Localization of enkephalin immunoreactivity in the spinal cord of the long-tailed ray Himantura fai

Enkephalin-like immunoreactivity (ENK-LI) was found throughout the spinal cord of the long-tailed ray Himantura fai. The densest ENK-LI was in the superficial portion of lamina A of the dorsal horn. Lamina B and the deeper parts of lamina A contained radially oriented, labelled fibres. Laminae C, D, and E contained many longitudinally orientated fascicles which were surrounded by a reticulum of transversely orientated, labelled fibres, some of which projected into the ventral and lateral funiculi. Labelled fibres were found in the dorsal commissure and around the central canal, but the later did not cross the midline. One-third of all enkephalinergic cells were found throughout laminae A and B, while two-thirds were located in the medial half of C, D, and E. Occasionally a labelled cell was located in the lateral funiculus. The ventral horn (laminae F and G) contained many enkephalinergic fibres but no labelled nuclei. A few dorsal column axons contained ENK-LI. In the lateral funiculus there were two groups of labelled axons, a superficial, dorsolateral group, and a deeper group, occupying a crescent-shaped region. The ventral funiculus also contained many labelled axons. The central projection of the dorsal root passed through the substantia gelatinosa and divided into rostrally and caudally projecting fascicles within lamina C. The root, and these fascicles, both lacked ENK-LI. In contrast, the fascicles in laminae D and E did contain enkephalinergic fibres. The origin of the various fibre systems and the role of enkephalin in the regulation of sensory processing and motor output are discussed. © 1996 Wiley-Liss, Inc.     

Somatotopic organization of single primary afferent axon projections to cat spinal cord dorsal horn.

Horseradish peroxidase injection of identified low threshold cutaneous mechanoreceptor (LTCM) primary afferent axons was used to assess the somatotopic organization of hindlimb projections to laminae III and IV of cat dorsal horn. Multiple injections in the same animals were used to assess bilateral symmetry and precision. Thirty-one axons were injected, with more than 1 axon injected in each of 8 animals (25 axons). Somatotopic relations between their receptive field (RF) centers and the centers of their dorsal horn projections were similar to the somatotopic relations between dorsal horn cell RF centers and cell locations. Very few reversals of mediolateral somatotopic gradients (proximodistal RF location as a function of mediolateral projection center) were observed. Two afferents with nearly identical RFs in 1 animal had nearly identical projections. These observations held for many different combinations of receptor types. A simple mathematical model was used to demonstrate that assembly of dorsal horn cell RFs via passive sampling of the presynaptic neuropil by dorsal horn cell dendrites cannot account for the sizes of dorsal horn cell LTCM RFs. Hypothesized mechanisms for assembly of dorsal horn cell RFs must take into account the functional selectivity of connections required to produce RFs smaller than those predicted by the passive assembly model.     

Dorsal root projections to dorsal horn neurons in the cat spinal cord

The projection of dorsal root fibers to the dorsal horn of the spinal cord of the cat has been studied by electron microscopy. Two distinct types of synaptic degeneration are seen with the electron microscope: small knobs which exhibit a marked increase in electron density, and large knobs which fill with neurofilaments. Variations in the distribution of degenerating knobs to the six laminae of the dorsal horn are observed: dense degenerating knobs are found throughout the horn, but are quite rare in laminae I and II. Lamina III exhibits the most dense knobs, and a great many are also present in laminae IV and VI with a somewhat lesser number seen in lamina V. Knobs undergoing neurofilamentous degeneration are found only in laminae V and VI, and are much Jess frequently seen than are dense knobs. The types of synaptic contacts made by degenerating dorsal root fibers also vary from one region of the dorsal horn to another. Dense degenerating knobs synapse primarily with small dendrites in laminae I, II and III, but not at all with large dendrites or nerve cell bodies. In lamina III, dense knobs are seen in axoaxonal synapses, and are always the pre-synaptic component of the synapse. In laminae IV, V and VI dark knobs are commonly seen to synapse upon cell bodies of large and medium sized neurons and their proximal dendrites, but not upon small cell bodies Dense knobs upon small dendrites are common. In degenerating axoaxonal synapses, the dense knob is always the post-synaptic component. Degenerating neurofibrillar knobs are only seen to synapse with cell bodies or larger dendrites in V and VI and not at all other synaptic knobs. The results are correlated with findings by light microscopy. Comparisons are made with some of the known physiological properties of dorsal horn neurons.     

Comparative localization of colorectal sensory afferent central projections in the mouse spinal cord dorsal horn and caudal medulla dorsal vagal complex

The distal colon and rectum (colorectum) are innervated by spinal and vagal afferent pathways. The central circuits into which vagal and spinal afferents relay colorectal nociceptive information remain to be comparatively assessed. To address this, regional colorectal retrograde tracing and colorectal distension (CRD)-evoked neuronal activation were used to compare the circuits within the dorsal vagal complex (DVC) and dorsal horn (thoracolumbar [TL] and lumbosacral [LS] spinal levels) into which vagal and spinal colorectal afferents project. Vagal afferent projections were observed in the nucleus tractus solitarius (NTS), area postrema (AP), and dorsal motor nucleus of the vagus (DMV), labeled from the rostral colorectum. In the NTS, projections were opposed to catecholamine and pontine parabrachial nuclei (PbN)-projecting neurons. Spinal afferent projections were labeled from rostral through to caudal aspects of the colorectum. In the dorsal horn, the number of neurons activated by CRD was linked to pressure intensity, unlike in the DVC. In the NTS, 13% ± 0.6% of CRD-activated neurons projected to the PbN. In the dorsal horn, at the TL spinal level, afferent input was associated with PbN-projecting neurons in lamina I (LI), with 63% ± 3.15% of CRD-activated neurons in LI projecting to the PbN. On the other hand, at the LS spinal level, only 18% ± 0.6% of CRD-activated neurons in LI projected to the PbN. The collective data identify differences in the central neuroanatomy that support the disparate roles of vagal and spinal afferent signaling in the facilitation and modulation of colorectal nociceptive responses.     

Noradrenergic inhibition of the release of substance P from the primary afferents in the rabbit spinal dorsal horn

To investigate pre-synaptic influence of the descending noradrenergic system on the primary afferents containing substance P (SP), effects of noradrenergic manipulations on the in situ release of immunoreactive SP (iSP) from the dorsal horn were examined in the thalamic rabbit. Local application of noradrenaline (10 microM) to the dorsal horn produced complete inhibition of the noxious mechanical stimuli-evoked release of iSP. This effect was reversed by yohimbine (the more selective alpha 2-blocker, 10 microM) and partially antagonized by prazosin (the more selective alpha 1-blocker, 10 microM). The resting release of iSP was not affected by noradrenaline. The noxious mechanical stimuli-evoked release of iSP was significantly increased by acute spinal transection and local application of yohimbine (10 microM) alone to the dorsal horn. Prazosin (10 microM) slightly increased the evoked iSP release, and a beta-blocker metoprolol did not affect it. These results suggest that the nociceptive primary afferents containing SP are tonically inhibited by the descending noradrenergic system linked to alpha-adrenoceptors, and that such alpha-adrenoceptors located on the primary afferent terminals may be one of the sites of action of noradrenaline spinal analgesia. In contrast to the evoked iSP release, the resting iSP release was increased only by acute spinal transection and not by yohimbine, prazosin and metoprolol. All these observations suggest that tonic inhibition in propriospinal neurons containing SP is mediated by a non-noradrenergic system.     

Selective distribution of GABA(A) receptor subtypes in mouse spinal dorsal horn neurons and primary afferents

In the spinal cord dorsal horn, presynaptic GABA_A receptors (GABA_ARs) in the terminals of nociceptors as well as postsynaptic receptors in spinal neurons regulate the transmission of nociceptive and somatosensory signals from the periphery. GABA_ARs are heterogeneous and distinguished functionally and pharmacologically by the type of α subunit variant they contain. This heterogeneity raises the possibility that GABA_AR subtypes differentially regulate specific pain modalities. Here, we characterized the subcellular distribution of GABA_AR subtypes in nociceptive circuits by using immunohistochemistry with subunit‐specific antibodies combined with markers of primary afferents and dorsal horn neurons. Confocal laser scanning microscopy analysis revealed a distinct, partially overlapping laminar distribution of α1–3 and α5 subunit immunoreactivity in laminae I–V. Likewise, a layer‐specific pattern was evident for their distribution among glutamatergic, γ‐aminobutyric acid (GABA)ergic, and glycinergic neurons (detected in transgenic mice expressing vesicular glutamate transporter 2–enhanced green fluorescent protein [vGluT2–eGFP], glutamic acid decarboxylase [GAD]67–eGFP, and glycine transporter 2 (GlyT2)–eGFP, respectively). Finally, all four subunits could be detected within primary afferent terminals. C‐fibers predominantly contained either α2 or α3 subunit immunoreactivity; terminals from myelinated (Aβ/Aδ) fibers were colabeled in roughly equal proportion with each subunit. The presence of axoaxonic GABAergic synapses was determined by costaining with gephyrin and vesicular inhibitory amino acid transporter to label GABAergic postsynaptic densities and terminals, respectively. Colocalization of the α2 or α3 subunit with these markers was observed in a subset of C‐fiber synapses. Furthermore, gephyrin mRNA and protein expression was detected in dorsal root ganglia. Collectively, these results show that differential GABA_AR distribution in primary afferent terminals and dorsal horn neurons allows for multiple, circuit‐specific modes of regulation of nociceptive circuits. J. Comp. Neurol. 520:3895–3911, 2012. © 2012 Wiley Periodicals, Inc.     

Expression of transient receptor potential ankyrin 1 (TRPA1) in the rat trigeminal sensory afferents and spinal dorsal horn

Transient receptor potential ankyrin 1 (TRPA1), responding to noxious cold and pungent compounds, is implicated in the mediation of nociception, but little is known about the processing of the TRPA1‐mediated nociceptive information within the trigeminal sensory nuclei (TSN) and the spinal dorsal horn (DH). To address this issue, we characterized the TRPA1‐positive (+) neurons in the trigeminal ganglion (TG) and investigated the distribution of TRPA1⁺ afferent fibers and their synaptic connectivity within the rat TSN and DH by using light and electron microscopic immunohistochemistry. In the TG, TRPA1 was expressed in unmyelinated and small myelinated axons and also occasionally in large myelinated axons. Many TRPA1⁺ neurons costained for the marker for peptidergic neurons substance P (26.8%) or the marker for nonpeptidergic neurons IB4 (44.5%). In the CNS, small numbers of axons and terminals were immunopositive for TRPA1 throughout the rostral TSN, in contrast to the dense network of positive fibers and terminals in the superficial laminae of the trigeminal caudal nucleus (Vc) and DH. The TRPA1⁺ terminals contained clear round vesicles, were presynaptic to one or two dendrites, and rarely participated in axoaxonic contacts, suggesting involvement in relatively simple synaptic circuitry with a small degree of synaptic divergence and little presynaptic modulation. Immunoreactivity for TRPA1 was also occasionally observed in postsynaptic dendrites. These results suggest that TRPA1‐dependent orofacial and spinal nociceptive input is processed mainly in the superficial laminae of the Vc and DH in a specific manner and may be processed differently between the rostral TSN and Vc. J. Comp. Neurol. 518:687–698, 2010. © 2009 Wiley‐Liss, Inc.     

Long ascending projections of the spinal dorsal horn in a teleost, Sebastiscus marmoratus

Ascending projections of the spinal cord in a teleost, Sebastiscus marmoratus, were studied by means of the horseradish peroxidase tracing method. Projecting fibers were observed in the reticular formation, vagal lobe, octaval nuclei, a dorsomedial portion of the descending nucleus of the trigeminal nerve, corpus cerebelli and nucleus ventromedialis thalami.     

Complex effects of general anesthesia on sensory processing in the spinal dorsal horn

A chronic animal preparation allowed us to compare activity of the same single, spinal dorsal horn neurons in the physiologically intact, awake, drug-free state and in the anesthetized state. The inhalation anesthetic enflurane produced profound, and at times, opposite effects on spinal dorsal horn neuron responses to non-noxious and noxious receptive field stimulation. Some effects would not have been predicted, based upon current understanding of anesthetics.     

Central distribution of cervical primary afferents in the rat, with emphasis on proprioceptive projections to vestibular, perihypoglossal, and upper thoracic spinal nuclei

The projections of primary afferents from rostral cervical segments to the brainstem and the spinal cord of the rat were investigated by using anterograde and transganglionic transport techniques. Projections from whole spinal ganglia were compared with those from single nerves carrying only exteroceptive or proprioceptive fibers. Injections of horseradish peroxidase (HRP) or wheat germ agglutinin-horseradish peroxidase conjugate (WGA-HRP) were performed into dorsal root ganglia C2, C3, and C4. Free HRP was applied to the cut dorsal rami C2 and C3, greater occipital nerve, sternomastoid nerve, and to the C1/2 anastomosis, which contains afferents from suboccipital muscles and the atlanto-occipital joint. WGA-HRP injections into ganglia C7 and L5 were performed for comparative purposes. Injections of WGA-HRP or free HRP into rostral cervical dorsal root ganglia and HRP application to C2 and C3 dorsal rami produced labeling in dorsal and ventral horns at the level of entrance, the central cervical nucleus, and in external and main cuneate nuclei. From axons ascending to pontine and descending to upper thoracic spinal levels, medial collaterals were distributed to medial and descending vestibular, perihypoglossal and solitary nuclei, and the intermediate zone and Clarke's nucleus dorsalis in the spinal cord. Lateral collaterals projected mainly to the trigeminal subnucleus interpolaris and to lateral spinal laminae IV and V. Results from HRP application to single peripheral nerves indicated that medial collaterals were almost exclusively proprioceptive, whereas lateral collaterals were largely exteroceptive with a contribution from suboccipital proprioceptive fibers. WGA-HRP injections into dorsal root ganglia C7 and L5 failed to produce significant labeling within vestibular and periphypoglossal nuclei, although they demonstrated classical projection sites within the brainstem and spinal cord. The consistent collateralisation pattern of rostral cervical afferents along their whole rostrocaudal course enables them to contact a variety of precerebellar, vestibulospinal, and preoculomotor neurons. These connections reflect the well-known significance of proprioceptive neck afferents for the control of posture, head position, and eye movements.     

Acute and chronic changes in dorsal horn innervation by primary afferents and descending supraspinal pathways after spinal cord injury

Sprouting of peptidergic nociceptive and descending supraspinal projections to the dorsal horn following spinal cord injury (SCI) has been proposed as a mechanism of neuropathic pain. To identify structural changes that could initiate or maintain SCI pain, we used a complete transection model in rats to examine how structural remodeling in the dorsal horn rostral to the lesion relates to distance from injury, laminar region, and duration of injury. The major classes of C-fiber primary afferents differed greatly in their susceptibility to structural and chemical changes and their ability to undergo plasticity. Peptidergic primary afferents showed a widespread loss throughout the dorsal horn of segments approaching the injury site. Some of this loss may have been due to decreased neuropeptide expression. The reduction in peptidergic fibers was transient, indicating compensatory sprouting and perhaps also increased neuropeptide expression within the cord. Nonpeptidergic afferents expressing GFRalpha1 were largely unaffected by SCI. In contrast, in GFRalpha2-expressing nonpeptidergic afferents SCI caused a permanent loss of dorsal horn innervation. Unexpectedly, GFRalpha2 was transiently induced throughout deeper laminae but this was not due to upregulation of GFRalpha2 in dorsal root ganglia. We also observed permanent sprouting of catecholamine terminals of supraspinal origin. This was restricted to the superficial laminae. Our results show that SCI caused a loss of sensory input as well as structural remodeling such that the balance of nociceptive inputs and descending modulation was permanently altered. These changes may contribute to mechanisms rostral to the site of SCI that trigger and maintain neuropathic pain.     

Choline acetyltransferase-immunoreactive profiles are presynaptic to primary sensory fibers in the rat superficial dorsal horn

The specific aim of this study was to search for morphological counterparts to the known antinociceptive effects of cholinomimetic drugs at the spinal cord level. For this, the light microscopic and ultrastructural distribution of choline acetyltransferase immunoreactivity was studied in laminae I-III of the rat cervical spinal cord. Immunoreactivity was present in cell bodies in lamina III, and in dendrites and axons of all three laminae. Immunoreactive axonal varicosities were often presynaptic to the central varicosities of type II synaptic glomeruli in lamina II and lamina III, less often presynaptic to the central elements of type I glomeruli in lamina II, and often presynaptic to dendrites in both type I and type II glomeruli. In addition, immunoreactive dendrites were often postsynaptic to the central varicosities of glomeruli of all morphological types. These results indicate that 1) primary sensory fibers excite cholinergic interneurons; 2) the acetylcholine released by the axon terminals of these interneurons modulates both nociceptive and non-nociceptive sensory information at the spinal cord level through both pre- and postsynaptic mechanisms. Furthermore, our results reinforce current ideas on reciprocal sensory interaction between thick and fine afferent fibers.     

Depletion of GDNF from primary afferents in adult rat dorsal horn following peripheral axotomy

Glial cell line-derived neurotrophic factor (GDNF) is produced in a subset of adult rat spinal ganglion neurons and anterogradely transported to the superficial dorsal horn. In this study the effect of sciatic nerve axotomy on the expression of GDNF protein in the dorsal horn was investigated, using immunocytochemistry. Image analysis showed a 44% decrease relative to the non-transected side after 5 days survival, progressing to more than 80% decrease after 10 days and remaining so for at least 100 days. This rapid and strong decrease suggests active down-regulation of GDNF protein after peripheral axotomy. The observed down-regulation of GDNF is compared with changes observed for other substances in primary afferents after peripheral axotomy and is discussed in light of its presumed trophic or transmitter role in nociception.     

Synaptic connectivity of urinary bladder afferents in the rat superficial dorsal horn and spinal parasympathetic nucleus

That visceral sensory afferents are functionally distinct from their somatic analogues has been known for a long time but the detailed knowledge of their synaptic connections and neurotransmitters at the first relay nucleus in the spinal cord has been limited. To provide information on these topics, we investigated the synapses and neurotransmitters of identified afferents from the urinary bladder to the superficial laminae of the rat spinal dorsal horn (DH) and the spinal parasympathetic nucleus (SPN) by tracing with horseradish peroxidase, quantitative electron microscopical analysis, and immunogold staining for GABA and glycine. In the DH, most bladder afferent boutons formed synapses with 1–2 postsynaptic dendrites, whereas in the SPN, close to a half of them formed synapses with 3–8 postsynaptic dendrites. The number of postsynaptic dendrites and dendritic spines per bladder afferent bouton, both measures of synaptic divergence and of potential for synaptic plasticity at a single bouton level, were significantly higher in the SPN than in the DH. Bladder afferent boutons frequently received inhibitory axoaxonic synapses from presynaptic endings in the DH but rarely in the SPN. The presynaptic endings were GABA- and/or glycine-immunopositive. The bouton volume, mitochondrial volume, and active zone area, all determinants of synaptic strength, of the bladder afferent boutons were positively correlated with the number of postsynaptic dendrites. These findings suggest that visceral sensory information conveyed via the urinary bladder afferents is processed differently in the DH than in the SPN, and differently from the way somatosensory information is processed in the spinal cord.     

Reorganization of central terminals of myelinated primary afferents in the rat dorsal horn following peripheral axotomy

We have investigated the time course and extent to which peripheral nerve lesions cause a morphological reorganization of the central terminals of choleragenoid-horseradish peroxidase (B-HRP)-labelled primary afferent fibers in the mammalian dorsal horn. Choleragenoid horseradish peroxidase is retrogradely transported by myelinated (A) sensory axons to laminae I, III, IV and V of the normal dorsal horn of the spinal cord, leaving lamina II unlabelled. We previously showed that peripheral axotomy results in the sprouting of numerous B-HRP labelled large myelinated sensory axons into lamina II. We show here that this spread of B-HRP-labelled axons into lamina II is detectable at 1 week, maximal by 2 weeks and persists for over 6 months postlesion. By 9 months, however, B-HRP fibers no longer appear in lamina II. The sprouting into lamina II occurs whether regeneration is allowed (crush) or prevented (section with ligation), and does not reverse at times when peripheral fibers reinnervate the periphery. We also show that 15 times more synaptic terminals in lamina II are labelled by B-HRP 2 weeks after axotomy than in the normal. We interpret this as indicating that the sprouting fibers are making synaptic contacts with postsynaptic targets. This implies that A-fiber terminal reorganization is a prominent and long-lasting but not permanent feature of peripheral axotomy. We also provide evidence that this sprouting is the consequence of a combination of an atrophic loss of central synaptic terminals and the conditioning of the sensory neurons by peripheral axotomy. The sprouting of large sensory fibers into the spinal territory where postsynaptic targets usually receive only small afferent fiber input may bear on the intractable touch-evoked pain that can follow nerve injury. © 1995 Wiley-Liss, Inc.     

Ultrastructural analysis of medial brain stem afferents to the superficial dorsal horn

Axonal projections of medial brain stem areas rich in serotonin-containing neurons were identified in layers I and II of cat medullary dorsal horn using EM autoradiography. Following [³H]amino acid injections into the brain stem, labeled axonal endings were found throughout layers I and II but were most numerous in layer I. Three different morphological types of endings could be distinguished. Each type resembled serotonergic axonal endings identified in previous experiments. The labeled endings formed both symmetrical and asymmetrical synapses on dendritic shafts and spines and occasionally on a neuronal soma suggesting that the major site of action of the descending serotonergic afferents is on the neurons in layers I and II.     

Peripheral nerve injury induces reorganization of galanin-containing afferents in the superficial dorsal horn of monkey spinal cord

Peripheral nerve injury-induced structural and chemical modifications of the sensory circuits in the dorsal horn of the spinal cord contribute to the mechanism of neuropathic pain. In contrast to the topographic projection of primary afferents in laminae I-IV in the rat spinal cord, the primary afferents of Macaca mulatta monkeys almost exclusively project into laminae I-II of the spinal cord. After peripheral nerve injury, up-regulation of galanin has been found in sensory neurons in both monkey and rat dorsal root ganglia. However, the nerve injury-induced ultrastructural modification of galanin-containing afferents in the monkey spinal cord remains unknown. Using immunoelectron microscopy, we found that 3 weeks after unilateral sciatic nerve transection, the number of galanin-containing afferents was increased in ipsilateral lamina II of monkey spinal cord. Branching of these galanin-positive afferents was often observed. The afferent terminals contained a large number of synaptic vesicles, peptidergic vesicles and mitochondria, whereas the number of synapses was markedly reduced. Some of the afferents-enriched microtubules were often packed into bundles. Moreover, galanin-labeling could be associated with endosomal structures in many dendrites and axonal terminals of dorsal horn neurons. These results suggest that peripheral nerve injury induces an expansion of the central projection of galanin-containing afferents in lamina II of the monkey spinal cord, not only by increasing galanin levels in primary afferents but also by triggering afferent branching.     

Ascending projections from marginal zone (Lamina I) neurons of the spinal dorsal horn

A search for postsynaptic elements, excited only by slowly-conducting afferent fibers (Aδ and C), was made by recording from the dorsal horn of cats and monkeys with dye-filled microelectrodes. Units identified by afferent responsiveness were tested for antidromic invasion by electrical stimulation of the opposite ventrolateral funiculus at the midcervical level. Recording points were marked by iontophoretically passing dye from the recording electrode and subsequently located in histologically-prepared material. Evidence for antidromic excitation from spinal cord stimulation was found for five of 21 units in cat and 13 of 31 neurons in monkey. Antidromically excited cells were located within the distribution of the large posteromarginal neurons of the dorsal marginal zone (Lamina I). Although recording loci for a number of the elements studied were unequivocally located within Laminae II (substantia gelatinosa) or III, none could be antidromically excited. All antidromically driven units received a powerful input from Aδ primary afferent units and upon testing with natural stimuli responded specifically to stimuli of the type initiating activity either for high threshold mechanoreceptors or for low threshold thermoreceptors. It is concluded that some Lamina I neurons form part of an ascending projection which follows the spinal pathway of the spinothalamic tract and thereby contribute to the mechanical nociceptive and thermoreceptive features of this pathway. The absence of antidromic response is argued to be uncertain and evidence for a lack of projection is open to alternative explanation.