Receptor endocytosis and dendrite reshaping in spinal neurons after somatosensory stimulation

Somatostatin receptors in Neuro2A neuroblastoma cells: ligand internalization

1. Receptor-dependent internalization of somatostatin (SRIF) agonists has been a matter of controversy probably because [125I]Tyr11-SRIF-14 is rapidly degraded. We have studied the internalization of a stable somatostatin analogue, [125I]-BIM-23027, in a neuronal cell line, Neuro2A, which natively expresses somatostatin sst2 receptors. 2. Incubation of Neuro2A cells with [125I]-BIM-23027 at 37 degrees C resulted in a time-dependent internalization of the ligand, which reached a maximum at 30 min. Acid-washing showed that cell-surface binding of the ligand accounted for only 34% of total binding at this time. Internalization was dramatically reduced at 15 degrees C. 3. Internalization of [125I]-BIM-23027 was prevented by inclusion of unlabelled somatostatin receptor agonists in a concentration-dependent manner. The IC50 values for inhibition of [125I]-BIM-23027 internalization were approximately 100 fold lower than for inhibition of [125I]-BIM-23027 binding to membrane homogenates but followed the same rank order of potencies. 4. Disruption of G-protein coupling by treatment with pertussis toxin caused a 60% reduction in internalization of ligand. A combination of antimycin (50 nM) and deoxyglucose (50 mM) pretreatment, which leads to a depletion of cellular ATP, decreased internalization of [125I]-BIM-23027 by 66% of control and increased the proportion of surface-bound ligand. Hypertonic sucrose, which prevents clathrin-mediated endocytosis, reversibly abolished the internalization of ligand without increasing the proportion bound at the cell surface. 5. After internalization of [125I]-BIM-23027, approximately half of the ligand was recycled back to the extracellular medium within 20 min at 37 degrees C. This finding suggests that the intracellular content of [125I]-BIM-23027 reaches a steady state which is determined by the rates of both internalization and recycling of the ligand. In contrast to studies in which the internalization of [125I]-Tyr11-SRIF-14 was examined, neither internalized nor recycled [125I]-BIM-23027 was degraded to its component amino acids. 6. These findings indicate that the somatostatin agonist, [125I]-BIM-23027, is internalized in a receptor-dependent manner which involves clathrin-coated pits in Neuro2A cells. Furthermore, much of the internalized ligand is rapidly recycled back to the extracellular medium without undergoing significant degradation.

Secondary hyperalgesia to mechanical but not heat stimuli following a capsaicin injection in hairy skin

A psychophysical investigation was carried out to examine whether heat hyperalgesia exists within the secondary mechanical hyperalgesia zone surrounding a capsaicin injection site on hairy skin. A non-contact laser stimulator was used to deliver temperature controlled stimuli to sites within and outside the zone of mechanical hyperalgesia. Heat testing was carried out before and after the intradermal injection of 50 micrograms of capsaicin into the volar forearm. The zones of mechanical hyperalgesia to punctate and stroking stimuli and the region of flare were also mapped after the capsaicin injection. Heat pain thresholds inside the secondary mechanical hyperalgesic zone were not significantly different from thresholds outside the secondary mechanical hyperalgesia zone. In addition, pain ratings to an ascending series of heat stimuli delivered inside the zone of secondary hyperalgesia were not significantly different from pain ratings outside the zone of secondary hyperalgesia. Thus, there was no evidence for heat hyperalgesia within the zone of secondary hyperalgesia to punctate mechanical stimuli. Though the areas of punctate and stroking hyperalgesia were correlated, no correlation existed between the magnitude of capsaicin evoked pain and the areas mechanical hyperalgesia to punctuate and stroking stimuli or the area of flare. This suggests that independent mechanisms may mediate evoked pain, central sensitization that leads to mechanical hyperalgesia, and axon reflexive flare.

Inflammatory pain hypersensitivity mediated by phenotypic switch in myelinated primary sensory neurons

Pain is normally evoked only by stimuli that are sufficiently intense to activate high-threshold A(delta) and C sensory fibres, which relay the signal to the spinal cord. Peripheral inflammation leads to profoundly increased pain sensitivity: noxious stimuli generate a greater response and stimuli that are normally innocuous elicit pain. Inflammation increases the sensitivity of the peripheral terminals of A(delta) and C fibres at the site of inflammation. It also increases the excitability of spinal cord neurons, which now amplify all sensory inputs including the normally innocuous tactile stimuli that are conveyed by low-threshold A(beta) fibres. This central sensitization has been attributed to the enhanced activity of C fibres, which increase the excitability of their postsynaptic targets by releasing glutamate and the neuropeptide substance P. Here we show that inflammation results in A(beta) fibres also acquiring the capacity to increase the excitability of spinal cord neurons. This is due to a phenotypic switch in a subpopulation of these fibres so that they, like C-fibres, now express substance P. A(beta) fibres thus appear to contribute to inflammatory hypersensitivity by switching their phenotype to one resembling pain fibres, thereby enhancing synaptic transmission in the spinal cord and exaggerating the central response to innocuous stimuli.

Detection of naturally expressed receptors for gastrin-releasing peptide and tachykinins using cyanine 3-labelled neuropeptides

Peptides labelled with the fluorophore cyanine 3 were used to study naturally expressed neuropeptide receptors by confocal microscopy in continuous cell lines, primary cultures, and unfixed tissue. Swiss 3T3 fibroblasts bound cyanine 3-gastrin-releasing peptide at 4 degrees C, and internalized the peptide after 10 min at 37 degrees C. Internalization was specific, since it was blocked by incubation with unlabelled peptide. Primary cultures of myenteric neurons of the guinea pig incubated with cyanine 3-substance P at 4 degrees C had specific surface labelling. After 30 s at 37 degrees C, the peptide was internalized into vesicles in both the soma and neurites. Direct observation of live neurons showed movement of fluorescent vesicles to a perinuclear region after 30 min. Endocytosis was associated with a loss of surface binding sites. Unfixed whole mounts of guinea pig and rat ileum were incubated with cyanine 3-neurokinin A at 4 degrees C. After 5 min at 37 degrees C, Cy3-neurokinin A was specifically internalized in neurons and smooth muscle cells. After 30 min, a perinuclear labelling occurred in some cells. Labelling in rat neurons was diminished by the NK3-R antagonist SR142801. Thus, cyanine 3-neuropeptides are valuable tools to study expression and endocytosis of naturally expressed receptors.

Enhanced withdrawal responses to heat and mechanical stimuli following intraplantar injection of capsaicin in rats

Withdrawal responses to heat and mechanical stimuli applied to the plantar surface of the rat hindpaw were measured before and after an intraplantar injection of capsaicin. In separate groups of rats, capsaicin doses of 1, 10 and 30 micrograms, and the vehicle were given into the center of the plantar surface in a volume of 10 microliters. Withdrawal latency evoked by radiant heat and the frequency of withdrawal evoked by mechanical stimuli (von Frey monofilaments) were obtained from both hindpaws before and after injection. Hyperalgesia to heat was defined as a decrease in withdrawal latency and mechanical hyperalgesia was indicated by an increase in withdrawal response frequency. Intraplantar injection of capsaicin evoked nocifensive behavior characterized by lifting and guarding the injected paw which typically lasted up to 3 min following injection. Capsaicin produced a decrease in withdrawal latency to heat and increased the frequency of withdrawal to mechanical stimuli in a dose-dependent manner. These effects were observed on the injected paw only. The duration of hyperalgesia produced by capsaicin was also dose-dependent. Withdrawal latencies to heat were decreased up to 45 min following capsaicin while withdrawal responses to mechanical stimuli remained elevated up to 4 h. The area of mechanical hyperalgesia included most of the plantar surface and extended approximately 9 mm proximal and distal to the injection. Injection of the vehicle did not significantly alter withdrawal responses to heat or mechanical stimuli. These studies demonstrate that intraplantar injection of capsaicin in rats produces hyperalgesia to heat and mechanical stimuli. This model should be useful for correlative behavioral, physiological and pharmacological studies of underlying mechanisms of capsaicin-evoked hyperalgesia.

The spinal contribution of substance P to the generation and maintenance of inflammatory hyperalgesia in the rat

That substance P (SP) contributes in some way to spinal nociceptive processing has been known for many years. However, the contribution of SP and NK-1 receptors to the generation and maintenance of inflammatory hyperalgesia or persistent chemical hyperalgesia is not clear. The purpose of this study was to test the hypothesis that SP contributes to the generation but not maintenance of hyperalgesia using two models of inflammatory pain: carrageenan, which allows for testing of acute noxious thermal and mechanical stimuli, and formalin, a model of spontaneous pain. Intrathecal pretreatment with the NK-1 receptor antagonist CP-96,345 (100, 50, 25 nmol) dose-dependently attenuated the thermal (46%, 27% and 16%, respectively) and mechanical (66%, 37% and 3%, respectively) hyperalgesia produced by 2 mg carrageenan, but not 6 mg carrageenan, 3 h after the induction of inflammation. The attenuation was still apparent at 5 h for the greatest dose, but at 7 h the magnitude of hyperalgesia was equal to rats pretreated with saline. Posttreatment with 100 nmol CP-96,345 following the establishment of hyperalgesia had no effect. Intrathecal pretreatment with 125 nmol CP-96,345 prior to formalin (1% or 5%) injection into the hindpaw produced an overall 29% or 23% attenuation, respectively, of the nociceptive behavior during the 1-h observation period. For both 1% and 5% formalin injections, the phase 2 response, but not the phase 1 response, was significantly lower than that from rats pretreated both saline. Pretreatment with 100 or 125 nmol of the inactive enantiomer, CP-96,344, was no different than pretreatment with saline. A dose of 250 nmol CP-96,345 produced voluntary paralysis yet the flexion reflex to noxious pinch remained. These results support the hypothesis that SP contributes to the generation of inflammatory hyperalgesia but once established, the contribution of SP to maintaining the state of hyperalgesia is reduced. The interaction of SP, NK-1 receptors and spinal NMDA receptors in relation to inflammatory pain is discussed.

Agonist-selective endocytosis of mu opioid receptor by neurons in vivo

Opiate alkaloids are potent analgesics that exert multiple pharmacological effects in the nervous system by activating G protein-coupled receptors. Receptor internalization upon stimulation may be important for desensitization and resensitization, which affect cellular responsiveness to ligands. Here, we investigated the agonist-induced internalization of the mu opioid receptor (MOR) in vivo by using the guinea pig ileum as a model system and immunohistochemistry with an affinity-purified antibody to the C terminus of rat MOR. Antibody specificity was confirmed by the positive staining of human embryonic kidney 293 cells transfected with epitope-tagged MOR cDNA, by the lack of staining of cells transfected with the delta or kappa receptor cDNA, and by the abolition of staining when the MOR antibody was preadsorbed with the MOR peptide fragment. Abundant MOR immunoreactivity (MOR-IR) was localized to the cell body, dendrites, and axonal processes of myenteric neurons. Immunostaining was primarily confined to the plasma membrane of cell bodies and processes. Within 15 min of an intraperitoneal injection of the opiate agonist etorphine, intense MOR-IR was present in vesicle-like structures, which were identified as endosomes by confocal microscopy. At 30 min, MOR-IR was throughout the cytoplasm and in perinuclear vesicles. MOR-IR was still internalized at 120 min. Agonist-induced endocytosis was completely inhibited by the opiate antagonist naloxone. Interestingly, morphine, a high-affinity MOR agonist, did not cause detectable internalization, but it partially inhibited the etorphine-induced MOR endocytosis. These results demonstrate the occurrence of agonist-selective MOR endocytosis in neurons naturally expressing this receptor in vivo and suggest the existence of different mechanisms regulating cellular responsiveness to ligands.

Ultrastructural localization of D1 dopamine receptor immunoreactivity in rat striatonigral neurons and its relation with dopaminergic innervation

We have investigated by immunohistochemistry the cellular and subcellular distribution of the D1 dopamine receptor (D1R) in the rat striatonigral complex and its relation with the dopaminergic innervation. In the striatum, single pre-embedding immunoperoxidase and immunogold labeling demonstrate that D1R is mainly located on dendritic shafts and spines of spiny dendrites. D1R is also found in association with the plasma membrane of half of the perikarya of medium spiny neurons. Double labeling experiments allowing the simultaneous detection of D1R and of tyrosine hydroxylase (TH) demonstrate that D1R distribution does not match dopamine innervation: a majority of the receptors is located at sites distant from dopamine profiles and there is no significant D1R enrichment at sites of membrane appositions between dopamine and D1R profiles. In the substantia nigra, D1R is located at pre-synaptic sites on small diameter axons which are not in contact with TH-positive elements, and on terminal boutons forming symmetrical synapses on TH-positive or negative dendrites. These data demonstrate abundance and wide distribution of D1R at various extrasynaptic sites in the striatum and the substantia nigra, bringing strong evidence of anatomical basis for dopamine non-synaptic volume transmission in the rat striatonigral complex.

Localization of substance P NK-1 receptors in rat tongue

In rat tongue, neurons containing substance P terminate in connective tissue, in taste buds, and in lingual epithelium surrounding taste buds in fungiform, foliate and circumvallate papillae. Although many functions have been attributed to these neurons, virtually nothing is known about their physiological function. As a step towards this end, immunocytochemical methods were used to identify the NK-1 receptors (SPR) in rat tongue. SPR-IR was found in the basolateral membranes of taste cells in fungiform, circumvallate and foliate papillae. SPR-IR was not found in the dorsal epithelium or in any structure that could be clearly identified as a neuron. SPR-IR was also found in von Ebner's glands in circumvallate and foliate papillae and in blood vessels in connective tissue in all three papillae. These data suggest that substance P may play a role in taste and/or in oral pain.

Distribution and neurochemical character of substance P receptor (SPR)-immunoreactive striatal neurons of the macaque monkey: accumulation of SP fibers and SPR neurons and dendrites in "striocapsules" encircling striosomes

The striatal distribution of the substance P receptor (SPR) protein was examined in relation to its ligand, the neuro-peptide SP, as well as to the neurochemical and compartmental composition of the neostriatum in rhesus monkeys (Macaca mulatta) in immunohistochemical experiments. About 2% of striatal neurons, displaying varicose, virtually spine-free dendrites characteristic of large and medium-sized aspiny interneurons, expressed SPR immunoreactivity. SPR/choline acetyltransferase, SPR/somatostatin, SPR/GABA, SPR/calbindin D28k, and SPR/parvalbumin double immunolabeling experiments demonstrated that SPR-positive cells are either cholinergic or somatostatinergic. Comparison of SP and SPR immunoreactivities in double-labeled and adjacent single-labeled sections revealed compartment-specific match and mismatch between the densities of the peptide and receptor. A matching high density of SP fibers and SPR cells and dendrites was only observed in the rim of the striosome compartments. To our knowledge, this is the first evidence for an anatomical border comprised of dendritic processes that separate striatal compartments. We have termed these zones "striocapsules," because they encircle and encapsulate striosomal cell islands. In the striatal matrix, an abundance of SPR-labeled profiles was complemented with light SP staining. By contrast, in the core of the striosomes, SPR labeling was sparse and SP staining intense. SP-positive axon-like puncta frequently contacted SPR-positive dendrites in all striatal compartments. The SP receptor/ligand match indicates a sharp increase in the efficacy of SP action in the striocapsules, and suggests that the influence of SP might be heightened in this striatal subcompartment.

Vanilloid receptor loss is independent of the messenger plasticity that follows systemic resiniferatoxin administration

Resiniferatoxin (RTX) depletes vanilloid (capsaicin) receptors from lumbar dorsal root ganglia (DRG) of the rat. In addition, RTX causes changes in neuropeptide and nitric oxide synthase expression in lumbar DRG neurons, similar to those described following axotomy; this latter phenomenon is referred to as messenger plasticity. These findings suggested that vanilloid receptor loss may be part of the plasticity that follows RTX treatment. Here we show that vanilloid receptor expression, as detected by [3H]RTX autoradiography, is not changed in lumbar DRGs of axotomized rats, nor is it altered in a rat model (chronic constriction injury) of neuropathic pain. Thus, the in vivo expression of vanilloid receptors detected by specific [3H]RTX binding does not require the presence of intraaxonally transported trophic factors such as nerve growth factor. We conclude that messenger plasticity and vanilloid receptor loss are mediated by distinct mechanisms.

Differential expression of two isoforms of the neurokinin-1 (substance P) receptor in vivo

Recent pharmacological and biochemical studies have suggested that there may be more than one molecular form of the neurokinin-1 receptor (NK-1), a long and short isoform differing in the length of their cytoplasmic carboxyl-terminal tails, but no definitive evidence of the existence of such NK-1 receptor isoforms in tissue has been presented. To examine whether these different isoforms are expressed in vivo we have compared the distribution of high affinity substance P (SP) binding sites (visualized by autoradiography with [125I]SP), with the distribution of the C-terminal epitope of the full length receptor (visualized with a specific antibody against the extreme C-terminal sequence). The former method labels both long and short forms of the NK-1 receptor, while the latter labels only the long form of the protein. In the rat there is a close correspondence of [125I]SP binding and NK-1 immunoreactivity in the striatum, suggesting that the long isoform predominates in this tissue. In the parotid and submaxillary gland, there are very high levels of [125I]SP binding but only low levels of NK-1 immunoreactivity, suggesting that expression of the short form predominates in these tissues. These results imply that different tissues express different ratios of the two isoforms of the NK-1 receptor. This differential expression provides the theoretical basis for tissue specific pharmacological targeting of NK-1 receptors.

Neurokinin-1 receptors on lumbar spinothalamic neurons in the rat

In order to determine whether spinothalamic neurons in the lumbar spinal cord of the rat process neurokinin-1 (substance P) receptors, we injected cholera toxin B subunit into the thalamus and carried out dual-labelling immunocytochemistry to search for neurons that were immunoreactive with antibodies to cholera toxin and neurokinin-1 receptor. We examined 356 spinothalamic neurons in transverse sections and found that 35% of these were neurokinin-1 receptor-immunoreactive. Double-labelled cells made up the majority of the spinothalamic population in lamina I and the lateral spinal nucleus, and were also present in laminae III-V and the area around the central canal. On the side contralateral to the injection site, 77% of spinothalamic neurons in lamina I also showed neurokinin-1 receptor immunoreactivity, while 33% of those in laminae III-V and 14% of the ventromedial group possessed the receptor. Several of the double-labelled neurons with cell bodies in laminae III and IV had dendrites which could be followed dorsally into the superficial dorsal horn. These results indicate that substance P released from nociceptive primary afferents into the superficial dorsal horn is likely to act on spinothalamic tract neurons in lamina I, and also on those with cells bodies in laminae III-IV and long dorsal dendrites.

Beta-adrenergic receptors regulate astrogliosis and cell proliferation in the central nervous system in vivo

Astrocytes express several cell surface receptors including the beta 2 -adrenergic receptor. To explore whether beta-adrenergic receptors (beta-ARs) directly regulate astrogliosis and glial scar formation, we evaluated the effects of beta-AR activation and blockade on astrocyte hypertrophy and cell proliferation in rabbit optic nerves in vivo. Artificial cerebrospinal fluid (CSF), isoproterenol (ISO; a beta-agonist), or propranolol (PROP; a beta-antagonist) were infused via osmotic minipumps into non-injured and crushed optic nerves for 14 days. Changes in nerve cell numbers and astroglial hypertrophy were monitored by ethidium bromide nuclear staining and glial fibrillary acidic protein (GFAP) immunohistochemistry, respectively. In non-injured nerves infused with CSF or PROP, there were no alterations in GFAP-immunoreactivity or cell numbers compared to normal optic nerves; however, in non-injured nerves infused with ISO, there was a significant increase in both GFAP-immunoreactivity and cell number. In crushed optic nerves, there was a significant increase in both GFAP-immunoreactivity and cell number compared to normal nerves, and this increase was not altered by infusion of either CSF or ISO. In contrast, PROP infusion significantly reduced the crush-induced increase in GFAP-immunofluorescence and cell number. These findings suggest that a) beta-AR activation, in the absence of injury, can promote astroglial hypertrophy and cell proliferation; b) after injury, beta-AR activation drives injury-induced astrogliosis and cell proliferation; c) astrocyte beta-ARs are maximally stimulated after neuronal injury; and d) neuronal regeneration may be influenced, both positively and negatively, through the pharmacological manipulation of glial receptors.

What are the roles of substance P and neurokinin-1 receptors in the control of negative chronotropic or negative dromotropic vagal motoneurons? A physiological and ultrastructural analysis

Recent data indicate that there is a cardiotopic organization of negative chronotropic and negative dromotropic neurons in the nucleus ambiguus (NA). Negative dromotropic neurons are found in the rostral ventrolateral NA (rNA-VL), negative chronotropic neurons are found in the caudal ventrolateral NA (cNA-VL), and both types of neurons are found in an intermediate level of the ventrolateral NA (iNA-VL). Substance P (SP) immunoreactive nerve terminals synapse upon negative chronotropic vagal motoneurons in the iNA-VL, and SP microinjections in the NA cause bradycardia. In the present report we have attempted to: (1) define the type of tachykinin receptor which mediates the negative chronotropic effect of SP microinjections into the iNA-VL; (2) define the physiological effect of microinjections of a selective SP agonist into the rNA-VL on atrioventricular (AV) conduction: and (3) find ultrastructural evidence for synaptic interactions of SP-immunoreactive nerve terminals with negative dromotropic vagal motoneurons in the rNA-VL. Microinjections of the excitatory amino acid glutamate (Glu) into the iNA-VL to activate all local vagal preganglionic neurons caused both bradycardia and a decrease in the rate of AV conduction. Injections of the selective neurokinin-1 (NK-1) receptor agonist drug GR-73632 also caused bradycardia, however the rapid onset of agonist induced desensitization prevented an evaluation of potential effects on AV conduction in the iNA-VL. These data suggest that the SP-induced bradycardia which can be elicited from the NA is mediated, at least in part, by NK-1 receptors. Microinjections of Glu into the rNA-VL caused a decrease in AV conduction without an effect on cardiac rate. On the other hand, GR-73632 microinjections into rNA-VL did not affect AV conduction. Following injections of the beta subunit of cholera toxin conjugated to horseradish peroxidase (CTB-HRP) into the left atrial fat pad ganglion which selectively mediates changes in AV conduction, retrogradely labeled neurons were histochemically visualized in the rNA-VL. These tissues were subsequently processed for the simultaneous immunocytochemical visualization of SP, and examined by electron microscopy. Histochemically labeled neurons were large, multipolar, with abundant cytoplasm containing large masses of rough endoplasmic reticulum, and exhibited distinctive dendritic and somatic spines. Unlabeled nerve terminals were noted to form either asymmetric or symmetric synapses with dendrites, dendritic spines, and perikarya of histochemically labeled neurons. SP-immunoreactive nerve terminals were also detected in the rNA-VL. SP terminals typically contained numerous small pleomorphic vesicles, multiple large dense core vesicles, and several mitochondria, and they synapsed upon unlabeled dendritic profiles. A total of 154 SP-immunoreactive nerve terminals were observed on photomicrographs of tissues which also contained histochemically labeled profiles. None made an identifiable synapse with a retrogradely labeled profile on the sections examined. In summary, both physiological and ultrastructural data indicate that SP terminals in the iNA-VL do modify the output of negative chronotropic vagal motoneurons. This effect is mediated by NK-1 receptors. On the other hand both physiological and ultrastructural data indicate that SP terminals in the rNA-VL do not modify the output of negative dromotropic vagal motoneurons. Therefore different mechanisms (neurotransmitters or receptors) mediate the central vagal control of cardiac rate and AV conduction.

Origin of beading constrictions at the axolemma: presence in unmyelinated axons and after beta,beta'-iminodipropionitrile degradation of the cytoskeleton

Myelinated nerve fibres become beaded when nerves are subjected to a mild stretch; the beading is seen as varicosities, a series of alternating constrictions and enlargements, when using freeze-substitution or cold-fixation to hold this labile form change in place during fixation. One possibility for how this form change comes about is that the myelin sheath or its Schwann cell initiates beading. We now report, however, that a similar beading is seen in the axons of unmyelinated fibres. In electron micrographs, longitudinal sections of axons show the series of constrictions and expansions typical of beading. In cross-sections, axons with unusually small diameter, corresponding to the constrictions, are seen to contain closely packed microtubules and neurofilaments while neighbouring swollen axons with widely dispersed microtubules correspond to the beading expansions. Another possibility for the form change is that the cytoskeleton is responsible for beading. We discovered that direct exposure of nerves to beta, beta'-iminodipropionitrile in vitro for 1-6 h causes both axonal microtubules and neurofilaments to become degraded and replaced by an amorphous residue. Nevertheless, beta,beta'-iminodipropionitrile-treated nerves show constrictions in myelinated fibres when stretched. An even greater degree of beading with narrower and longer constrictions appears in some fibres, with the expanded regions having oblate ends giving the appearance of a string of sausages. In cross-sections taken through the constrictions, a greater than usual reduction of axonal area was seen, this was due to the loss of cytoskeletal organelles which would act to limit the degree of constriction. With longer exposure to beta, beta'-iminodipropinitrile more fibres show complete degeneration of the cytoskeleton and form ovoids typical of Wallerian degeneration. Unmyelinated axons of beta, beta'-iminodipropionitrile-treated nerves which showed degeneration of their cytoskeleton with its replacement by amorphous material still demonstrated beading. As neither the myelin sheath nor the intact cytoskeleton within the axon is necessary for beading, by exclusion, we consider beading constrictions to be initiated at the level of the axolemma. In our hypothesis the membrane skeleton is responsible; namely, the spectrin, actin and other molecular species lining the inside of the axolemma and binding to transmembrane proteins. The membrane skeleton may be activated by stretch via transmembrane proteins (e.g. beta 1-integrins). The membrane skeleton mechanism may also be directly engaged in the production of Wallerian degeneration or be induced by neurotoxic agents.

Spinal cord substance P receptor immunoreactivity increases in both inflammatory and nerve injury models of persistent pain

Numerous studies have implicated the primary afferent derived neuropeptide, substance P, which exerts its effects via the neurokinin-1/substance P receptor, in the transmission of nociceptive messages at the level of the spinal cord. Immunocytochemical studies demonstrate that the substance P receptor is concentrated in neurons of lamina I of the superficial dorsal horn. Since alterations in the number and distribution of the receptor may underlie persistent pain conditions, we have used immunocytochemistry to study the distribution of the receptor in two very different rat models of persistent pain: chronic inflammation, which is associated with increased levels of substance P, and sciatic nerve section, which is associated with decreased levels of substance P in the dorsal horn. Inflammation was produced by unilateral hindpaw injection of complete Freund's adjuvant. We report that there is an up-regulation of substance P receptor immunoreactivity in the superficial laminae of the dorsal horn in both injury models. The increase was found at all time points studied (up to one week after induction of inflammation and up to two weeks after sciatic nerve section). The increase in substance P receptor immunoreactivity was not only present in the medial part of the dorsal horn at segment L4, which is the region of input of the afferents from the hindpaw, but also in the lateral parts of the dorsal horn, and at segments rostral (L1) and caudal (S1) to the afferent input from the hindpaw. These results indicate that the up-regulation of the receptor is not predictable merely by the change in the concentration of substance P in the dorsal horn. Furthermore, the non-topographic up-regulation of substance P receptor in these different conditions may contribute to the central sensitization of dorsal horn nociceptors under conditions of persistent pain.

Differential expression of substance P receptors in patients with Crohn's disease and ulcerative colitis

BACKGROUND & AIMS

Although clinical and pathological differences exist between Crohn's disease (CD) and ulcerative colitis (UC), distinguishing features are often absent, making diagnosis and treatment problematic. This study evaluated the differences in the expression of substance P (SP) receptors in patients with CD or UC.

METHODS

Tissue samples from patients with inflammatory bowel disease or control patients were obtained at surgery, processed for 125I-SP binding, and analyzed by quantitative autoradiography.

RESULTS

Patients with CD showed a massive increase in SP receptors in lymphoid aggregates, small blood vessels, and enteric neurons of the small and large bowel relative to controls. Six of 16 CD specimens had no pathological evidence of CD yet continued to express high concentrations of SP receptors. Pathologically positive patients with UC showed high concentrations of SP receptors on colonic lymphoid aggregates and small blood vessels but not enteric neurons. No increased SP binding was evident in clinically and pathologically quiescent UC colons and normal UC ileostomy samples.

CONCLUSIONS

The increased expression of SP receptors on the enteric neurons of patients with CD distinguishes CD from UC. The persistent increased SP binding in pathologically normal CD tissue may indicate a subclinical disease state. SP receptor expression may have important diagnostic, etiologic, and therapeutic usefulness in inflammatory bowel disease.

Long-term potentiation. The cell biology connection

The relative importance of pre- and post-synaptic mechanisms in long-term potentiation has been controversial; a cell-biological approach has now provided strong evidence for the involvement of pre-synaptic mechanisms.