Expression and regulation of catecholaminergic traits in primary sensory neurons: relationship to target innervation in vivo

Catecholaminergic (CA) phenotypic characteristics have recently been detected in adult sensory neurons, demonstrating that CA expression in the periphery extends beyond the sympathoadrenal axis. Consequently, we may now determine whether common principles underlie CA phenotypic organization in functionally and embryologically diverse populations of peripheral neurons. To begin defining sensory transmitter regulation, the present study examined the relationship of CA expression to sensory target innervation in cranial nerve ganglion cells of the adult rat. Retrograde labeling combined with tyrosine hydroxylase (TH) immunocytochemistry indicated that 80-90% of CA sensory neurons in the glossopharyngeal petrosal ganglion project peripherally in the carotid sinus nerve (CSN). Most of these cells innervate a single target, the carotid body, revealing a striking correlation between CA expression and the pattern of sensory target innervation. Furthermore, CSN transection resulted in a transient marked decrease in TH catalytic activity and immunoreactivity within 1 week. Activities returned to normal by 3 weeks. Thus, axotomy reversibly decreased sensory TH, reproducing effects observed with central CA neurons (Ross et al., 1975), but differing in certain aspects from observations with sympathetic CA neurons (Cheah and Geffen, 1973; Kessler and Black, 1979). To determine whether disruption of axonal transport itself decreased TH in petrosal neurons, colchicine cuffs were placed around the intact CSN. Colchicine blockade reproduced the effects of axotomy, suggesting that deranged transport, and not axonal damage per se, altered TH. Finally, we studied the role of sensory projections to the CNS by examining petrosal TH after glossopharyngeal nerve rhizotomy. In contrast to sequelae of peripheral axotomy, rhizotomy did not alter TH, suggesting that projections to the periphery predominate in regulation of sensory TH.(ABSTRACT TRUNCATED AT 250 WORDS)     

Sustained potentiation by substance P of NMDA-activated current in rat primary sensory neurons

This study aimed to explore the modulatory effect of substance P (SP) on the current response mediated by N-methyl-D-aspartate (NMDA) receptor in rat primary sensory neurons and its time course using whole-cell patch clamp technique. The majority of neurons (179/213, 84.0%) examined were sensitive to NMDA (0.1-1000 microM) with an inward current, and a proportion of the NMDA-sensitive neurons also responded to SP (78/98, 80.0%) with an inward current. Pretreatment with SP potentiated the NMDA-activated current (INMDA) in a non-competitive manner, which is shown in that SP shifted the concentration-response curve for NMDA upwards compared with the control; the maximal value of INMDA increased fourfold, while the EC50 values for both curves were very close (28 vs. 30 microM). Furthermore, this potentiating effect was time-dependent: the amplitude of INMDA reached its maximum 20 min after SP preapplication, and thereafter maintained a steady level of about 2-3 times its control for 2 or even 3 h. This sustained potentiation by SP of INMDA could be blocked by extracellular application of WIN51708, a selective non-peptide antagonist of NK-1 receptor; and abolished by intracellular application of either BAPTA, or H-7, or KN-93. Though NMDA applied alone also induced a short-term (less than 20 min) self-potentiation of INMDA, it could be abolished by intracellular dialysis of BAPTA or KN-93 completely. As is known, the cell body of dorsal root ganglion (DRG) neurons is generally used as an accessible model for studying the characteristics of the membrane of primary afferent terminals in the dorsal horn of spinal cord. Therefore, these results may offer a clue to the explanation of the symptoms of chronic pain.     

Increase of preprotachykinin mRNA and substance P immunoreactivity in spared dorsal root ganglion neurons following partial sciatic nerve injury

Complete sciatic nerve injury reduces substance P (SP) expression in primary sensory neurons of the L4 and L5 dorsal root ganglia (DRG), due to loss of target-derived nerve growth factor (NGF). Partial nerve injury spares a proportion of DRG neurons, whose axons lie in the partially degenerating nerve, and are exposed to elevated NGF levels from Schwann and other endoneurial cells involved in Wallerian degeneration. To test the hypothesis that SP is elevated in spared DRG neurons following partial nerve injury, we compared the effects of complete sciatic nerve transection (CSNT) with those of two types of partial injury, partial sciatic nerve transection (PSNT) and chronic constriction injury (CCI). As expected, a CSNT profoundly decreased SP expression at 4 and 14 days postinjury, but after PSNT and CCI the levels of preprotachykinin (PPT) mRNA, assessed by in situ hybridization, and the SP immunoreactivity (SP-IR) of the L4 and L5 DRGs did not decrease, nor did dorsal horn SP-IR decrease. Using retrograde labelling with fluorogold to identify spared DRG neurons, we found that the proportion of these neurons expressing SP-IR 14 days after injury was much higher than in neurons of normal DRGs. Further, the highest levels of SP-IR in individual neurons were detected in ipsilateral L4 and L5 DRG neurons after PSNT and CCI. We conclude that partial sciatic nerve injury elevates SP levels in spared DRG neurons. This phenomenon might be involved in the development of neuropathic pain, which commonly follows partial nerve injury.     

Immunohistochemical localization of bombesin/gastrin-releasing peptide and substance P in primary sensory neurons

The existence of bombesin/gastrin-releasing peptide-like immunoreactivity (BN-GRP-LI) in rat sensory ganglia and spinal cord was confirmed using immunocytochemistry, gel filtration chromatography, and high performance liquid chromatography combined with radioimmunoassay. Immunohistochemical studies showed that in the spinal sensory ganglia of the rat about 5% of the neurons exhibited BN-GRP-LI, whereas about 20% of the neurons exhibited substance P-like immunoreactivity (SP-LI). The two immunoreactivities were found in different cells, but both were located in small ganglion cells. In the posterior horn of the spinal cord, BN-GRP-LI and SP-LI were located in the superficial layers, and this distribution was different from that of Met5-enkephalin-like immunoreactivity. The results are in agreement with the concept that there is a primary sensory pathway from the sensory ganglia to the spinal cord which contains BN-GRP-LI and that these neurons are separate from those containing substance P. In extracts prepared from spinal ganglia, two molecular weight forms of BN-GRP-LI were found using gel filtration chromatography. The high molecular weight form coeluted with porcine GRP and the low molecular weight form was smaller than bombesin. The low molecular weight BN-GRP-LI extracted from spinal cord was more hydrophilic than bombesin or ranatensin.     

Cooperative regulation of calcitonin gene-related peptide levels in rat sensory neurons via their central and peripheral processes.

Calcitonin gene-related peptide (CGRP) is present in both motor and sensory neurons and transported in the somatofugal direction. CGRP levels in sensory neurons are assumed to be regulated by NGF supplied from their peripheral targets. In cultured sensory neurons, however, a basal level of CGRP persists even without NGF. This suggests that some additional factors may be involved in regulation of CGRP levels of sensory neurons. The present study shows that chronic section of the sciatic nerve in the rat reduces CGRP levels in the lumbar dorsal root ganglia (DRG), whereas section of dorsal roots increases CGRP levels in the DRG. This increased CGRP level by dorsal rhizotomy was associated with enhancement of the CGRP mRNA expression in the DRG. Thus, CGRP expression in DRG appears to be regulated reciprocally via their central and peripheral processes. When the sciatic nerve had been cut 1 week previously, however, dorsal rhizotomy no longer increased CGRP levels in the lumbar DRG. Therefore, stimulation of CGRP synthesis in the DRG by dorsal rhizotomy may require the integrity of the peripheral processes. When NGF had been infused into the central stump of the cut sciatic nerve, dorsal rhizotomy again increased CGRP levels in the DRG, despite prior section of the peripheral processes. We conclude that CGRP expression in sensory neurons may be regulated by cooperative action of some factors derived via their central processes and NGF supplied from the peripheral targets.     

Change in excitability and phenotype of substance P and its receptor in cat Abeta sensory neurons following peripheral inflammation.

The effect of peripheral inflammation on spontaneous firing and level of substance P (SP) and its receptor in electrophysiologically identified cat Abeta neurons of dorsal root ganglion (DRG) was studied in vivo using a combination of intracellular recording, dye injection and immunohistochemical techniques. Following injection of carrageenan (Carg) into cat hindpaw, the number of Abeta neurons with spontaneous firing was enhanced significantly (42.9%, n=182) in comparison with control (16.8%, n=149, P<0.01). DRG Abeta neurons became less depolarized 2-4 h following Carg injection. After identifying the cell properties, Lucifer Yellow was injected and SP-like immunoreactivity (SP-LI) was then detected. A total of 17% of Abeta sensory neurons exhibited SP-LI in inflammatory cat. We also found in rat DRGs that the number of SP-LI positive large cells (>35 microm) was also significantly increased in Carg-treated DRG (11.8+/-1.2, n=8) compared with untreated DRG (1.8+/-0.8, n=8, P<0.01). In control cat, the topical use of SP in DRG did not induce any response of Abeta neurons. However, in Carg-treated cat, SP depolarized the membrane potential in most Abeta neurons (68.2%, n=22). L668,169, an antagonist of SP receptor, completely blocked the SP-induced responses. Furthermore, repeated application of SP did not induce obvious desensitization of Abeta neurons. These data suggest that peripheral inflammation increased the excitability, SP level and sensitivity of SP receptor of Abeta neurons. Therefore, we concluded that Abeta sensory neurons appear to contribute to inflammatory allodynia.     

Synaptic regulation of hypothalamic neurons containing ACTH by substance P

Synaptic connections between substance P (SP)- and ACTH-containing neurons in the rat arcuate nucleus were studied by a technique of combined pre- and postembedding immunohistochemical staining. The results showed that immunoreactive (ir) SP fiber terminals form synapses with ir ACTH cell bodies. This strongly suggests that the activity of ACTH neurons is under neuronal regulation by SP neurons.     

ANF receptors: distribution and regulation in central and peripheral tissues

Atrial natriuretic factor is a recently-discovered family of biologically active peptides produced in, stored and secreted by mammalian atria. ANF exerts a wide variety of actions in the periphery as well as within the central nervous system. In general, these actions are directed toward the maintenance of body fluid and electrolyte balance and regulation of arterial blood pressure. In a fashion similar to that of many other hormonal systems, the actions of ANF in various target tissues appear to be mediated by at least one class of specific receptors. However, while the biosynthesis and biological actions of ANF have been extensively investigated, little research has been focused on ANF receptor systems. In this article, we will provide an overview of current literature regarding the distribution and binding characteristics of receptor sites for ANF in peripheral and central target tissues. In addition, we will consider factors involved in the regulation and alteration of ANF receptor sites in various tissues. Finally, a brief discussion of the emerging concept of ANF and angiotensin II as mutual antagonists in body fluid homeostasis and cardiovascular regulation will be offered.     

Gene regulation in an ascending nociceptive pathway: inflammation-induced increase in preprotachykinin mRNA in rat lamina I spinal projection neurons.

Tachykinin peptides are distributed widely in the nervous system and have been shown to play a prominent role in nociceptive pathways in the spinal cord and dorsal root ganglia. This study investigated the inflammation-induced response of dorsal horn projection neurons and local circuit neurons expressing preprotachykinin (PPT) mRNA using RNA blot analysis and in situ hybridization histochemistry. To identify projection neurons, fluorogold was injected into the parabrachial area of the brainstem. In laminae I, II and V/VI ipsilateral to inflammation, there was a differential increase in the number of neurons exhibiting PPT mRNA. In lamina I, the number of spinal projection neurons containing PPT mRNA showed a greater than 200% increase. The identification of spinal projection neurons with inflammation-induced increases in PPT mRNA suggests that tachykinin peptides may act as neurotransmitters in nociceptive CNS projection pathways.     

Local immune regulation in the central nervous system by substance P vs. glutamate.

The response of parenchymal microglia to interferon-gamma (IFN-gamma) varies across the brain. To ask if local neurochemicals contribute to site-specific control, the influence of substance P (SP) and glutamate was evaluated in brainstem vs. hippocampus. In brainstem, stereotaxic injection of SP increased class II MHC upregulation by IFN-gamma, while a SP receptor antagonist (Spantide I) prevented it. In hippocampus, where the baseline response to IFN-gamma was lower, SP was ineffective, but blocking glutamate enhanced the response in a proportion of rats. Attempts to understand and control immune activity in the CNS should take the local neurochemical environment into account.     

A comparison of substance P peptide and preprotachykinin mRNA levels during development of rat medullary raphe and neostriatum

Substance P (SP) and the mRNA coding for its precursor peptide, preprotachykinin (PPT), were measured in medullary raphe nuclei (MRN) and neostriatum (NS) over development in order to determine (1) whether PPT mRNA levels correlate with peptide development, and (2) whether changes in PPT mRNA might help to account for the apparent decline in SP seen immunohistochemically in certain brain areas postnatally. Total RNA was quantified in dissected tissue pieces using the sensitive orcinol reaction. When MRN PPT mRNA levels measured by Northern blot analysis were adjusted to total RNA levels, PPT mRNA per MRN increased over development with a profile similar to that seen for SP peptide. Moreover, both peptide and mRNA levels exhibited a similar decline after postnatal day 15. Therefore, developmental regulation of SP biosynthesis in the MRN may, in part, explain previous evidence documenting a postnatal decline in SP there. In the NS, SP peptide and PPT mRNA increased with a similar profile from E18 through the first postnatal week. Thereafter, SP increased less rapidly than its mRNA, indicating incongruities in prohormone message and processed peptide in the NS.     

Capsaicin and regulation of respiration: Interaction with central substance P mechanisms

Summary The neuropharmacological effects of capsaicin (CAPS) (8-methyl-N-vanillyl-6-nonenamide) have been closely linked to the peptide neurotransmitter substance P (SP).In order to elucidate SP mechanisms in peripheral and central control of breathing we have studied the respiratory effects of CAPS and SP administration to neonatal and adult rats using a whole body plethysmographic method. CAPS (3 and 30g) induced an immediate apnea after intravenous injection. This effect could be reduced by vagotomy but not further changed by combined vagotomy and glossopharyngectomy. The apnoic periods were followed by periods of tachypnea. Intracerebroventricular (i.c.v.) administration of CAPS resulted in an increased tidal volume (V_T) and a decreased respiratory frequency (f),i.e. a respiratory response similar to that seen after i.c.v. SP. No apnoic episodes were seen after i.c.v. injection. The respiratory pattern after acute i.c.v. CAPS administration was not significantly changed by neonatal CAPS pretreatment. However, while saline pretreated control animals responded to an i.c.v. injection of SP with an increase in V_T and inspiratory drive (V_T/T_I), animals pretreated with CAPS responded with a shortening of inspiratory and expiratory time in combination with an increase in V_T. Similar changes have been observed in vagotomized animals after SP administration.It is concluded that CAPS elicits apnea via mechanisms located outside the CNS, which cannot be fully deafferented by combined vagotomy and glossopharyngectomy. Furthermore, CAPS i.c.v. induces a stimulation of respiration by a central mechanism of action, possibly due to a release of SP. Neonatal pretreatment with CAPS modifies the respiratory response to i.c.v. SP. This effect might be due to an impairment in tonical afferent SP mechanisms to the central respiratory regulating system and possibly also to an impairment of central SP mechanisms involved in respiration.     

Immunocytochemical evidence for synaptic regulation of paraventricular vasopressin-containing neurons by substance P

Employing a combination of pre-embedding peroxidase-antiperoxidase-labeling for substance P (SP) and postembedding immunogold labeling with protein A-colloidal gold-anti-arginine vasopressin (AVP) complex, we demonstrated immunoreactive SP containing nerve fibers, which terminate synaptically on the perikarya, contained gold-labeled secretory granules in the magnocellular paraventricular nucleus of rats. The perikarya were also synapsed with unlabeled nerve fibers. It is concluded that SP plays a role as an axosomatic neurotransmitter in diverse synaptic controls of vasopressinergic neurons.     

Basal and stimulated release of substance P from dissociated cultures of vagal sensory neurons.

Substance P, the widely distributed 11 amino acid neuropeptide, is present in up to 20% of vagal sensory cell bodies and the fibers emanating from them. To study the factors regulating the release of SP, vagal sensory (nodose or nodose/jugular) ganglia were obtained from neonatal rats and dissociated using neutral protease. Survival of plated neurons on collagen substrate was 10-20% at 2 weeks and 20-30% when neurons were plated over previously dissociated rat atriacytes. Substance P content was low in cultures for the first several days, then rose linearly to 0.1-0.2 pg/surviving neuron. Substance P was released into a 4.5 mM potassium medium at a steady rate of 0.036%/min. In 50 mM K+ supplemented medium, total release during 20 min increased 5-8-fold and steady-state release increased 4-5-fold to 0.15%/min. The sensory neuron specific excitatory neurotoxin, capsaicin, evoked SP release in similar amounts to 50 mM K+. Both net K(+)- and capsaicin-evoked, but not basal release were completely inhibited by 3.5 mM cobalt chloride. Bradykinin, 1-100 nM, stimulated SP release 2-4 times above basal levels. Forskolin and phorbol ester also increased SP release 1.5-3 times basal amounts. In summary, substance P is present in cultured vagal sensory neurons in amounts similar to in vivo and is released in response to sensory specific stimuli. These cultures should allow exploration of some of the tissue specific factors regulating neurotransmitter release in the sensory vagus nerve.     

Expression of myelin basic protein mRNA and polypeptides in mouse oligodendrocytes in culture: differential regulation by genetic and epigenetic factors

We have analyzed the effects of genetic and epigenetic factors on the steady-state levels of myelin basic protein mRNA and polypeptides during development of mouse oligodendrocytes in culture. Oligodendrocytes were characterized by immunofluorescent staining with antibodies for the following markers: galactocerebroside, myelin basic protein, proteolipid protein, myelin-associated glycoprotein and 2',3'-cyclic nucleotide phosphohydrolase. Oligodendrocytes expressing one or more of these markers first appeared at 3 days in culture and increased to a maximum of 1.5 X 10(5) per brain around 6 days, after which the number remained constant up to 31 days. In medium containing fetal calf serum, accumulation of myelin basic protein polypeptides was delayed relative to in vivo in cultures derived from C57BL/6J, BALB/cJ and DBA/2J inbred mice, but not in cultures derived from C3H/HeJ and AKR/J inbred mice. In medium containing serum from other species or in serum substitute, the temporal expression of myelin basic protein polypeptides in cultures from all the inbred strains was contemporaneous with that in brain. Northern hybridization analysis indicated that the steady-state level of myelin basic protein-specific mRNA in all cultures was regulated similarly to in vivo suggesting that the delayed expression of myelin basic protein polypeptides in some cultures was due to translational and/or post-translational regulation. Analysis of myelin basic protein expression in cultures from informative hybrid and recombinant inbred strains indicated that translational or post-translational expression of myelin basic protein requires trans-acting factors, the inducibility of which is controlled by multiple genetic determinants which segregate independently and are expressed additively.(ABSTRACT TRUNCATED AT 250 WORDS)     

Expression and regulation of tyrosine hydroxylase in adult sensory neurons in culture: Effects of elevated potassium and nerve growth factor

To determine whether similar molecular mechanisms regulate the same proteins in diverse neuronal populations, the present study compared regulation of tyrosine hydroxylase (TOH) in placodal sensory and neural crest-derived sympathetic neurons in tissue culture. Long-term explant cultures of adult nodose and petrosal sensory ganglia (NPG) contained abundant TOH-immunoreactive neurons and exhibited TOH catalytic activity, as in vivo. After an initial decline during the first week of culture, enzyme activity was maintained at a stable plateau of 60% of zero time values for at least 3 weeks. However, exposure of 2-week-old cultures to depolarizing concentrations of potassium (K+; 40 mM) increased TOH activity approximately two-fold; total protein was unchanged, suggesting that the rise was due to increased TOH specific activity. Therefore, membrane depolarization in vitro appears to regulate this specific catecholaminergic (CA) trait in sensory, as in sympathetic CA cells. In sympathetic neurons, NGF regulates TOH activity throughout life. In marked contrast, TOH activity in adult NPG cultures was unchanged in the presence of 0, 10 or 100 units NGF/ml or in the presence of high concentrations of antiserum against the beta-subunit of NGF. Adult sympathetic neurons, however, grown under identical conditions, exhibited a 5- to 10-fold rise in TOH activity in the presence of NGF. Thus, unlike sympathetics, CA metabolism in adult NPG neurons is not regulated by NGF in vitro; NGF is therefore unlikely to mediate target effects on CA metabolism in placodal sensory neurons in vivo. Our findings indicate that certain mechanisms of CA regulation are shared by placodal sensory and neural crest-derived sympathetic neurons, whereas others are not.(ABSTRACT TRUNCATED AT 250 WORDS)