The central projections of mesothoracic sensory neurons in wild-type Drosophila and bithorax mutants

Sensory axons entering the CNS from large campaniform sensilla on the normal, mesothoracic wings of four-winged flies of the genotype $\text{bx}{}^3\text{pbx}\text{Ubx}{}^{130}$ follow the same two tracts as do the corresponding axons in wild-type flies. However, they produce more branches along the ventromedial tract (including some in the mesothoracic neuromere), more fibers crossing the midline in the metathorax, and several other modifications of the wild-type pattern. No morphological differences between the receptors in normal and mutant flies could be detected, even with the SEM. The extra branching and other altered characteristics are present in bithorax flies which are also genetically wingless and do not form the homeotic appendages, so they appear to be due to the $\text{bx}{}^3\text{pbx}\text{Ubx}{}^{130}$ or $\text{bx}{}^3\text{Ubx}{}^{130}$ genotype and not to some effect of the axons from the homeotic wings.     

Subcellular sites of enzymes catalyzing the phosphorylation-dephosphorylation of dolichol in the central nervous system

The subcellular locations of several enzymes involved in dolichyl monophosphate (Dol-P) metabolism in brain have been investigated. Dolichol kinase is highly enriched in a heavy microsomal fraction from calf brain, while 71% of the Dol-P phosphatase activity was recovered with the light microsomes. Lower amounts of the phosphatase activity were also found in the heavy microsomal, mitochondrial-lysosomal, and synaptic plasma membrane fractions. Since the light microsomal fraction also contained substantial acetylcholinesterase activity, an axon plasma membrane marker, an axolemma-enriched fraction, was prepared from rat brain by a second procedure. A comparison with microsomal and mitochondrial-lysosomal fractions revealed that the axolemma-enriched fraction contained the highest specific activity of Dol-P phosphatase, indicating that the enzyme was present in the axon plasma membrane. The tunicamycin-sensitive UDP-N-acetylglucosamine:Dol-P N- acetylglucosaminylphosphotransferase , glucosyl- phosphoryldolichol (Glc-P-Dol) synthase, Glc-P-Dol:oligosaccharide glucosyltransferase, and the oligosaccharyltransferase were all found predominantly in the heavy microsomes. These results indicate that the enzymes responsible for the initiation and termination of biosynthesis, as well as the transfer of dolichol-linked oligosaccharides, reside in the rough endoplasmic reticulum (ER) of central nervous tissue. Evidence that at least some Dol-P molecules formed by dolichol kinase are accessible to multiple glycosyltransferases in the rough ER of brain is also presented.     

Development and regulation of substance P in sensory neurons in vitro

Substance P (SP), the putative neuropeptide mediator of pain sensation, is contained in small dorsomedial sensory neurons of the dorsal root ganglion. Using different culture techniques and a sensitive radioimmunoassay for SP, we studied the ontogeny and regulation of this functionally important neurotransmitter in these neurons, obtained from neonatal rats. In ganglion explants grown by two different techniques, SP increased two- to threefold during the first week in culture. This rise was predominantly due to mechanisms intrinsic to the ganglion since it occurred in a fully defined medium, in the absence of added nerve growth factor (NGF). Blockade of protein synthesis with cycloheximide prevented the increase in SP suggesting that ongoing protein synthesis was necessary. Furthermore, depolarization with veratridine blocked the increase in SP, an effect which was reversed by tetrodotoxin, suggesting that transmitter characteristics in sensory neurons may be regulated by depolarization and/or transmembrane sodium flux. After a week in culture on a collagen substratum, supplementary NGF was necessary for the continued rise in SP. However, raising the dose of the trophic factor had no incremental effect on SP content, suggesting that NGF was acting primarily on neuronal survival. To approach such questions at the cellular level, ganglia were dissociated and grown in cell culture. In all cultures, SP increased 1.5-fold during the first day. In the absence of NGF, however, SP and cell numbers fell progressively after the second day. NGF elicited parallel increases in cell survival and SP content, supporting the suggestion that NGF acts primarily through neuronal survival to increase SP. Veratridine blocked the increase in SP in a tetrodotoxin-reversible manner, without affecting neuronal survival, indicating that the effects of these agents do not depend on normal ganglionic cellular architecture. Consequently, depolarization probably affects ganglionic sensory neurons directly. Our studies suggest that the development of transmitter characteristics in primary sensory neurons may be regulated by multiple factors, including neuronal activity as well as trophic agents such as NGF.     

A cell surface marker for neural crest and placodal cells: further evolution in peripheral and central nervous system

The recent production of a monoclonal antibody (NC-1) recognizing migrating avian neural crest (NC) cells (M. Vincent, J. L. Duband , and J. P. Thiery , Dev. Brain Res. 9, 235-238, 1983) allowed us to detail their migration pathways at the trunk level of the chick embryo. Three routes can be recognized: NC cells facing the bulk of the somite accumulate to form a spinal ganglion, those facing the intersomitic space can readily reach periaortic areas to contribute to the primary sympathetic chain, and cells at intermediate levels between these two accumulate between the neural tube and the somite but some of them can escape between the sclerotome and the myotome and settle near the aorta. Histological and in vitro immunofluorescence patterns have demonstrated that the NC-1 antigen is a neuroectodermal feature. In addition to its presence on the great majority of NC cells, it persists at the surface of both neuronal and satellite cells of the peripheral ganglia. Moreover, it can be detected on neurogenic placodes and their derivatives. The appearance of the NC-1 antigen in the central nervous system coincides with the first noticeable morphological changes of the neutral tube and develops according to a rostro-caudal gradient which parallels its development: it seems, however, to be transiently expressed by the neuron cell bodies and to concentrate later on their processes. It is also present on non-neuronal cells derived from the neuroectoderm. The neuroectodermal character of NC-1 reactivity is further emphasized by its disappearance from the melanocytes and the mesectodermal derivatives of the NC. The loss by the latter, in ventral areas of the head, of the NC-1 epitope is discussed in relation to previous findings on the degree of commitment of the cephalic NC. The NC-1 epitope is associated with several high-molecular-weight polypeptides and may involve a carbohydrate moiety.     

Determination of content and specific activity of amino acids in central nervous system tissue utilizing tritium and carbon-14 dual labeling

A method is reported for measuring content and specific activity of amino acids in central nervous system tissue of the rat. Tritiated dinitrofluorobenzene is used to produce dinitro-[³H]phenyl amino acid derivatives which are separated by two-dimensional thin-layer chromatography on silica gel. Both content and specific activity can be determined simultaneously by pulse-labeling with an appropriate ¹⁴C precursor and measuring radioactivity in the individual spots of dinitrophenyl amino acids scraped from the chromatogram. This method is sensitive to at least 100 pmol and is shown to be more rapid than previously described procedures.     

Consequences of neural tube and notochord excision on the development of the peripheral nervous system in the chick embryo

Notochordectomy and neuralectomy were carried out either in one- or in two-step experiments on the chick embryo. The aim of this operation was to study the influence of the axial organs (notochord and neural tube) on the development of the ganglia of the peripheral nervous system. The neural crest cells from which most peripheral ganglion cells arise were labeled through the quail-chick marker system and their fate was followed under various experimental conditions. It appeared that the development of the dorsal root and sympathetic ganglia depends on survival and differentiation of somite-derived structures. In the absence of neural tube and notochord, somitic cells die rapidly, and so do the neural crest cells that are present in the somitic mesenchyme at that time. In contrast, those crest cells which can reach the mesenchymal wall of the aorta, the suprarenal glands, or the gut survive and develop normally into nerve and paraganglion cells. Differentiation of the neural crest- and placode-derived sensory ganglia of the head which develop in the cephalic mesenchyme is not affected by removal of notochord and encephalic vesicles. These results show that the peripheral ganglia are differentially sensitive to the presence of the neural tube and the notochord. Among the various ganglia of the peripheral nervous system, spinal and sympathetic ganglia are the only ones which require the presence of these axial structures. The neural tube allows both the spinal and the sympathetic ganglia to develop in the absence of the notochord. In contrast, if the notochord is left in situ and the neural tube removed, the spinal ganglia fail to differentiate and only sympathetic ganglia can develop.     

The effects of dietary selenium on the biotransformation of 7,21-dimethylbenz[a]anthracene

The influence of dietary selenium on the mutagenic activation of 7,12-dimethylbenz[a]anthracene (DMBA) by rat liver S9 was studied using the Ames test. Rats received supplemental selenium, as sodium selenite, in the drinking water or in the diet. All rats additionally received 0, 20, 50, 100, or 500 mg Aroclor 1254 per kg body weight. Revertant counts decreased 72 and 31% at the 20- and 100-mg/kg induction levels, respectively, with S9 preparations from rats given selenium supplementation, compared to controls. No significant effects of selenium on S9 preparations was observed in rats treated with 500 mg/kg Aroclor. Preparations of S9 from rats receiving 2.5 ppm Se in their diet produced 46, 84 and 70% less revertants than controls at the 20-, 50- and 100-mg/kg induction levels. Increasing the selenium concentration in the diet to 5 ppm reduced the revertant counts by 71, 68 and 65%, at the 20-, 50- and 100-mg/kg induction level of Aroclor, respectively. Dietary selenium supplementation was shown to decrease the mutagenic activation of DMBA by liver microsomes. These studies indicate that in vivo selenium supplementation may reduce susceptibility to the action of various carcinogens.     

The early development of cranial sensory ganglia and the potentialities of their component cells studied in quail-chick chimeras

The quail-chick marker system has been used to study the early developmental stages of the ganglia located along cranial nerves VII, IX, and X. The streams of neural crest cells arising from the rhombencephalic-vagal neural crest were followed from the onset of their migration up to the localization of crest cells in the trunk and root ganglia of these nerves. It was shown that two different populations of crest cells are segregated early as a result of morphogenetic movements in the hypobranchial region. The dorsal population gives rise to the root ganglia of nerves IX and X located close to the encephalic vesicles, where the crest cells differentiate both into neurons and into glia. In contrast, the ventral stream of neural crest cells contributes together with cells from epibranchial placodes to the trunk ganglia (geniculate, petrous, and nodose ganglia) of cranial nerves VII, IX, and X. The successive steps of the invasion of the placodal anlage by crest cells can be followed owing to the selective labeling of the neural crest cells. It appears that the latter give rise to the satellite cells of the geniculate, petrous, and nodose ganglia while the large sensory neurons originate from the placodes. The nodose ganglion has been the subject of further studies aimed to investigate whether neuronal potentialities can be elicited in the neural crest-derived cells that it contains. The ability to label selectively either the neurons or the glia by the quail nuclear marker made this investigation possible in the particular case of the nodose ganglion whose neurons and satellite cells have a different embryonic origin. By the technique already described (N. M. Le Douarin, M. A. Teillet, C. Ziller, and J. Smith, 1978, Proc. Nat. Acad. Sci. USA75, 2030–2034) of back-transplantation into the neural crest migration pathway of a younger host, it was shown that the presumptive glial cells of the nodose ganglion are able to remigrate when transplanted into a 2-day chick host and to differentiate into autonomic structures (sympathetic ganglion cells, adrenomedullary cells, and enteric ganglia). It is proposed as a working hypothesis that neuronal potentialities contained in the neural crest cells which invade the placodal primordium of the nodose ganglion are repressed through cell-cell interactions occurring between placodal and crest cells.     

Quantitative in vitro studies on the nerve growth factor (NGF) requirement of neurons: I. Sympathetic neurons

Quantitative studies on the nerve growth factor (NGF) requirement of chick embryo sympathetic neurons in dissociated cell culture revealed the following. (i) The minimum concentration of 2.5 S NGF required for survival of maximal numbers of neurons is about 0.5 ng/ml (～2 × 10^?11M). In culture, this concentration of NGF appears not to be stable for more than 24 hr. Long-term neuronal maintenance with medium changes twice weekly requires a minimum of 5 ng/ml of NGF. (ii) At 24 hr after plating in medium containing 10% fetal bovine serum, neuronal survival is less than optimal at NGF concentrations above 5 ng/ml; in medium with 5% horse serum, survival is constant with up to 5000 ng/ml of NGF. (iii) Survival of neurons after 1 week in culture was less than optimal at NGF concentrations greater than 50 ng/ml, even in medium containing horse serum. (iv) No correlation was observed between the level of NGF (0.5–500 ng/ml) and the estimated neuronal somatic volumes up to 1 month in vitro. (v) Withdrawal of NGF, even after 4 weeks of culture, resulted in degeneration of nerve cell bodies and processes.     

The effects of cadmium and copper on the renal uptake and metallothionein binding of gold in the rat and hamster

Rats and hamsters, (pre)-treated with copper and cadmium, were used to investigate whether species-differences in renal metallothionein synthesis in response to gold were determined by changes in the kidney concentrations of other metals. The effects of both dietary copper limitation and excess on the renal metabolism of gold also were studied in the rat. In this species, all of the pre-treatments affected the renal concentrations of total and metallothionein-bound copper, but none of them altered either the kidney uptake or thionein-binding of gold. Incorporation of zinc into the metallothionein, which accompanied the binding of gold in this fraction of the kidney, however, was influenced slightly by the pretreatments. In hamsters, pretreatment with cadmium, which increased the concentrations of total and thionein-bound zinc in the kidneys, also did not affect the renal uptake of gold, although it increased significantly the binding of gold to the metallothionein fraction of the renal cytosol. This increased binding of gold also was accompanied by further increases in the zinc and copper contents of the metallothionein; the contents of total and thionein-bound cadmium, however, remained essentially unchanged. Concentrations of copper and zinc in the hamster kidney were not affected significantly by subcutaneous administration of copper alone (five daily doses, each of 3.2 mg Cu/kg body wt.), but were increased when gold was given during the copper-treatment. The concentrations of gold, copper and zinc in the renal metallothionein fraction also were increased under these conditions. From these results it seems that kidney metallothionein synthesis in response to gold may be related to the changes in either the concentration or distribution of zinc, rather than copper.     

The deacylation of acyl-cycloamyloses : The catalytic effects of benzimidazole derivatives on the rate

Cycloheptaamylose cinnamate, an intermediate in the hydrolysis of m-nitrophenyl cinnamate by cycloheptaamylose, was isolated in pure form. The deacylation of acyl-cycloamyloses (cinnamate and acetate) catalyzed by noncovalently complexed 6-nitrobenzimidazole (1) was studied. The reaction was enzyme-like. Saturation of acyl-cycloamylose by 1 was observed; the rate and dissociation constants were determined from Lineweaver-Burk plots. The catalyzed reaction rates at neutral pH were two to three times larger than those of the spontaneous reactions for cycloheptaamylose or cyclohexaamylose cinnamate, respectively. The catalytic effect of 1 on the deacylation rate of cyclohexaamylose cinnamate became smaller as the pH of the solution was raised. The deacylation of cyclohexaamylose acetate was followed by nmr spectroscopy, whereas the deacylation of cycloamylose cinnamates was followed by uv spectroscopy and extraction of trans-cinnamic acid with ether. Thermodynamic parameters for the rates of deacylation of cycloamylose cinnamates and dissociation constants of cycloamylose cinnamate-1 complexes were obtained and discussed.     

The effects of iodination on the receptor binding affinity of ovine prolactin

A completely iodinated form of ovine prolactin was prepared using lactoperoxidase. The iodination was characterized using gel filtration, electrophoresis and fluorescence analysis. Complete iodination corresponds to a 33% decrease in intrinsic tryptophanyl fluorescence (275348). Each ovine prolactin molecule possesses four iodination sites which cannot be distinguished by kinetic analysis. The receptor binding capacity of the tetraiodoprolactin was also assayed using the particulate fraction from female rat livers. Although the total binding capacity of native and iodoprolactins is indistinguishable, significant differences in receptor binding behavior were observed.     

The effects of insulin and tunicamycin on insulin receptors of cultured fibroblasts

The effect of down-regulation on the intracellular pool of insulin receptors and the role of glycosylation in recovery from down-regulation have been studied in fibroblastic cultures from the skin of non-diabetic mice. In control cultures, 55% of the total specific [¹²⁵I]insulin-binding activity was in the intracellular compartment. Insulin caused a time- and concentration-dependent decrease in the number of cell surface insulin receptors, with no significant change in total insulin receptors. This decrease in surface receptors was accompanied by an increase in the specific binding of [¹²⁵I]insulin in the intracellular compartment. Removal of insulin from down-regulated cells resulted in a time-dependent increase in the binding of [¹²⁵I]insulin to surface receptors, reaching 90% of that in controls by 12 h. The recovery of surface insulin receptors after removal of insulin was blocked by incubation of cultures with tunicamycin, but not by cycloheximide. These results indicate that down-regulation of surface insulin receptors by insulin is associated with translocation of receptors into the intracellular pool and suggest that protein glycosylation is important in insulin receptor recycling and externalization.     

A physical and genetic map of the IncFI plasmid ColV2-K94

A restriction enzyme map of the IncFI plasmid ColV2-K94 was generated using EcoRI, BamHI, HindIII, and XhoI; the genetic features of this element were then mapped from previous heteroduplex studies.     

The role of coenzyme Q10 for preservation of the rat kidney: a model experiment for kidney transplantation.

In an experimental model system for kidney transplantation, the ability of the rat kidney to resynthesize ATP after warm ischemic time and subsequent restoration of renal blood flow was found to determine tissue viability and survival of the animal. The administration of CoQ₁₀ prior to warm ischemia enhanced the rate and extent of ATP resynthesis by reflow following two-hour warm ischemia and this was accompanied by an increase in survival rate of the rats.     

The effects of cell proliferation on the lipid composition and fluidity of hepatocyte plasma membranes.

The fluorescence probe, 1,6-diphenyl-1,3,5-hexatriene, has been used to investigate the effects of controlled and uncontrolled growth on the dynamic properties of the lipid regions of hepatocyte plasma membranes. DPH was incubated with plasma membranes derived from quiescent and regenerating liver and Morris hepatoma 7777, and the resulting systems were studied by fluorescence polarization spectroscopy. Membranes from the rapidly growing hepatoma exhibited a significantly lower fluorescence polarization than observed in quiescent liver, suggesting the presence of a more fluid membrane lipid domain. Membranes from regenerating liver exhibited a time-dependent increase in membrane fluidity, reaching a maximum 12 h after growth stimulation. A close correspondence between membrane fluidity and the cholesterol-phospholipid ratio was also observed where a decrease in this ratio resulted in a more fluid lipid matrix. These results suggest that cell cycling, as observed in regenerating liver and Morris hepatoma 7777, results in significant increases in membrane fluidity, a property which may play an important regulatory role in various cell functions.     

Effects of high K+ concentrations on the growth and development of ciliary ganglion neurons in cell culture

Extracts prepared from embryonic eye tissue permit all of the neurons present in embryonic ciliary ganglia to survive and develop in cell culture. High K⁺ concentrations stimulate growth of the neurons in culture above the maximal levels obtained with eye extract alone. Growth in 25 mM K⁺ produced parallel increases in the levels of choline acetyltransferase activity, lactate dehydrogenase activity (a common cytoplasmic enzyme), and total protein synthesis per neuron. The K⁺ effect appears to be mediated by membrane depolarization. Intracellular recording confirmed that the neurons were chronically depolarized in 25 mM K⁺. Veratridine produced the same stimulation of growth, while tetrodotoxin blocked the veratridine effect without preventing the K⁺ effect. Ca²⁺ may also play a role in the K⁺ effect. Two drugs thought to block Ca²⁺ channels (Mg²⁺ and D600) each blocked or reduced in the increase in growth caused by 25 mM K⁺. The drugs did not interfere with neuronal growth in control cultures, indicating that eye extract and membrane depolarization influence neuronal growth by different mechanisms.     

The effects of interferon on epidermal growth factor action

Epidermal growth factor-stimulated thymidine incorporation in human fibroblasts is inhibited more than 80% by human interferon, whereas the stimulation of α-aminoisobutyrate uptake is unaffected. Maximum inhibition of thymidine incorporation is observed after treatment of cells with interferon prior to the onset of DNA synthesis. However, even after the initiation of DNA synthesis, interferon rapidly blocks any further increase in thymidine incorporation. Despite these effects, interferon treatment causes no alterations in epidermal growth factor binding, receptor downregulation or receptor reappearance.