Epidermal receptor development and sensory pathways in vitally stained amphioxus (Branchiostoma floridae)

Chloromethyl (CM) DiI was applied to the exterior of living embryos, larvae, and metamorphic juveniles of amphioxus. This fluorescent dye is taken up preferentially (but not highly selectively) by epidermal receptors and often stains sensory axons to their full extent. Type I primary receptors in the epidermis first become morphologically detectable along the rostrocaudal axis of the 2.5 day larva when their epidermal perikarya extend unbranched axons to the nerve cord. These axons run posteriorly or anteriorly within the nerve cord, depending on whether their perikarya are located, respectively, rostral or caudal to the most posterior pharyngeal slit. In later larvae, axons of type I receptors are organized into a dorsal and a subdorsal sensory tract on either side of the nerve cord. In the epidermis of metamorphic juveniles, CM-DiI also stains type II receptors (which are axonless, secondary receptors) and ventral pit cells (which may not be receptors). It is probable, but not yet conclusively demonstrated, that peripheral neurites from Retzius bipolar cells (primary intramedullary sensory neurones) synapse with type II secondary epidermal receptors or ramify freely among the other epidermal cells. The discussion considers homologies among epidermal sensory receptors in chordates.     

Altered glial function causes neuronal death and increases neuronal susceptibility to 1-methyl-4-phenylpyridinium- and 6-hydroxydopamine-induced toxicity in astrocytic/ventral mesencephalic co-cultures

Altered glial function in the substantia nigra in Parkinson's disease may lead to the release of toxic substances that cause dopaminergic cell death or increase neuronal vulnerability to neurotoxins. To investigate this concept, we examined the effects of subjecting astrocytes to lipopolysaccharide (LPS)-induced activation alone or combined with L-buthionine-[S,R]-sulfoximine-induced glutathione depletion or inhibition of complex I activity by 1-methyl-4-phenylpyridinium (MPP+) on the viability of primary ventral mesencephalic neurones or susceptibility to MPP+ and 6-hydroxydopamine (6-OHDA) in co-cultures. LPS-activated astrocytes caused neuronal death in a time-dependent manner, but glutathione-depleted or complex I-inhibited astrocytes had no effect on neuronal viability. The neurotoxicity of LPS-activated astrocytes was inhibited by the inducible nitric oxide synthase inhibitor aminoguanidine, by the nitric oxide scavenger 2-(4-carboxyphenyl)-4,4,5,5-tetramethylimidazoline-1-oxyl-3-oxide, and by reduced glutathione (GSH). MPP+-induced neuronal death was greater in ventral mesencephalic cultures previously cultured with LPS-activated, glutathione-depleted, or complex I-inhibited astrocytes compared with co-cultures containing normal astrocytes. The increased neuronal susceptibility to MPP+ caused by LPS-activated or complex I-inhibited astrocytes and glutathione-depleted astrocytes was inhibited by the NMDA/glutamate antagonist MK-801 and by GSH, respectively. Neuronal death caused by 6-OHDA was increased in ventral mesencephalic cultures previously cultured with LPS-activated and glutathione-depleted, but not complex I-inhibited astrocytes, compared with co-cultures containing normal astrocytes. Treatment of co-cultures with GSH prevented the increased neuronal susceptibility to 6-OHDA. These findings suggest that glial dysfunction may cause neuronal death or render neurones susceptible to toxic insults via a mechanism involving the release of free radicals and glutamate. Such a mechanism may play a role in the development or progression of nigrostriatal degeneration in Parkinson's disease.     

Encoding of plant odour information in insects: peripheral and central mechanisms

Insects are suitable model organisms for studying mechanisms underlying olfactory coding and olfactory learning, by their unique adaptation to host plants in which the chemical senses are essential. Recent molecular biological studies have shown that a large number of genes in insects and other organisms are coding for olfactory receptor proteins. In general, one receptor type seems to be expressed in each neurone. The functional characterisations of olfactory receptor neurones have been extensive in certain insect species, demonstrating a fine-tuning of single neurones to biologically relevant odourants; both insect and plant produced volatiles. Stained neurones of the same functional type have been shown to project in one and the same glomerular unit in the primary olfactory centre, the antennal lobe. This corresponds to molecular biological studies, showing projections in one glomerulus by neurones expressing the same receptor type. Comparison of these findings with physiological and morphological characterisations of antennal lobe neurones has indicated correspondence between input and output of the glomerular units. Examples are presented from studies of heliothine moths. From the antennal lobe, the olfactory information is further conveyed to the mushroom bodies, particularly important for learning, and the lateral protocerebrum, a premotoric area. The three brain areas are regions of synaptic plasticity important in learning of odours, which is well studied in the honeybee but also in species of moths.     

In vivo effects of adenosine A(2) receptor agonist and antagonist on neuronal and astrocytic intermediary metabolism studied with ex vivo (13)C MR spectroscopy.

The effect of adenosine A(2) receptor agonist 2-[p-(2-carboxyethyl)phenylethylamino]-5'-ethylcarboxamidoadenosine (CGS 21680) and antagonist 3,7-dimethyl-1-propargylxanthine (DMPX) on [1-(13)C]glucose and [1,2-(13)C]acetate metabolism was studied in rats by (13)C magnetic resonance (MR) spectroscopy and HPLC. In the cortex a significant reduction was observed in the amounts of [2-(13)C]GABA and [3-(13)C]aspartate from [1-(13)C]glucose in CGS 21680. In the subcortex the concentration of labelled [4-(13)C]glutamate was increased in both treatment groups. The amounts of [2 + 3-(13)C]succinate and [3-(13)C]lactate were increased in the CGS 21680 group compared to control, and the DMPX group showed an increase in the total amount of [6-(13)C]N-acetyl aspartate compared to control in the subcortex. Astrocyte metabolism was only affected in the cortex as shown by a decrease in the pyruvate carboxylase/pyruvate dehydrogenase ratio in glutamate and glutamine in the treatment groups. Labelling from [1,2-(13)C]acetate was not much affected by CGS 21680 or DMPX. However, the amount of [1,2-(13)C]acetate in cortex and subcortex was reduced in the DMPX group. In the cortex a reduction in the labelling of [3-(13)C]GABA in the DMPX group compared to control and an increase in the total amount of taurine in both treatment groups was detected. The present study shows that A(2) receptor agonist and antagonist have similar effects; however, in cortex GABAergic neurones and astrocytes were affected in contrast to subcortex, where glutamatergic neurones showed the greatest changes.     

GRP neurones in the rat small intestine issue long anal projections

Gastrin releasing peptide (GRP) immunoreactive nerve fibres are numerous in the gut wall. Nerve cell bodies containing GRP are regularly found in the myenteric ganglia. The projections of GRP neurones in the rat small intestine were studied after myectomy or transection of the gut wall. Operated rats were left for 8–10 days or 5 weeks. Specimens were studied by immunocytochemistry, immunochemistry and in vitro for motor activity. GRP fibres were absent and GRP was markedly reduced in the gut wall underlying the area of myectomy and 10 mm anally to the myectomy or site of transection. Further anally, GRP and the GRP fibres gradually returned and were back to normal 25–30 mm from the lesion. Myenteric GRP neurones in the rat small intestine thus project anally over a distance of approximately 20–25 mm. A series of experiments was performed in order to test the idea that GRP is directly involved in intestinal motor functions. The results did not support this view. Strips of longitudinal smooth muscle with adherent myenteric ganglia were taken orally and anally to the myectomy and the motor activity of the specimens was compared. Electrical stimulation evoked a contractile response in the oral segment that was 6 times greater than that of the anal segment. However, GRP (10^?9–10^?5 M) did not evoke contraction and the electrically induced contractile response was unaffected by GRP but could be blocked by atropine. The reduced contractile response in the ‘denervated’ anal segment is thus probably not due to a shortage of GRP fibres.     

In vivo knockdown of ckit impairs neuronal migration and axonal extension in the cerebral cortex

The tyrosine kinase receptor cKit and its ligand stem cell factor (SCF) are well known mediators in proliferation, survival, and positive chemotaxis of different cell types in the hematopoietic system. However, and in spite of previous reports showing robust expression of cKit and SCF in the brain during development, their possible function in the cerebral cortex has not been clarified. In this study, embryonic knockdown expression of cKit in the rat cortex by in utero electroporation of specific RNAi resulted in delayed radial migration of cortical neurons. In conditional Nestin‐cKit KO homozygous mutants, radial migration in the cortex was also delayed. The opposite phenotype was observed after overexpressing cKit in the cortex: radial migration was accelerated. Callosal fibers electroporated with cKit RNAi were also delayed in their extension within the contralateral cortex and eventually failed to innervate their target area. In vitro experiments showed that, whereas SCF was able to promote migration of cortical neurons, it had no effect on cortical neurite outgrowth. In summary, our results demonstrate that (1) cKit is necessary for radial migration of cortical neurons, probably through SCF binding and (2) cKit is necessary for the correct formation of the callosal projection, most likely by a mechanism not involving SCF. © 2013 Wiley Periodicals, Inc. Develop Neurobiol 73: 871–887, 2013     

Non-spiking local interneurones mediate abdominal extension related descending control of uropod motor neurones in the crayfish terminal abdominal ganglion

The role of non-spiking local interneurones in the synaptic interactions between abdominal extension-evoking descending interneurones and uropod motor neurones in the terminal abdominal ganglion of the crayfish Procambarus clarkii (Girard) was investigated electrophysiologically. Continuous electrical stimulation of the lateral region of the 3rd-4th abdominal connective that included abdominal extension evoking interneurones excited the opener motor neurones and inhibited the closer, reductor motor neurone. Spikes from a single descending interneurone evoked consistent and short latency (0.8–0.9 ms) excitatory postsynaptic potentials (e.p.s.ps) in the opener motor neurones, and evoked rather long-latency (1.5–2.7 ms) inhibitory postsynaptic potentials (i.p.s.ps) in the reductor motor neurone. Many non-spiking interneurones also received depolarizing p.s.ps (0.8–2.5 ms in latency) that were usually faster than i.p.s.ps of the reductor motor neurone if both neurones were recorded sequentially in the same preparation. Non-spiking interneurones received convergent inputs from several descending interneurones and made inverting connection with the reductor motor neurone. Elimination of descending inputs to a particular non-spiking interneurone could reduce the inhibitory response of the reductor motor neurone. These observations strongly suggested that descending inhibitory inputs to the closer, reductor motor neurone were mediated by non-spiking interneurones. Furthermore, some non-spiking interneurones made output connections with the opener motor neurones. The disynaptic pathway through non-spiking interneurones is significant to control and modulate the opening pattern of the uropod during abdominal extension. Accepted: 27 December 1996     

Cell behaviour on micropatterned surfaces

The local microenvironment of tissue cells has a profound influence on cell behaviour such as cell shape, guidance of movement, and so on. One approach to understanding this phenomenon, which is being applied by a number of groups, is to model possible cues using microfabrication technology. Such techniques have been used to examine the behaviour of a number of cell types. The responses of fibroblasts, epithelial cells and neurones have been determined on a variety of micropatterned surfaces. Conventional photolithographic techniques and laser holography have been employed to define topographic patterns with feature sizes ranging from 25 μm to 130 nm. Photolithography, combined with silanization of glass, has been used to chemically pattern surfaces; this results in differentially adhesive surfaces that mimic possible in vivo cues. The determination of the response of various cell types to these various surfaces has provided detailed information on the biological mechanisms controlling cell behaviour, and on aspects of tissue responses to implanted artificial devices; it has also illustrated the potential for technology utilizing immobilized cellular patterns.     

Isolation and Characterization of Secretory Granules Storing a Vasoactive Intestinal Polypeptide-Like Peptide in Torpedo Cholinergic Electromotor Neurones

Previous immunocytochemical work showed that the cholinergic electromotor neurones of Torpedo marmorata contain a vasoactive intestinal polypeptide-like immunoreactivity (VIPLI) that is conveyed to the terminals by axonal transport from the cell bodies where it is presumably synthesized. In extension of this work, we have now succeeded in isolating the VIPLI storage granules from both the terminals and the axons of these neurones and characterizing them morphologically and biochemically. They were readily separated from synaptic vesicles but contained several components in common that had previously been regarded as specific for synaptic vesicles. Among these were a heparan sulphate type of proteoglycan, synaptophysin, and a Mg2+-dependent ATPase. The VIPLI concentration in lobe tissue and the amount of tissue available were both insufficient to permit the isolation of granules from the electromotor cell bodies by the same technique but it was possible to establish the presence of such granules by particle-exclusion chromatography, using the stable markers mentioned above. In contrast to the VIPLI-containing granules, axonal synaptic vesicles differed from their terminal counterparts in having a very low acetylcholine content relative to stable vesicle markers: they presumably fill up on reaching the terminal where they are exposed to higher concentrations of cytoplasmic acetylcholine.