory signals from noise in the escape system of the cockroach: The role of wind acceleration (1981)

Plummer, Mark R. ; Camhi, Jeffrey M.

Springer

Journal of comparative physiology 142 (1981), S. 347-357

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ISSN: 1432-1351

Source: Springer Online Journal Archives 1860-2000

Topics: Biology , Medicine

Notes: Summary 1 Cockroaches (Periplaneta americana) that were restrained but were able to make normal walking movements were stimulated with wind puffs delivered to the cereal wind receptors. Some puffs were superimposed on a constant ‘headwind’ simulating the relative wind that the walking cockroach would experience if it were not fixed in place. Puffs were either of variable peak velocity, or of fixed peak velocity but variable acceleration. In some experiments the movement responses of one metathoracic leg were recorded; in other experiments the responses of giant interneurons were recorded. 2. The threshold wind velocity of 3 mm/s for evoking a behavioral response in slowly walking cockroaches (Camhi and Nolen 1981) was still effective even in the presence of an 80 mm/s headwind. Measurements of the background wind (‘noise’) near a cercus of a slowly walking cockroach in the headwind showed a mean velocity of about 80 mm/s plus periodic wind gusts of up to 30 mm/s produced by the stepping motions of the legs (Fig. 3). Although over 50% of these gusts have velocities greater than the threshold stimulus for evoking a behavior (Fig. 4A), the cockroach did not respond to these gusts. However, the maximal accelerations of these gusts were consistently less than that of the just-threshold wind puff (Fig. 4B). 3. Stimuli of high acceleration (greater than 600 mm/s2) usually evoked running. Those of intermediate acceleration (approximately 300 mm/s2) usually evoked a pause in walking. The lower the acceleration, the greater the incidence of no response (Fig. 7A). This discrimination of wind acceleration was generally the same even when the stimuli were superimposed on the headwind (Fig. 7B). The discrimination of acceleration was also independent of the direction of the wind stimuli (Fig. 7C, D). 4. The wind made by the strike of a natural predator, the toadBufo marinus (known to be the cue by which cockroaches detect and respond to the toad; Camhi et al. 1978) produces a sufficiently high wind acceleration, sufficiently early, to account for the cockroach's running response to the wind made by the strike. 5. In electrical recordings from a single connective of the ventral nerve cord, it was possible to identify the action potentials from the group of three largest giant interneurons, No.'s 1, 2, and 3, which may mediate the initiation of escape behavior (Camhi and Nolen 1981). The number and frequency of action potentials in these neurons were greater for wind stimuli of higher acceleration, even though the peak wind velocity of all stimuli was the same (Fig. 10). 6. The results indicate that wind acceleration is a crucial cue by which the cockroach escape system discriminates wind signals, including the wind from the strike of a predator, from background noise, including that produced by the animal's own walking.

Type of Medium: Electronic Resource

URL: http://dx.doi.org/10.1007/BF00605447

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