Joshua E. Adler

Substance p and somatostatin metabolism in sympathetic and special sensory ganglia in vitro

Mechanisms regulating the content of the putative peptide transmitters, substance P and somatostatin, were examined in several neuronal populations in culture. Substance P levels increased more than 25-fold within 48 h in sympathetic neurons in the explanted rat superior cervical ganglion, and remained elevated for 4 weeks. Identity of the peptide was authenticated by combined high pressure liquid chromatography-radioimmunoassay. Veratridine prevented the increase of substance P in vitro, and tetrodotoxin blocked the veratridine effect, suggesting that sodium ion influx and membrane depolarization prevent peptide elevation. Veratridine (or potassium)-induced membrane depolarization released substance P into the culture medium through a calcium-dependent process. Consequently, at least some veratridine effects are attributable to release and subsequent depletion of ganglion peptide. However, the inhibitory effects of veratridine were far greater than could be accounted for by the quantity of peptide released, suggesting a separate influence on net synthesis (synthesis less catabolism) of substance P. Viewed in conjunction with previous in vivo studies, our observations suggest that trans-synaptic impulses, through the mediation of postsynaptic sodium flux, release substance P from sympathetic neurons and also regulate intracellular peptide metabolism. To determine whether the processes regulating substance P in sympathetic neurons reflect generalized mechanisms, a different peptide, somatostatin, was examined in sympathetic neurons; moreover, substance P was examined in a different neuronal population, special sensory neurons in the nodose ganglion. Substance P levels increased significantly in both sympathetic and sensory neurons after explantation, and somatostatin levels increased in sympathetic neurons. In each instance, the increase was dependent upon the presence of the calcium ions. Moreover, these increases were all prevented by veratridine, in a tetrodotoxin-sensitive manner. Our observations suggest that common regulatory mechanisms govern peptide transmitter metabolism in diverse neuronal populations.

Membrane contact regulates transmitter phenotypic expression

High cell density, with attendant aggregation, selectively increases expression of substance P (SP) and choline acetyltransferase (ChAT) in virtually pure neonatal sympathetic neuronal cultures. To investigate the specific role of cell contact in selective transmitter expression, SP content and ChAT activity were examined in such cultures under various conditions. At high neuronal density SP content, detectable 6 h after plating, doubled during the first two culture days and subsequently increased more than 10-fold. Similarly, ChAT activity appeared de novo after two days and rose rapidly thereafter. The increases closely paralleled perikaryal aggregation, suggesting that cell contact might be the critical factor. Moreover, interference with aggregation physically, using methylcellulose, or chemically, using tunicamycin, inhibited the increases in SP content and ChAT activity without affecting neuronal survival. Thus, cell contact appears to mediate the expression of ChAT and the rise of SP in high-density neuronal cultures. To determine whether interaction of membrane component(s) elicited the rises in ChAT activity and SP content, membranes extracted from the neonatal superior cervical ganglion (SCG) were added to cultures of varying densities. After 3 days in high-density cultures, membranes doubled the increases in ChAT and SP. Moreover, even in lower-density cultures, membranes elicited the appearance of ChAT activity. Specificity was defined by examining membranes extracted from a variety of neonatal rat tissues. Dorsal root ganglia membranes were most effective in stimulating ChAT, followed by membranes from the SCG, kidney and brain. Membranes derived from the adrenal gland, liver and spinal cord had no effect. Our findings suggest that interaction of cell membrane components regulates phenotypic expression in aggregating neurons.

Target organ regulation of substance P in sympathetic neurons in culture

Target organ regulation of the putative, peptide neurotransmitter, substance P (SP) was examined in explants and dissociated cell cultures of the neonatal rat sympathetic superior cervical ganglion (SCG). SP levels increased dramatically in explants, rising more than 30-fold after 72 hr in culture. By contrast, peptide levels did not increase in dissociated ganglion cultures. However, SP increased almost 10-fold in cell cultures grown on a monolayer of cells derived from the pineal or salivary gland, targets of the SCG. By contrast, SP content did not increase in cultures grown on a substrate of cells derived from heart or intestine. Peptide identity in the SCG-target cocultures was authenticated by means of combined high-pressure liquid chromatography (HPLC)-radioimmunoassay. Moreover, immunohistochemical examination localized the peptide virtually exclusively to sympathetic neurons and nerve processes. Mechanisms mediating the sympathetic-target interaction were examined in SCG-pineal cocultures. The increase in peptide required interactions with living tissue, since substrates of killed target cells did not elevate SP levels. The target influences were not mediated by nerve growth factor or indoleamines, potential secretory products of pineal in culture. Veratridine treatment prevented the increase in SP in the cocultures, and tetrodotoxin blocked the veratridine effect, suggesting that sodium influx and membrane depolarization prevent SP elevation. Our observations suggest that sympathetic neuron interactions with target organs influence peptidergic expression, and that this interaction may be restricted to certain appropriate target structures.

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.

Glucocorticoids regulate adrenal opiate peptides

Abstract Although glucocorticoids and impulse activity are well-recognized mediators of adrenal catecholamine biosynthesis, the effects of these signals on the colocalized opiate peptide system is only presently emerging. Since it is generally agreed that impulse activity regulates adrenal opiate peptides, in the present report we sought to determine whether adrenal opiates are also subject to hormonal control. Pharmacological destruction of the adrenal cortex resulted in a decrease in baseline Leu-enkephalin levels in vivo. This suggested a tonic regulatory effect of adrenal cortical steroids on enkephalin pathways. To further examine the role of glucocorticoid hormones in regulating enkephalin biosynthesis in a more dynamic system, medullae were grown as explants where peptide levels typically rise 30- to 50-fold above baseline. Explanted medullae required medium supplemented with dexamethasone or corticosterone to achieve maximal levels of Leu-enkephalin in a dose-dependent fashion. The effects of glucocorticoid treatment were blocked by specific glucocorticoid receptor antagonists or by inhibition of receptor translocation to the nucleus. Since enkephalin levels rose in cultured medullae (even in the absence of added glucocorticoids), glucocorticoid-independent regulatory mechanisms may also play a role in this model. Based on this and previous results, it appears that adrenal opiate peptides, like catecholamines, are subject to dual hormonal and transsynaptic regulatory influences. The interaction of these two regulatory mechanisms may serve an adaptive role in modulating complex biochemical and behavioral responses with exquisite precision.

Simultaneous expression of the SP-peptidergic and noradrenergic phenotypes in rat sympathetic neurons.

We previously observed that substance P (SP) levels in the rat superior cervical ganglion (SCG) rise sharply when the ganglion is maintained in vitro. To define the cellular localization of SP, sections of cultured SCG were stained for the possible dual presence of SP and tyrosine hydroxylase (TOH). Immunoreactivity to both SP and TOH was present in the majority of principal neurons. This observation suggests that principal sympathetic neurons can express simultaneously both the noradrenergic and SP-peptidergic phenotypes.

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)

Regulation of neurotransmitter expression by a membrane-derived factor

Cell-cell contact appears to play a critical role in the expression of transmitter traits in developing neurons. We have previously shown that cell membrane contact induces the de novo appearance of choline acetyltransferase (CAT) in virtually pure cultures of dissociated sympathetic neurons. A membrane-associated CAT-inducing factor has been extracted and purified 5000-fold. This factor exerts differential effects on transmitter traits in cultured sympathetic neurons. After 3 days in vitro, neurons exposed to the factor contained 40-fold higher levels of the neuropeptide substance P than controls. Somatostatin exhibited a similar dramatic elevation. In contrast, the factor had no effect on leucine-enkephalin. Further, the specific activity of tyrosine hydroxylase was reduced to 5% of control activity in treated cultures. These effects occurred in the absence of any increases in cell number. Thus, it appears that cell contact via membrane-associated factors may exert differential effects on phenotypic expression.

Development of transsynaptic regulation of adrenal enkephalin

Transsynaptic activity differentially regulates biosynthesis of sympathoadrenal catecholamines and co-localized opiate peptides in the rat. We determined whether similar mechanisms were operative during development. Adrenal Leu-enkephalin (LEU), was first detected at E16.5, then increased 5-fold during maturation from birth to adulthood while adrenal weight increased 10-fold. Since medullary cells do not divide after the first postnatal week, this represents a specific maturational increase in LEU content per chromaffin cell. In adult medullae, decreasing transsynaptic activity through adrenal denervation or explantation results in a 30-50-fold increase in LEU. In contrast, LEU levels in denervated or explanted medullae from neonatal rats (less than or equal to 10 days) do not. Prolonged denervation (day 5-21) prevented even the normal maturational increase in LEU. However, depolarizing medullae with KCl lowered LEU levels at all ages tested with an increased magnitude of effect after 10 days postnatal age. Specific deficits in signal-transduction mechanisms or immaturity of opiate biosynthetic pathways may account for these observations. Thus, during development, adrenal opiate peptides are not under transsynaptic control yet require presynaptic terminals to mature normally. Therefore, like catecholamines, co-localized adrenal opiate peptides require presynaptic regulatory signals to achieve normal development and function.

Regulation of NGF gene expression in CNS glia by cell-cell contact.

Nerve growth factor (NGF) gene expression in central nervous system (CNS) glia appears to be associated with active glial growth. To study the underlying molecular mechanisms, we examined the effects of a number of growth-related factors on NGF mRNA expression in glial cultures. Our results suggest that glial membrane interaction, as a consequence of growth, actively inhibits NGF gene expression in CNS glia.