Catecholaminergic contributions to the neuronal machinery of the olfactory bulb: aftoradiographic, immunohistochemical and evoked feild potential studies

aftographic exeperiments on the localization of radiolabelednoradrenaline, dopamine and dopa, as well as immunohistochemicalstudies on hydroxylase-like activity, are summarized and comparedin both rat and turtle olfactory bulbs. Evoked field potentialstudies on effects of dopamine are also discussed. The histochemicalstudies suggest that dopaminergic periglomerular neurons arethe most significant cellular component of the catecholaminergicsystem in the olfactory bulb of both species. Scattered fluorescentcell group was also present in the internal plexiform layerand superficial granule cell layer of the turtle olfactory bulb.Other fibres, not related to intrinsic bulbar neuronal cellbodies, were also labeled, mostly in the granule cell layerbut also in the external plexiform layer. These might belongto a centrifugal catecholaminergic system from brain stem neurons.In the in vitro turtle olfactory bulb, dopamine and apomorphinedepressed the amplitude of field potentials evoked by a singlevolley in the olfactory nerve or lateral olfactory tract, andreduced the depression and latency of reponses when paired volleywere delivered. It is suggested that catecholaminergic systemsplay a key role in modulating mitral cell activity through actionsin both superficial (glomerular) and deep (granule) layers.This may involve direct actions, or other, non-catecholaminergicinterneurons.     

Effects of urbanization on streams of the Melbourne region, Victoria, Australia. I. Benthic macroinvertebrate communities

1. Macroinvertebrate community composition was assessed in small streams of the Melbourne region to test the effects of (a) urban density (catchment imperviousness 0–51%) and (b) stormwater drainage intensity (comparing the intensively drained metropolitan area with urban areas of the hinterland, which had open drains and some localized stormwater drainage).
2. Hinterland communities separated into two groups of sites correlating strongly with patterns of electrical conductivity (EC), basalt geology and annual rainfall. Community composition varied little in the high-EC, western group (imperviousness 0.2–1.2%), but in the eastern group it was strongly correlated with catchment imperviousness (0–12%), with lower taxon richness in more impervious catchments.
3. Metropolitan communities (imperviousness 1–51%) were all severely degraded, with high abundances of a few tolerant taxa. Community composition was poorly correlated with patterns of geology, rainfall or imperviousness. Differences between metropolitan and hinterland communities were well explained by patterns of biochemical oxygen demand and electrical conductivity, which were postulated to indicate the more efficient transport of pollutants to receiving streams by the metropolitan stormwater drainage system.
4. Degradation of macroinvertebrate community composition was well explained by urban density but intensive urban drainage increased degradation severely at even low urban densities. Quantification of relationships between imperviousness, drainage intensity and stream degradation can better inform the assessment, conservation and restoration of urban streams.     

Cytoplasm-enriched fragments ofChara: structure and electrophysiology

Summary Cytoplasm-enriched fragments prepared from internodal cells ofChara corallina by centrifugation contain membrane bound vesicles ranging in size from a few m to hundreds of m. If the fragments are incubated in artificial pond water (APW) of pH₀ above 6.5, neutral red stains the inside of many vesicles bright crimson, suggesting the presence of inward proton-pumping. In APW of pH₀ below 6 crimson vesicles are found less frequently. Under such conditions most vesicles remain unstained inside and some develop indistinct pink halos. After a few days most fragments form a central vacuole, which stains red, regardless of the pH₀. The cytoplasmic layer still contains vesicles after vacuole formation.In order to identify the membrane bounding the vesicles various fluorescent probes were applied either by injection into the fragment or directly onto the vesicles released into artificial cytoplasm. Lucifer yellow or 6 COOH-F move readily across the tonoplast in intact cells, but did not enter any vesicles. On the other hand, the fluorescent cationic stain DIOC, which is used to highlight mitochondria and especially endoplasmic reticulum, stained the vesicle membrane. Numerous elliptical or kidney shaped nuclei in the flowing cytoplasm were highlighted with DAPI. In some fragments the nuclei formed large agreggates sometimes filling the width of the fragment.Patch-clamping the vesicles in artificial cytoplasm showed the presence of several kinds of channels, some displaying similar behaviour to the K⁺ channels observed in cytoplasmic droplets.Analogous to the plasmalemma of intact cells, the fragments without vacuoles displayed electrophysiological states dominated by either K⁺ conduction, H⁺ (or OH^–) conduction or the proton pump. On the other hand, excitation transients in fragments were of low amplitude or absent altogether. Detailed comparisons of data from fragments and intact cells are shown. The effect of vacuole formation on fragment electrophysiology was also explored.     

numb, a gene required in determination of cell fate during sensory organ formation in Drosophila embryos

Neurons and support cells of each sensory organ in Drosophila embryos are most likely derived from a single precursor cell. This cell lineage is affected in numb mutants. Morphological alterations of sensory structures, as well as changes in the number of cells expressing cell type-specific markers, indicate that sensory neurons in numb mutant embryos are transformed into lineage-related nonneuronal support cells. Thus the numb gene controls the fate of progeny derived from sensory organ precursors. The numb gene has been isolated by the plasmid rescue method. The structure of its predicted product is discussed.