ALBERT — All Library Books, journals and Electronic Records Telegrafenberg

1

Electronic Resource

Embryonic development of identified neurones: differentiation from neuroblast to neurone (1979)

Goodman, Corey S. ; Spitzer, Nicholas C.

[s.l.] : Nature Publishing Group

Nature 280 (1979), S. 208-214

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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] Individually identified neurones are sufficiently large and accessible in grasshopper embryos to permit visualisation and impalement with intracellular microelectrodes from the time of their birth to their maturation. In this article part of the temporal pattern of differentiation from an ...

Type of Medium: Electronic Resource

URL: http://dx.doi.org/10.1038/280208a0

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2

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Control of neuronal fate by the Drosophila segmentation gene even-skipped (1988)

Doe, Chris Q. ; Smouse, David ; Goodman, Corey S.

[s.l.] : Nature Publishing Group

Nature 333 (1988), S. 376-378

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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] In insects, neurogenesis begins with two steps. Initially, cell interactions control the differentiation of a segmentally reproducible pattern of neuronal stem cells (called neuroblasts) from a morphologically uniform sheet of neuroectodermal cells4"7. The second step involves the generation of a ...

Type of Medium: Electronic Resource

URL: http://dx.doi.org/10.1038/333376a0

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3

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The effects of temperature on the threshold of identified neurons in the locust (1977)

Heitler, W. J. ; Goodman, Corey S. ; Rowell, C. H. Fraser

Springer

Journal of comparative physiology 117 (1977), S. 163-182

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ISSN: 1432-1351

Source: Springer Online Journal Archives 1860-2000

Topics: Biology , Medicine

Notes: Summary 1. At the preferred body temperature of the locust (30 °C and above), the metathoracic fast extensor of the tibia (FETi) motorneuron will sometimes spike in response to synaptic input from the descending movement detector (DMD) visual interneurons. This does not occur at lower temperatures (Fig. 1). The mechanism of the change in excitability is investigated in FETi and other identified motorneurons over the range 18–35 °C. 2. Action potentials show a reversible decrease in amplitude and duration on heating (Fig. 2). 3. EPSP amplitudes are relatively unchanged by temperature, but their duration decreases slightly on heating (Fig. 3). 4. Membrane potential hyperpolarises on heating and depolarises on cooling (Fig. 4). 5. Membrane resistance shows a transient increase on cooling, and a transient decrease on heating (Fig. 10), but there is usually little steady-state change in resistance with temperature (Fig. 5). 6. Spike threshold shows a transient increase followed by a steady-state decrease on heating, and the opposite on cooling (Fig. 10). This can be demonstrated with injected current (Fig. 6), membrane depolarisation (Fig. 7), spontaneous spike frequency (Fig. 9), and naturally occurring EPSPs (Fig. 8). This change in spike threshold is regarded as the major neural correlate of the change in excitability with temperature.

Type of Medium: Electronic Resource

URL: http://dx.doi.org/10.1007/BF00612785

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4

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Isogenic locusts and genetic variability in the effects of temperature on neuronal threshold (1977)

Goodman, Corey S. ; Heitler, W. J.

Springer

Journal of comparative physiology 117 (1977), S. 183-207

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ISSN: 1432-1351

Source: Springer Online Journal Archives 1860-2000

Topics: Biology , Medicine

Notes: Summary Physiological variability was previously encountered while studying the effects of temperature on identified motorneurons. Of 22 locusts examined from within the breeding colony, 3 deviant animals were found in which the current threshold of the fast extensor tibiae (FETi) motorneuron did not decrease as was expected with increasing temperature (Fig. 1). We have used clones of isogenic locusts to study the genetic basis, physiological extent, and behavioral effects of a similar abnormal threshold response of FETi to increases in temperature. Over 30 clones, raised by parthenogenetic breeding, were used to isolate naturally-occurring genotypic variability. In this study we have focused our attention on the behaviorally abnormal clone 7 animals that have a low probability of jumping which is not altered by heating; and the behaviorally normal clone 8 animals that have a higher probability of jumping which increases with increasing temperature (Table 1). In clone 8 animals, the physiological properties of FETi show the normal steady-state responses to increases in temperature: the current threshold decreases (Fig. 1), the voltage threshold decreases, and the membrane resistance remains relatively unchanged. In clone 7 animals, the physiological properties of FETi show abnormal steady-state responses to increases in temperature: the current threshold increases (Fig. 1), the voltage threshold remains relatively unchanged (Fig. 2), and the membrane resistance decreases (Fig. 3), all of which are similar to the abnormal responses observed occasionally from the heterogenic breeding colony. These abnormalities in FETi of clone 7 animals are regarded as a neurophysiological correlate of the absence of an increase in jumpiness with increasing temperature. An abnormal response to heating in clone 7 animals is also found in AAdC (Fig. 6), ASFlTi, and the first basalar motorneuron. A normal response to heating in clone 7 animals is found in the spiracle closer motorneurons (Fig. 7), the DUM neurons, and the CI neuron.

Type of Medium: Electronic Resource

URL: http://dx.doi.org/10.1007/BF00612786

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5

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Anatomy of the ocellar interneurons of acridid grasshoppers (1976)

Goodman, Corey S.

Springer

Cell & tissue research 175 (1976), S. 183-202

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ISSN: 1432-0878

Keywords: Ocelli ; Insect brain ; Cobalt stain ; Neuroanatomy

Source: Springer Online Journal Archives 1860-2000

Topics: Biology , Medicine

Notes: Summary The anatomy of the large ocellar interneurons in the brain of five species of acridid grasshoppers of two different subfamilies (Schistocerca vaga, S. gregaria, Gastrimargus africanus, Trimerotropis pallidipennis, and Arphia conspersa) was revealed by cobalt-filling of the three ocellar nerves and subsequent reconstructions from silver-intensified (Timm's method) serial sections. Conflicts in the literature are reviewed (Tables 1, 2) and differences in the number of cells, anatomical descriptions of these cells, and nomenclature are resolved by demonstration of an identical number of large ocellar interneurons in all five species examined (Fig. 1). There are 17 large 1st-order ocellar interneurons (Figs. 2, 3). Each of the three ocellar nerves contains the axons of seven large interneurons; four of these interneurons have axons in two ocellar nerves. The anatomy of three pairs of 2nd-order ocellar interneurons (with branches in the ocellar tracts within the brain and axons in the circum-esophageal connectives) is reconsidered in light of recent conflicts in the literature. Previous accounts by Williams (1975) of interneurons O2, O3, and PI(2):5 are corroborated and new details added (Fig. 7) by the use of a cobalt method that appears to stain these 2nd-order interneurons transsynaptically (Fig. 6).

Type of Medium: Electronic Resource

URL: http://dx.doi.org/10.1007/BF00232078

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6

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Anatomy of the ocellar interneurons of acridid grasshoppers (1976)

Goodman, Corey S. ; Williams, J. L. D.

Springer

Cell & tissue research 175 (1976), S. 203-225

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ISSN: 1432-0878

Keywords: Ocelli ; Insect brain ; Cobalt stain ; Neuroanatomy

Source: Springer Online Journal Archives 1860-2000

Topics: Biology , Medicine

Notes: Summary The anatomy of the small ocellar interneurons in the brain of the acridid grasshopper Schistocerca vaga was revealed by cobalt-filling the three ocellar nerves and subsequent reconstructions from silver-intensified (Timm's method) serial sections. In total, 61 small ocellar interneurons were repeatedly identified with arborizations in many areas of the brain and optic lobe, including in particular the posterior neuropil, ocellar tracts, protocerebral bridge, lobula, ventral bridge and tritocerebral crotch, calyces, and antenno-glomerular tracts. Each ocellar nerve contains the axons of small cells that arborize in the other two ocellar tracts; these tracts are sites of ocellar integration. Direct interactions between the ocelli and compound eyes are suggested by the projections of small ocellar interneurons into the proximal lobula. Small cell arborizations from all three ocelli are distributed across much of the protocerebral bridge, implying a role for the bridge as an ocellar neuropil within the brain. Four of the small interneurons could be seen in whole-mount preparations and are demonstrated to be identical in five species of acridid grasshoppers of two different subfamilies: Schistocerca vaga, S. gregaria, Gastrimargus africanus, Trimerotropis pallidipennis, and Arphia conspersa.

Type of Medium: Electronic Resource

URL: http://dx.doi.org/10.1007/BF00232079

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