Ontogeny of Glucose Metabolism in Sympathetic Ganglia of Chickens. Concurrence of Maximum Rates in the Hexosemonophosphate Shunt and in Synthesis of Lipids but Not of Ribonucleic Acid

Chains of sympathetic ganglia were excised from the lumbar region of white Leghorn chicken embryos, 8-19 days of age, and incubated, usually for 5 h, at 36 degrees C in a bicarbonate-buffered physiological salt solution containing [U-14C]glucose, [1-14C]glucose, [6-14C]glucose, or [5-3H]uridine. Lipid synthesis was measured by the incorporation of 14C into lipids, and RNA synthesis by the accumulation of 3H into macromolecules. The ratio of 14C put out in CO2 during the second hour of incubation in the presence of [1-14C]glucose to that with [6-14C]glucose was used as an index of activity in the hexosemonophosphate shunt (HMS). Both the rate of lipid synthesis and activity in the HMS reached well-defined maxima at about 11 days of embryonic age. There was no evidence of a similar rise and fall of RNA synthesis during the ages studied. Estimates of the rate of NADPH production by the HMS at near-peak lipid synthesis varied over a twofold range that included the rate needed for the observed lipid synthesis. The results thus support, quantitatively as well as qualitatively, the supposition that the HMS is accelerated during development to sustain lipid synthesis.     

Ontogeny of Glucose Metabolism in Sympathetic Ganglia of Chickens. Changes in the Carbon Fluxes to CO2, Lactate, and Tissue Constituents from 8 to 19 Days of Embryonic Age

Chains of sympathetic ganglia were excised from the lumbar region of white Leghorn chicken embryos, 8-19 days of age. The chains were incubated for 5 h at 36 degrees C in a bicarbonate-buffered physiological salt solution containing 5.55 mM unlabeled glucose and tracer amounts of glucose labeled either uniformly or at carbon-1 or carbon-6. Glucose uptake and labeled lactate output were both highest in ganglia from the youngest embryos studied and declined progressively with increasing age. The output of labeled CO2 rose to a peak rate at an incubation age of 10-12 days in the presence of either [U-14C]glucose or [1(-14)C]glucose, but changed relatively little with age in the presence of [6(-14)C]glucose. The incorporation of 14C into tissue constituents was fastest at 10-12 days with all three labeled glucoses. It is concluded that the hexosemonophosphate shunt is most active at an incubation age of 10-12 days, after glycolysis has greatly slowed. The literature on morphological and biochemical changes in the sympathetic ganglia during development is briefly reviewed and discussed in relation to the observed metabolic changes. The early high glycolytic rate may be related to the normal developmental delay in vascularization of the sympathetic chains.     

[14C]Glucose Metabolism in Sympathetic Ganglia of Chicken Embryos and in Primary Cultures of Neurons and of Other Cells from These Ganglia

Metabolism of [1-14C]glucose and [6-14C]glucose was measured in sympathetic ganglia excised from chicken embryos 12-16 days old and in primary cultures of neurons or nonneurons prepared from these ganglia. Some metabolic rates tended to change with the tissue/medium ratio, so this variable had to be controlled. Less C-6 than C-1 od glucose was put out in CO2 by all three types of preparations, indicating operation of the hexosemonophosphate shunt. The C-6/C-1 ratio was greater for the neuronal cultures and for intact ganglia than for the nonneuronal cultures. The C-6/C-1 ratio for the neurons increased with the amount of tissue added to a given volume of incubation medium, in agreement with previous experiments on embryonic dorsal root ganglia (Larrabee, 1978). Per unit of protein, the output of C-1 of glucose in CO2 was higher in both the neuronal and the nonneural cultures than in intact ganglia, whereas that of C-6 was higher in the neuronal cultures and lower in the nonneuronal ones than in the ganglia. The rates of release in lactate of C-1 and C-6 of glucose were 3-5 times higher from both types of cultures than from intact ganglia. The average rates of incorporation of C-1 and C-6 of glucose into tissue constituents were lower in the cultures than in intact ganglia, significantly so for incorporation of C-6 in the nonneuronal cultures.     

Synaptogenesis in Co-Culture of Neurons of Dorsal Root Ganglia and Spinal Cord

In co-culture of spinal cord and dorsal root ganglion (DRG) neurons, we studied at different terms of culturing postsynaptic currents in DRG neurons evoked by direct electrical stimulation of single spinal neurons using a voltage-clamp technique in the whole-cell configuration. According to the reversal potential and sensitivity to bicuculline, these currents were classified as inhibitory postsynaptic currents (IPSC) carried by Cl^- ions through GABA_A receptors. During neuronal development in dissociated co-culture, the amplitude of evoked IPSC and their time to peak significantly increased. The time to peak of spontaneous IPSC (sIPSC) in DRG neurons remained unchanged, while the frequency of these currents increased with increasing culturing time. It is concluded that under culturing conditions spinal neurons establish inhibitory synaptic contacts with the somata of DRG neurons, and the number of such functional contacts increases in the course of culturing. Our findings show that in dissociated co-culture the process of formation of inhibitory synapses on the axon terminals of primary afferent neurons is akin to that realized in vivo, but with dissimilar topography of distribution of such synapses.     

Developmental Regulation of Neuregulin1 Isoforms and erbB Receptor Expression in Intact Rat Dorsal Root Ganglia

Neuregulins (NRGs) are a family of growth factors which bind to the erbB family of tyrosine kinase receptors. The exact nature and interaction of specific NRG isoforms and erbB receptors that occur during the development of the nervous system have not been reported. In order to better understand the role that different NRG isoforms and erbB receptors play in the differentiation, proliferation, and survival of neurons and glial cells, we isolated protein and mRNA from dorsal root ganglia of rat pups between embryonic day (E) 13 and postnatal day (P) 15. The relative expression levels of the NRGs and erbB receptors for the different time points were compared using both Western and RT-PCR analyses. NRG1-type1α protein levels were highest at E-13 and then decreased by approximately 40% and remained constant through P-15. In contrast, mRNA levels for NRG1-type1α remained constant from E-15 to P-15. The protein levels for NRG1-type 1β were similar to NRG1-type1α at E-13 with an approximate 40% increase in the levels at E-15 and E-17 followed by a decrease to E-13 levels for the remainder of the developmental time periods. The mRNA levels for NRG1-type1β remained constant from E-15 to P-15. The protein and mRNA expression patterns for each erbB receptor were distinctive. The protein levels for erbB-2 were highest at E-19 while erbB-3 levels were highest at E-17 and E-18. ErbB-4 protein levels were highest at E-13 and decreased through P-15. The developmental pattern for erbB-2 and erbB-4 mRNA levels had no relation to that of the corresponding protein levels while the mRNA levels for erbB-3 were highest at E-17 and E-18 similar to the pattern observed for the erbB-3 protein levels. We concluded that both NRG and erbB expression in dorsal root ganglia are mostly translationally controlled and that NRG1 isoforms and their erbB receptors are not coordinately regulated. Special issue article in honor of Dr. George DeVries.     

Bradykinin Stimulates Phosphoinositide Hydrolysis and Mobilization of Arachidonic Acid in Dorsal Root Ganglion Neurons

Cultures of fetal rat dorsal root ganglion neurons (7 days in culture) were prelabeled with myo-[3H]inositol or [3H]arachidonic acid for 24 h and stimulated with 10 microM bradykinin for time intervals of 5-300 s. The incubation was terminated by addition of 5% perchloric acid to extract inositol phosphates or organic solvent to extract lipids. Inositol phosphates were resolved by anion-exchange HPLC; lipids were resolved by TLC. Bradykinin stimulation resulted in a 10-fold increased accumulation of inositol 1,4,5-trisphosphate (IP3) and inositol bisphosphate (IP2) (fivefold) by 5 s. The increase in IP3 was transient (half maximal by 1 min), whereas stimulated IP2 levels were sustained for several minutes. Even longer term increases were observed in inositol monophosphate. Stimulation also resulted in a threefold increase in arachidonic acid which was preceded by transient increases in diacylglycerol (twofold) and arachidonoyl-monoacylglycerol (threefold). The temporal lag in the accumulation of arachidonic acid with respect to diglyceride and monoglyceride suggested the involvement of di- and monoglyceride lipases in arachidonic acid mobilization. A role for phospholipase A2 is also possible, because pretreatment of cultures with quinacrine partially blocked arachidonic acid release. Bradykinin-stimulated arachidonic acid release was decreased in the presence of calcium channel blockers nifedipine or verapamil (50 microM), or EDTA (2.5 mM). The role of calcium was verified further in that accumulation of phosphatidic acid, diacylglycerol, and arachidonic acid was maximally stimulated by treatment with the calcium ionophore A23187 (20 microM).     

Extracellular Intermediates of Glucose Metabolism: Fluxes of Endogenous Lactate and Alanine Through Extracellular Pools in Embryonic Sympathetic Ganglia

The flux rates of lactate and alanine in and out of the cells of an intact tissue, which cannot be measured directly because some of the released materials are reabsorbed, were determined by computer analysis of uptakes and outputs by the whole tissue in the presence of various concentrations of these substances. The outputs of labeled lactate and alanine from [U-14C]glucose and the uptakes of [U-14C]lactate and [U-14C]alanine were measured on intact sympathetic ganglia excised from 15-day-old chicken embryos. The volume and time constant of the extracellular space were measured using labeled lactate, alanine, and sucrose. Models, which mathematically described the cellular uptakes and outputs as functions of the extracellular concentrations, were used to predict the exchanges that would be observed on the whole tissue, and their parameters were adjusted for best fit to the actual observations. The fitted models were then used to calculate the fluxes in and out of the cells and the concentrations in the extracellular space. The following results were obtained: (1) Cellular uptakes of lactate and alanine were both well described by familiar Michaelis-Menten kinetics. (2) The cellular output of [14C]-lactate from [14C]glucose declined with increase in the extracellular lactate concentration, whereas the cellular output of [14C]alanine from [14C]glucose rose with the extracellular alanine concentration. (3) Half-saturation values for cellular uptake, determined from the fitted equations, were 0.45 mM for lactate and 1.17 mM for alanine, both several-fold lower than less relevant estimates for the whole tissue made directly from the uptake observations. (4) As much as 45% of the carbon in the glucose consumed was released into the extracellular space as lactate and alanine, but much of this was reabsorbed. Implications for brain metabolism are discussed.     

Identification and Cytoprotective Function of a Novel Nestin Isoform,Nes-S,in Dorsal Root Ganglia Neurons

In this study, the first nestin isoform, Nes-S, was identified in neurons of dorsal root ganglia (DRG) of adult rats. Nes-S cannot form filaments by itself in cytoplasmic intermediate filament-free SW13 cells. Instead, it co-assembles into filaments with vimentin when transfected into vimentin⁺ SW13 cells, and with peripherin and neurofilament proteins when transfected into N2a cells. In primary DRG neurons, endogenous Nes-S co-assembles with peripherin and neurofilament proteins. The expression of Nes-S first appears in DRG at postnatal day 5 and persists to adulthood. Among the adult tissues we examined, the expression of Nes-S is restricted to the sensory and motor neurons. Finally, exogenous Nes-S enhances viability when transfected into N2a cells, and knockdown of endogenous Nes-S impairs the survival of DRG neurons in primary cultures. Taken together, Nes-S is a new neuronal intermediate filament protein that exerts a cytoprotective function in mature sensory and motor neurons.     

Nuclear Localization of SP, CGRP, and NK 1 R in a Subpopulation of Dorsal Root Ganglia Subpopulation Cells in Rats

Signals generated by renal pelvic afferent nerves in response to stimulation are transmitted from peripheral processes of dorsal root ganglia neurons to their central terminals in the dorsal horn of the spinal cord to cause the release of neuropeptides, including SP and CGRP. All of the cellular activities of SP are considered to be mediated through interaction with NK₁R located on the cell surface. We have investigated the colocalization and subcellular distribution of NK₁R, SP, and CGRP in different subpopulations of neurons that innervate renal tissue. Our findings therefore provide the first evidence for the presence of NK₁R, SP, and CGRP in the nuclei of DGR neural cells. The physiological significance of this localization remains unknown. One possibility is that pelvic sensory neurons may regulate their responses to different stimuli by modulating the ratio of CGRP and SP release and/or nuclear NK₁R expression.     

Regional Distribution of Calcitonin Gene-Related Peptide-, Substance P-, Cholecystokinin-, Met5-Enkephalin-, and Dynorphin A (1–8)-Like Materials in the Spinal Cord and Dorsal Root Ganglia of Adult Rats: Effects of Dorsal Rhizotomy and Neonatal Capsaicin

Biochemical mapping of five different peptide-like materials--calcitonin gene-related peptide (CGRP), substance P (SP), Met5-enkephalin (ME), cholecystokinin (CCK), and dynorphin A (1-8) (DYN)--was conducted in the dorsal and ventral zones of the spinal cord at the cervical, thoracic, and lumbar levels in 3-month-old rats 10 days after unilateral dorsal rhizotomy at the cervical level (C4-T2) or after neonatal administration of capsaicin (50 mg/kg s.c.). In control rats, all peptide-like materials were more abundant in the dorsal than in the ventral zone all along the spinal cord. However, in both zones, absolute concentrations of CGRP, SP, ME, and CCK were significantly higher at the lumbar than at the cervical level. Rhizotomy-induced CGRP depletion (-85%) within the ipsilateral dorsal zone of the cervical cord was more pronounced than that due to neonatal capsaicin (-60%), a finding suggesting that this peptide is contained in both capsaicin-sensitive (mostly unmyelinated) and -insensitive (myelinated) primary afferent fibers. In contrast, similar depletions of SP (-50%) were observed after dorsal rhizotomy and neonatal capsaicin treatment, as expected from the presence of SP only in the capsaicin-sensitive small-diameter primary afferent fibers. Although the other three peptides remained unaffected all along the cord by either intervention, evidence for the existence of capsaicin-insensitive CCKergic primary afferent fibers could be inferred from the increased accumulation of CCK (together with SP and CGRP) in dorsal root ganglia ipsilateral to dorsal root sections.     

Ontogeny of estrogen receptor alpha,estrogen receptor beta and androgen receptor,and their co-localization with Islet-1 in the dorsal root ganglia of sheep fetuses during gestation

The aims of the present study were to detect the ontogeny of estrogen receptor (ERα and ERβ) and androgen receptor (AR) expressions and their co-localization with Islet-1 in the developing dorsal root ganglia (DRG) of sheep fetuses by immunohistochemistry. From the single staining results, the ERα immunoreactivity (ERα-ir), ERβ immunoreactivity (ERβ-ir) and AR immunoreactivity (AR-ir) was first detected at days 90, 120 and 90 of gestation, respectively. From days 90 to 120, ERα and AR were consistently detected in the nuclei of DRG neurons and the relative percentage (approximately 60%) of ERα-ir or AR-ir cells did not change significantly. Moreover, there was no change in ERα expression, while a dramatic loss of AR expression was observed at birth. From day 120 of gestation to birth, very few neurons (approximately 8%) showed nuclear ERβ immunoreactivity. The dual staining results showed that Islet-1 was co-localized with ERα, ERβ or AR in the nuclei of DRG neurons with various frequencies, and over 70% ERα-ir, ERβ-ir or AR-ir cells contained Islet-1. These results imply that ERs, AR and Islet-1 may be important in regulating the differentiation and functional maintenance of some phenotypes of DRG neurons after mid-gestation in the sheep fetus.     

Partitioning of CO2 Production Between Glucose and Lactate in Excised Sympathetic Ganglia, with Implications for Brain

Abstract: Chains of lumbar sympathetic ganglia from 15-day-old chicken embryos were incubated for 4 h at 36°C in a bicarbonate-buffered salt solution equilibrated with 5% CO₂-95% O₂. Glucose (1–10 m M ), lactate (1–10 m M ), [U-¹⁴C]glucose, [1-¹⁴C]glucose, [6-¹⁴C]glucose, and [U-¹⁴C]lactate were added as needed. ¹⁴CO₂ output was measured continuously by counting the radioactivity in gas that had passed through the incubation chamber. Lactate reduced the output of CO₂ from [U-¹⁴C]glucose, and glucose reduced that from [U-¹⁴C]lactate. When using uniformly labeled substrates in the presence of 5.5 m M glucose, the output of CO₂ from lactate exceeded that from glucose when the lactate concentration was >2 m M . The combined outputs at each concentration tested were greater than those from either substrate alone. The ¹⁴CO₂ output from [1-¹⁴C]glucose always exceeded that from [6-¹⁴C]glucose, indicating activity of the hexose monophosphate shunt. Lactate reduced both of these outputs, with the maximum difference between them during incubation remaining constant as the lactate concentration was increased, suggesting that lactate may not affect the shunt. Modeling revealed many details of lactate metabolism as a function of its concentration. Addition of a blood-brain barrier to the model suggested that lactate can be a significant metabolite for brain during hyperlactemia, especially at the high levels reached physiologically during exercise.     

Chemical Structure and Morphology of Dorsal Root Ganglion Neurons from Naive and Inflamed Mice

Fourier transform infrared spectromicroscopy provides label-free imaging to detect the spatial distribution of the characteristic functional groups in proteins, lipids, phosphates, and carbohydrates simultaneously in individual DRG neurons. We have identified ring-shaped distributions of lipid and/or carbohydrate enrichment in subpopulations of neurons which has never before been reported. These distributions are ring-shaped within the cytoplasm and are likely representative of the endoplasmic reticulum. The prevalence of chemical ring subtypes differs between large- and small-diameter neurons. Peripheral inflammation increased the relative lipid content specifically in small-diameter neurons, many of which are nociceptive. Because many small-diameter neurons express an ion channel involved in inflammatory pain, transient receptor potential ankyrin 1 (TRPA1), we asked whether this increase in lipid content occurs in TRPA1-deficient (knock-out) neurons. No statistically significant change in lipid content occurred in TRPA1-deficient neurons, indicating that the inflammation-mediated increase in lipid content is largely dependent on TRPA1. Because TRPA1 is known to mediate mechanical and cold sensitization that accompanies peripheral inflammation, our findings may have important implications for a potential role of lipids in inflammatory pain.     

Preferential Synthesis of Prostaglandin D2 by Neurons and Prostaglandin E2 by Fibroblasts and Nonneuronal Cells in Chick Dorsal Root Ganglia

To determine the type and the relative amount of prostaglandins (PGs) synthesized by various neural tissues, homogenates of meninges, dorsal root ganglia (DRG) capsules, decapsulated DRG, and unsheathed sciatic nerves were incubated with [1-14C]arachidonic acid. Homogenates of cultured cells (meningeal cells, fibroblasts, and nonneuronal or neuronal DRG cells) were used to specify the cells producing particular PGs. The highest synthetic capacity was found in fibroblast-rich tissues (meninges and DRG capsules) and in cultures of meningeal cells or fibroblasts. Two major cyclooxygenase products were formed: [14C]PGE2 and an unusual 14C-labeled compound, Y. The accumulation of compound Y, corresponding probably to 15-hydroperoxy PGE2, was completely impaired by addition of exogenous GSH, which conversely enhanced the synthesis of [14C]PGE2 and promoted the formation of [14C]PGD2. In contrast, decapsulated DRG or unsheathed sciatic nerves displayed a 10-20 times lower capacity to synthesize PGs than fibroblast-rich tissues and produced mainly [14C]PGE2 and [14C]PGD2. In this case, [14C]PGE2 or [14C]PGD2 synthesis was neither enhanced nor promoted by addition of exogenous GSH. Neuron-enriched DRG cell cultures allowed us to specify that [14C]PGD2 is the major prostanoid produced by primary sensory neurons as compared with nonneuronal DRG cells. Because PGD2 synthesis in DRG and more specifically in DRG neurons does not depend on exogenous GSH and differs from PGD2 synthesis in fibroblast-rich tissues, it is concluded that at least two distinct enzymatic processes contribute to PGD2 formation in the nervous system.(ABSTRACT TRUNCATED AT 250 WORDS)     

Reduced numbers of calcitonin gene-related peptide-(CGRP-) and tachykinin-immunoreactive sensory neurones associated with greater enkephalin immunoreactivity in the dorsal horn of a mutant rat with hereditary sensory neuropathy

Summary The mutilated foot rat is a mutant with autosomal recessive sensory neuropathy and frequent mutilation of the hindlimbs. Decreased numbers of dorsal root ganglion cells and diminished sensitivity to painful stimuli are characteristics of these animals. By use of immunocytochemistry, changes in the distributions of peptides involved in sensory and/or autonomic regulation, i.e. calcitonin generelated peptide (CGRP), tachykinins, enkephalin and neuropeptide Y in spinal cord, dorsal root ganglia and skin of these animals, were studied. In comparison with normal litter-mate controls, the dorsal horn of mutilated foot rats contained substantially fewer CGRP and tachykinin-immunoreactive fibres but more fibres immunoreactive for enkephalin. Many enkephalin-immunoreactive cell bodies were also found in the dorsal horn of the mutants, by contrast none were visible in control animals. Neuropeptide Y immunoreactivity was, however, unchanged in the spinal cord of the mutants. In the dorsal root ganglia of the mutants, the number of CGRPor tachykinin-immunoreactive cells and their proportion to total neuronal numbers were significantly less in comparison with normal controls. The diameter range of CGRP- and tachykinin-immunoreactive cells shifted from small (15–25 m) to medium size (25–45 m) as revealed by frequency distribution histograms. The skin from the affected foreand hindlimbs of the mutant rats, in keeping with fewer CGRP- and tachykinin-immunoreactive cells in the dorsal root ganglia, contained substantially less fibres immunoreactive for CGRP and tachykinins; a difference that was not seen in skin of unaffected areas (whiskers and snout). By contrast, neuropeptide Y-immunoreactive fibres showed a normal distribution around blood vessels and sweat glands of mutilated foot rats. The data suggest that diminished pain perception in the mutilated foot rat is related to loss of peptide-containing sensory neurones. Furthermore, the intraspinal increase of enkephalinergic neurones in the dorsal horn, concomitant with the decreased number of primary sensory neurones, may also play a contributory rôle in reducing pain thresholds.     

[3H]Choline Uptake and Metabolism in Nonsynaptic Regions of a Crustacean Sensory Nerve

Abstract: The posterior stomach nerve (PSN) is a crustacean sensory nerve containing about 60 cholinergic neurons, which are devoid of synaptic interactions. Kinetic analysis shows that the PSN takes up [³H]choline by both low-affinity ( K _m= 163 μM) and high-affinity (Na⁺-dependent) ( K _m= 1 μM) processes. The capacity of the high-affinity system is only about 1% that of the low-affinity system. The high-affinity system is not tightly coupled to acetylcholine (ACh) synthesis, and it appears that both ACh and phosphorylcholine are formed from an intracellular pool of choline, which is fed by both uptake systems. There are differences in the rates of [³H]choline uptake and ³H metabolite accumulation between regions of the PSN that contain neuronal cell bodies and those that do not. These differences may arise from differences in the relative proportion of neuronal to nonneuronal tissue in each nerve region.     

Gene expression and localization of diacylglycerol kinase isozymes in the rat spinal cord and dorsal root ganglia

The dorsal root ganglion (DRG) and dorsal horn of the spinal cord are areas through which primary afferent information passes enroute to the brain. Previous studies have reported that, during normal neuronal activity, the regional distribution of a second messenger, diacylglycerol (DG), which is derived from phosphoinositide turnover, is diverse in these areas. However, the way that DG is regulated in these organs remains unknown. The present study was performed to investigate mRNA expression and protein localization of DG kinase (DGK) isozymes, which play a central role in DG metabolism. Gene expression for DGK isozymes was detected with variable regional distributions and intensities in the spinal cord. Among the isozymes, most intense signals were found for DGKζ and DGKι in the DRG. By immunohistochemical analysis, DGKζ immunoreactivity was detected heterogeneously in the nucleus and cytoplasm of small DRG neurons with variable levels of distribution, whereas it was detected exclusively in the cytoplasm of large neurons. On the other hand, DGKι immunoreactivity was distributed solely in the cytoplasm of most of the DRG neurons. Double-immunofluorescent imaging of these isozymes showed that they coexisted in a large population of DRG neurons at distinct subcellular sites, i.e., DGKζ in the nucleus and DGKι in the cytoplasm. Thus, DGK isozymes may have different functional roles at distinct subcellular sites. Furthermore, the heterogeneous subcellular localization of DGKζ between the nucleus and cytoplasm implies the possible translocation of this isozyme in small DRG neurons under various conditions.The work was supported by grants-in-aid from the Ministry of Education, Science, Culture, and Sports of Japan (M.T., K.G.) and from the Ono Medical Research Foundation, Kato Memorial Bioscience Foundation, and Janssen Pharmaceutical (K.G.) and by the 21st Century Center of Excellence Program of the Ministry of Education, Culture, Sports, Science and Technology of Japan.