Neuropeptidergic regulation of bone resorption and bone formation

Immunohistochemical studies have revealed an extensive network of nerve fibers in the vicinity and within the skeleton, not only in the periosteum of bone but also in cortical and trabecular bone as well as in the bone marrow. Phenotyping of the skeletal nerve fibers have demonstrated the expression of a restrictive panel of different signalling molecules including neuropeptides, neurotransmitters and neurotrophins. In this review, the presence of receptors for the neuropeptides vasoactive intestinal peptide, calcitonin gene-related peptide and substance P on osteoblasts and osteoclasts and the capacity of these receptors to regulate bone formation, osteoclast formation and activity are described. These findings, together with data obtained by chemically and surgically targeted nerve deletion and observations made in paraplegic patients, strongly suggest that neuro-osteogenic interactions play an important role in skeletal function.     

Osteotropic effects by the neuropeptides calcitonin gene-related peptide, substance P and vasoactive intestinal peptide

Immunohistochemical phenotypic characterization of skeletal nerve fibers has demonstrated the expression of a restricted number of neuropeptides, including calcitonin gene-related peptide (CGRP), substance P (SP) and vasoactive intestinal peptide (VIP). According to the neuro-osteological hypothesis, such neuropeptides can be released and exert paracrine biological effects on bone cells present close to the nerve endings expressing these signaling molecules. The existence of such interplay is most convincingly shown by the hypothalamic control of bone formation, in the case of leptin stimulation of hypothalamic nuclei mediated by the sympathetic nervous system and inhibitory beta-adrenergic receptors on osteoblasts. In addition to these receptors, osteoblasts and osteoclasts express functional receptors for CGRP, SP and VIP, which can regulate both bone formation and bone resorption. The evidence for these observations is summarized in the present paper.     

Deletions of genes encoding calcitonin/alpha-CGRP, amylin and calcitonin receptor have given new and unexpected insights into the function of calcitonin receptors and calcitonin receptor-like receptors in bone

It has been suggested that skeletal nerves fibers may play important roles in neuro-osteogenic interactions. This view is partly based upon information obtained from immunohistochemical studies, chemical and surgical denervation experiments and clinical observations in patients with stroke and spinal cord injury, indicating the presence of a network of nerve fibers in the skeleton and that defective signalling in skeletal nerve fibers affects remodelling of bone. This view is also supported by data showing that functional receptors for signalling molecules in skeletal nerve fibers are expressed in bone cells and that activation of these receptors leads to profound effects on bone forming osteoblasts and bone resorbing osteoclasts. Convincing evidence for a role of neuronal signalling in bone metabolism has been provided by gene deletion approaches in which it has been shown that leptin-sensitive and neuropeptide Y-sensitive receptors in hypothalamus are important for bone remodelling in mice. Recently, gene deletion experiments have shown that calcitonin gene-related peptide (CGRP), one of the neuropeptides present in skeletal nerve fibers, is an important physiological regulator of bone formation at the level of osteoblast activity. CGRP belongs to the calcitonin (CT) family of peptides also including CT, amylin and adrenomedullin, as well as the recently described intermedin and calcitonin receptor-stimulating peptide. These peptides utilize two seven transmembrane G protein-coupled receptors - the calcitonin receptor (CTR) and the calcitonin receptor- like receptor (CRLR) - which can dimerize with three different single transmembrane proteins, making up the RAMP family. Associations between RAMPs and either CTR or CRLR give rise to seven distinct, molecularly characterized, receptors for CT, CGRP, amylin and adrenomedullin. Deletions of the genes for ligands in the CT family of peptides and for one of the receptors have revealed unexpected findings that have changed our view on the role of these peptides in bone remodelling. It was anticipated that deletions of the CT/alpha-CGRP and CTR genes would lead to bone loss, since CT has been shown to inhibit bone resorption in vitro and in vivo and has been used to treat patients with excessive bone resorption. Surprisingly, it was found that CT/alpha-CGRP-/- and CTR+/- mice have increased bone mass due to increased bone formation. Mice with deletion of the amylin gene, however, exhibited bone loss due to enhanced bone resorption. Selective deletion of the alpha-CGRP gene also leads to bone loss, but due to decreased bone formation. Thus, our understanding of the role of the CT family of peptides has been changed dramatically and much more data have to be gained before we fully understand the roles these peptides have in bone biology.     

The role of peripheral nerve fibers and their neurotransmitters in cartilage and bone physiology and pathophysiology

The peripheral nervous system is critically involved in bone metabolism, osteogenesis, and bone remodeling. Nerve fibers of sympathetic and sensory origin innervate synovial tissue and subchondral bone of diathrodial joints. They modulate vascularization and matrix differentiation during endochondral ossification in embryonic limb development, indicating a distinct role in skeletal growth and limb regeneration processes. In pathophysiological situations, the innervation pattern of sympathetic and sensory nerve fibers is altered in adult joint tissues and bone. Various resident cell types of the musculoskeletal system express receptors for sensory and sympathetic neurotransmitters. Osteoblasts, osteoclasts, mesenchymal stem cells, synovial fibroblasts, and different types of chondrocytes produce distinct subtypes of adrenoceptors, receptors for vasointestinal peptide, for substance P and calcitonin gene-related peptide. Many of these cells even synthesize neuropeptides such as substance P and calcitonin gene-related peptide and are positive for tyrosine-hydroxylase, the rate-limiting enzyme for biosynthesis of catecholamines. Sensory and sympathetic neurotransmitters modulate osteo-chondrogenic differentiation of mesenchymal progenitor cells during endochondral ossification in limb development. In adults, sensory and sympathetic neurotransmitters are critical for bone regeneration after fracture and are involved in the pathology of inflammatory diseases as rheumatoid arthritis which manifests mainly in joints. Possibly, they might also play a role in pathogenesis of degenerative joint disorders, such as osteoarthritis. All together, accumulating data imply that sensory and sympathetic neurotransmitters have crucial trophic effects which are critical for proper limb formation during embryonic skeletal growth. In adults, they modulate bone regeneration, bone remodeling, and articular cartilage homeostasis in addition to their classic neurological actions.     

Nerve growth factor receptor (NGFR) immunoreactivity in skeletal muscles of the rat.

The peroxidase-antiperoxidase (PAP) method, and a specific monoclonal antibody (192-IgG) were used to determine the localization of nerve growth factor receptor (NGFr) in the skeletal muscles of the adult rats. The rectus femoris and the gastrocnemius (medialis and lateralis) muscles were analyzed. Occurrence of NGFr immunoreactivity was observed in: 1) a subpopulation of myelinated nerve fibers within muscle nerve trunks; 2) the vascular adventitia and nerve-like profiles around the blood vessels; 3) the outer capsule and the surface of the intrafusal muscle fibers of muscle spindles. Conversely, images, suggesting the presence of NGFr on muscle fibers or in motor end-plates, were not found. Our results suggest the presence of NGF-binding sites in sensory and sympathetic nerve fibers, and/or their target tissues localized on the skeletal muscles of the rat, whereas the motor nerve fibers lack of NGFr. The dependence of sympathetic neurons, proprioceptive primary sensory neurons, and motoneurons innervating the mammalian muscles upon NGF or other neurotrophic factors is discussed.     

Neural control of muscle blood flow during exercise.

Activation of skeletal muscle fibers by somatic nerves results in vasodilation and functional hyperemia. Sympathetic nerve activity is integral to vasoconstriction and the maintenance of arterial blood pressure. Thus the interaction between somatic and sympathetic neuroeffector pathways underlies blood flow control to skeletal muscle during exercise. Muscle blood flow increases in proportion to the intensity of activity despite concomitant increases in sympathetic neural discharge to the active muscles, indicating a reduced responsiveness to sympathetic activation. However, increased sympathetic nerve activity can restrict blood flow to active muscles to maintain arterial blood pressure. In this brief review, we highlight recent advances in our understanding of the neural control of the circulation in exercising muscle by focusing on two main topics: 1) the role of motor unit recruitment and muscle fiber activation in generating vasodilator signals and 2) the nature of interaction between sympathetic vasoconstriction and functional vasodilation that occurs throughout the resistance network. Understanding how these control systems interact to govern muscle blood flow during exercise leads to a clear set of specific aims for future research.     

Sympathetic neural influence on bone metabolism in microgravity (Review)

Bone loss is one of the most important complications for astronauts who are exposed to long-term microgravity in space and also for bedridden elderly people. Recent studies have indicated that the sympathetic nervous system plays a role in bone metabolism. This paper reviews findings concerning with sympathetic influences on bone metabolism to hypothesize the mechanism how sympathetic neural functions are related to bone loss in microgravity. Animal studies have suggested that leptin stimulates hypothalamus increasing sympathetic outflow to bone and enhances bone resorption through noradrenaline and β-adrenoreceptors in bone. In humans, even though there have been some controversial findings, use of β-adrenoblockers has been reported to be beneficial for prevention of osteoporosis and bone fracture. On the other hand, microneurographically-recorded sympathetic nerve activity was enhanced by exposure to microgravity in space as well as dry immersion or long-term bed rest to simulate microgravity. The same sympathetic activity became higher in elderly people whose bone mass becomes generally reduced. Our recent findings indicated a significant correlation between muscle sympathetic nerve activity and urinary deoxypyridinoline as a specific marker measuring bone resorption. Based on these findings we would like to propose a following hypothesis concerning the sympathetic involvement in the mechanism of bone loss in microgravity: An exposure to prolonged microgravity may enhance sympathetic neural traffic not only to muscle but also to bone. This sympathetic enhancement increases plasma noradrenaline level and inhibits osteogenesis and facilitates bone resorption through β-adrenoreceptors in bone to facilitate bone resorption to reduce bone mass. The use of β-adrenoblockers to prevent bone loss in microgravity may be reasonable.     

Pathophysiology and medical treatment of pain in fibrous dysplasia of bone

One of the most common complications of fibrous dysplasia of bone (FD) is bone pain. Usual pain killers are often of inadequate efficacy to control this bone pain. The mechanism of bone pain in FD remains uncertain, but by analogy with bone tumors one may consider that ectopic sprouting and formation of neuroma-like structures by sensory and sympathetic nerve fibers also occur in the dysplastic skeleton. Bone pain has been reported in up to 81% of adults and 49% of children. It affects predominantly the lower limbs and the spine. The degree of pain is highly variable and adults reports more pain than children. Bisphosphonates have been shown to reduce bone pain in uncontrolled studies. Their influence on bone strength remains unknown. In a randomized trial testing alendronate, bone pain was not significantly improved. Another trial assessing the effect of risedronate is ongoing. Possible future therapies include tocilizumab, denosumab and drugs targeting nerve growth factor and its receptor TrkA.     

Neuropeptide Y: presence in perivascular noradrenergic neurons and vasoconstrictor effects on skeletal muscle blood vessels in experimental animals and man

The presence of neuropeptide Y (NPY)-like immunoreactivity (-LI) in sympathetic perivascular nerves and the functional effects of NPY and noradrenaline (NA) on vascular tone were studied in skeletal muscle of various species. A dense network of NPY-LI was found around arteries and arterioles but not venules in the gluteus maximus muscle of man, gracilis muscle of dog, tenuissimus muscle of rabbit and quadriceps muscle of cat, rat, guinea pig and pig. The distribution of NPY-immunoreactive (-IR) nerves was closely correlated to the presence of tyrosine hydroxylase (TH) and dopamine-beta-hydroxylase (DBH)-positive fibers, two markers for noradrenergic neurons. Double-staining experiments revealed that NPY- and TH-IR as well as NPY- and DBH-IR nerve fibers around arteries and arterioles were identical. The veins and venules, however, lacked or had a very sparse innervation of NPY-, TH- and DBH-positive fibers. The NPY- and TH-IR nerves in quadriceps muscle of the guinea pig were absent after treatment with 6-hydroxydopamine. Lumbosacral sympathetic ganglia from the same species contained many NPY-positive cells which were also TH- and DBH-IR. NPY-LI was also detected by radioimmunoassay in extracts of skeletal muscle from guinea pig, rabbit, dog, pig and man as well as of lumbosacral sympathetic ganglia. The content of NPY-LI in skeletal muscle was relatively low (0.1-0.4 pmol/g), whereas lumbosacral sympathetic ganglia had a much higher content (48-88 pmol/g). NPY (10(-7) M) contracted arterioles in the tenuissimus muscle of the rabbit to a similar extent (by 65%) as NA (10(-6) M), as studied by intravital microscopy in vivo. NPY had no effect on the corresponding venules while NA caused a slight contraction of these vessels. In vitro studies of small human skeletal muscle arteries and veins revealed that NPY was more potent than NA in contracting the arteries, and the highest concentration of NPY (5 x 10(-7) M) caused a contraction of a similar magnitude as NA 10(-5) M. NA contracted veins from human skeletal muscle, while NPY had only small effects. It is suggested that NPY, together with NA, could be of importance for sympathetic control of skeletal muscle blood flow.     

Light and electron microscopic studies on the excessive growth of sympathetic ganglia in rats injected daily from birth with 6-OHDA and NGF.

Concomitatn daily treatment of rats immediately after birth with NGF and 6-OHDA for a period of 2-4 weeks, results in a volume increase of sympathetic ganglia of thirty times that of controls and 2.3 that of NGF treated littermates, at three weeks of age. Studies at the light, fluorescent and electron-microscope, showed that this overall enlargement is due to increase in size and number of sympathetic neurons and, to an even higher extent, to profuse production and branching of collaterals from postganglionic adrenergic nerve fibers. These axonal collaterals find accomodation inside the ganglia where they displace nerve cells and build a thick fibrillar capsule around the same ganglia. The survival in excellent conditions of sympathetic nerve cells treated with NGF but prevented by 6-OHDA from establishing anatomical and functional connections with their end organs, suggests that the growth factor find access to its target cells through the plasms membrane which envelops the cell perikarya. The extraordinary production of collaterals by chemically axotomized sympathetic fibers, brings to light growth potentialities of these fibers which materialize only upon disconnection of their endings from peripheral tissues. These results uncover a new facet of the interaction between nerve fibers and innervated tissues.     

Electrostimulation and morphologic study of the nerves to the bone marrow of the albino rat.

The innervation of the bone marrow of the albino rat was investigated by electrostimulation and morphological methods. Stimulation of the lumbar sympathetic trunks resulted in the release of reticulocytes and neutrophils into the circulating blood. The effects of stimulation on other cell types in the bone marrow could not be definitely established. It was concluded that the nerve fibers to the bone marrow were distributed to the arteries. It is postulated that the transmitter substance released at the autonomic nerve endings may have an effect upon the permeability of the venous sinusiods and the mobility of the blood cells in the marrow parenchyma resulting in their release into the circulating blood.     

Distribution of CGRP-, VIP-, DβH-, SP-, and NPY-immunoreactive nerves in the periosteum of the rat

Summary In light of the possible role peripheral nerves may play in bone metabolism, the morphology of calcitonin gene-related peptide (CGRP)-, vasoactive intestinal peptide (VIP)-, substance P (SP)-, neuropeptide Y (NPY)-, and dopamine--hydroxylase (DH)-immunoreactive nerve fibers was examined in whole-mount preparations of periosteum of membranous bones (calvaria, mandible) and long bones (tibia) from the rat. Periosteum from animals treated to remove selectively either the sympathetic or fine-caliber primary afferent nerves was also examined to determine the origin of the nerve fibers. We found a consistent and often dense innervation of the periosteum. The innervation patterns of the calvaria and mandible were similar, with networks of nerves spread across the surface of the bone. Nerves in the tibial periosteum were oriented in the longitudinal axis and were more numerous at the epiphyses than in the mid-shaft region. CGRP-immunoreactive fibers were widely and densely distributed. The presence of populations of CGRP-immunoreactive fibers of differing calibers and perivascular arrangements suggests that such nerves in bone tissues may serve different functions. SP-immunoreactivity was present in a fine network of varicose fibers in the superficial layers of the periosteum. CGRP- and SP-immunoreactive nerve fibers were dramatically reduced in periosteum of capsaicin-treated animals as compared to controls, indicating the sensory origin of these nerves. VIP-immunoreactive nerve fibers were distributed in the periosteum of mandible and calvaria as small networks and individual fine varicose fibers. In tibial periosteum, larger networks of these fibers were visible. VIP-immunoreactive nerve fibers in the periosteum were associated with both vascular and nonvascular elements within the layers of cells closest to the bone, suggesting that VIP may serve more than one function in periosteal tissues. NPY-immunoreactive fibers were largely confined to vascular elements; occasional fibers were observed among the bone-lining cells. DH-immunoreactivity was associated only with blood vessels. VIP-, NPY-, and DH-immunoreactivities were dramatically reduced in the periosteum of guanethidinetreated animals, indicating the sympathetic origin of these nerves.     

Sensory and sympathetic nerve fibers undergo sprouting and neuroma formation in the painful arthritic joint of geriatric mice

Introduction

Although the prevalence of arthritis dramatically increases with age, the great majority of preclinical studies concerning the mechanisms that drive arthritic joint pain have been performed in young animals. One mechanism hypothesized to contribute to arthritic pain is ectopic nerve sprouting; however, neuroplasticity is generally thought to be greater in young versus old nerves. Here we explore whether sensory and sympathetic nerve fibers can undergo a significant ectopic nerve remodeling in the painful arthritic knee joint of geriatric mice.

Methods

Vehicle (saline) or complete Freund's adjuvant (CFA) was injected into the knee joint of 27- to 29-month-old female mice. Pain behaviors, macrophage infiltration, neovascularization, and the sprouting of sensory and sympathetic nerve fibers were then assessed 28 days later, when significant knee-joint pain was present. Knee joints were processed for immunohistochemistry by using antibodies raised against CD68 (monocytes/macrophages), PECAM (endothelial cells), calcitonin gene-related peptide (CGRP; sensory nerve fibers), neurofilament 200 kDa (NF200; sensory nerve fibers), tyrosine hydroxylase (TH; sympathetic nerve fibers), and growth-associated protein 43 (GAP43; nerve fibers undergoing sprouting).

Results

At 4 weeks after initial injection, CFA-injected mice displayed robust pain-related behaviors (which included flinching, guarding, impaired limb use, and reduced weight bearing), whereas animals injected with vehicle alone displayed no significant pain-related behaviors. Similarly, in the CFA-injected knee joint, but not in the vehicle-injected knee joint, a remarkable increase was noted in the number of CD68⁺ macrophages, density of PECAM⁺ blood vessels, and density and formation of neuroma-like structures by CGRP⁺, NF200⁺, and TH⁺ nerve fibers in the synovium and periosteum.

Conclusions

Sensory and sympathetic nerve fibers that innervate the aged knee joint clearly maintain the capacity for robust nerve sprouting and formation of neuroma-like structures after inflammation/injury. Understanding the factors that drive this neuroplasticity, whether this pathologic reorganization of nerve fibers contributes to chronic joint pain, and how the phenotype of sensory and sympathetic nerves changes with age may provide pharmacologic insight and targets for better controlling aging-related joint pain.     

The anatomy and innervation of the mammalian pineal gland

The parenchymal cells of the mammalian pineal gland are the hormone-producing pinealocytes and the interstitial cells. In addition, perivascular phagocytes are present. The phagocytes share antigenic properties with microglial and antigen-presenting cells. In certain species, the pineal gland also contains neurons and/or neuron-like peptidergic cells. The peptidergic cells might influence the pinealocyte by a paracrine secretion of the peptide. Nerve fibers innervating the mammalian pineal gland originate from perikarya located in the sympathetic superior cervical ganglion and the parasympathetic sphenopalatine and otic ganglia. The sympathetic nerve fibers contain norepinephrine and neuropeptide Y as neurotransmitters. The parasympathetic nerve fibers contain vasoactive intestinal peptide and peptide histidine isoleucine. Recently, neurons in the trigeminal ganglion, containing substance P, calcitonin gene-related peptide, and pituitary adenylate cyclase-activating peptide, have been shown to project to the mammalian pineal gland. Finally, nerve fibers originating from perikarya located in the brain containing, for example, GABA, orexin, serotonin, histamine, oxytocin, and vasopressin innervate the pineal gland directly via the pineal stalk. Biochemical studies have demonstrated numerous receptors on the pinealocyte cell membrane, which are able to bind the neurotransmitters located in the pinealopetal nerve fibers. These findings indicate that the mammalian pinealocyte can be influenced by a plethora of neurotransmitters.     

Adrenergic signalling in osteoarthritis

Adrenoceptors (ARs) mediate the effects of the sympathetic neurotransmitters norepinephrine (NE) and epinephrine (E) in the human body and play a central role in physiologic and pathologic processes. Therefore, ARs have long been recognized as targets for therapeutic agents, especially in the field of cardiovascular medicine. During the past decades, the contribution of the sympathetic nervous system (SNS) and particularly of its major peripheral catecholamine NE to the pathogenesis of osteoarthritis (OA) attracted growing interest. OA is the most common degenerative joint disorder worldwide and a disease of the whole joint. It is characterized by progressive degradation of articular cartilage, synovial inflammation, osteophyte formation, and subchondral bone sclerosis mostly resulting in chronic pain. The subchondral bone marrow, the periosteum, the synovium, the vascular meniscus and numerous tendons and ligaments are innervated by tyrosine hydroxylase-positive (TH+) sympathetic nerve fibers that release NE into the synovial fluid and cells of all abovementioned joint tissues express at least one out of nine AR subtypes. During the past decades, several in vitro studies explored the AR-mediated effects of NE on different cell types in the joint. So far, only a few studies used animal OA models to investigate the contribution of distinct AR subtypes to OA pathogenesis in vivo. This narrative review shortly summarizes the current background knowledge about ARs and their signalling pathways at first. In the second part, we focus on recent findings in the field of NE-induced AR-mediated signalling in different joint tissues during OA pathogenesis and at the end, we will delineate the potential of targeting the adrenergic signalling for OA prevention or treatment. We used the PubMed bibliographic database to search for keywords such as ‘joint’ or ‘cartilage’ or ‘synovium’ or ‘bone’ and ‘osteoarthritis’ and/or ‘trauma’ and ‘sympathetic nerve fibers’ and/or ‘norepinephrine’ and ‘adrenergic receptors / adrenoceptors’ as well as ‘adrenergic therapy’.     

Glutamatergic regulation of bone remodeling

L-glutamate (Glu) is the predominant neuromediator in the mammalian central nervous system (CNS). Bone is highly innervated and there is growing evidence of a neural control of bone cell metabolism. The recent discovery of Glu-containing nerve fibers in bone and Glu receptors (GluR) and transporters in bone cells suggest that this neuromediator may also act as a signaling molecule in bone and regulate bone cell function. Our previous studies have demonstrated that ionotropic N-Methyl-D-Aspartate (NMDA) GluR are highly expressed by mammalian osteoclasts. NMDA receptors (NMDAR) are heteromers associating the NR1 subunit and one of the four types of NR2 subunits (NR2A to D). We showed that osteoclasts express NR1, NR2B and NR2D subunits, suggesting a molecular diversity of NMDAR in these cells. Electrophysiological studies have confirmed that NMDAR are functional in mature osteoclasts, and features of Glu-induced current recorded in these cells indicate a major NR2D subunit composition. Using an in vitro assay of bone resorption, we showed that several antagonists of NMDAR binding to different sites of the receptor inhibit bone resorption. In particular, the specific NMDAR channel blocker MK801 had no effect on osteoclast attachment to bone and survival while it rapidly decreased the percentage of osteoclasts with actin ring structures that are associated with actively resorbing osteoclasts. NMDAR may thus be involved in adhesion-induced formation of the sealing zone required for bone resorption. NMDAR are also expressed by osteoclast precursors isolated from mouse bone marrow. We recently confirmed the presence of NR1, NR2B and NR2D in these cells and demonstrated their expression at all differentiation stages from osteoclast precursors to mature resorbing osteoclasts. No regulation of these subunits mRNA expression levels was observed throughout the osteoclastic differentiation sequence. Activation of NMDAR may therefore represent a new mechanism for regulating osteoclast formation and activity. While the origin of Glu in bone is still unknown, the possibility of a glutamatergic neurotransmission in this tissue is suggested by the detection of Glu in nerve fibers in close contact to bone cells. Furthermore, we recently demonstrated that sciatic neurectomy in growing rats induces a bone loss associated with a reduction of nerve profiles immunostained for Glu. These results suggest that Glu may be released from glutamatergic nerve profiles present in bone and therefore contribute to the local regulation of bone cell function.     

Changes in surviving nerve fibers associated with submucosal arteries following extrinsic denervation of the small intestine

Summary The neuropeptide content of nerve fibers associated with submucosal arteries in the small intestine of guinea pigs was studied in whole-mount preparations using immunohistochemical methods. Tissues were obtained from normal animals or animals in which the small intestine had been extrinsically denervated. In normal animals, submucosal arteries are innervated by extrinsic sensory nerve fibers which contain both substance P and calcitonin gene-related peptide, and by sympathetic noradrenergic nerve fibers. In preparations obtained from animals 5–9 days after denervation, nerve fibers which contained substance P without detectable calcitonin gene-related peptide were associated with a few submucosal arteries. Nerve fibers which contained vasoactive intestinal peptide were also associated with some arteries. By 42–48 days after extrinsic denervation, substance P-containing fibers (without calcitonin gene-related peptide) and vasoactive intestinal peptide-containing fibers were associated with nearly every blood vessel. The extrinsic sympathetic nerve fibers did not regenerate during the course of this study. The nerve fibers associated with submucosal arteries in denervated tissues were not sensitive to capsaicin treatment.The alteration in the innervation of submucosal arterioles that follows extrinsic denervation of the gut may reflect either an increase in the neuropeptide content of the fibers, synthesis of a new peptide, or an increase in the number of fibers as a result of axonal sprouting.     

Isoform variants of troponin in skeletal and cardiac muscle cells cultured with and without nerves

Immunofluorescence microscopy shows that cultured skeletal and cardiac muscle cells of chicken embryos exhibit the same stainabilities with antibodies against skeletal and cardiac troponin components as do those in embryos. Muscle cells of each type cultured with motor or sympathetic nerves or in medium containing the nerve extract exhibit the same reactivities as do those in adult animals. Cardiac muscle cells incubated in the nerve-conditioned medium also change the form of troponin components to the adult type. It appears that the differentiation of individual muscle fibers to specific types is induced by nerves, and especially by the neurohumoral effect.     

Tissue preparation and immunostaining of mouse sensory nerve fibers innervating skin and limb bones

Detection and primary processing of physical, chemical and thermal sensory stimuli by peripheral sensory nerve fibers is key to sensory perception in animals and humans. These peripheral sensory nerve fibers express a plethora of receptors and ion channel proteins which detect and initiate specific sensory stimuli. Methods are available to characterize the electrical properties of peripheral sensory nerve fibers innervating the skin, which can also be utilized to identify the functional expression of specific ion channel proteins in these fibers. However, similar electrophysiological methods are not available (and are also difficult to develop) for the detection of the functional expression of receptors and ion channel proteins in peripheral sensory nerve fibers innervating other visceral organs, including the most challenging tissues such as bone. Moreover, such electrophysiological methods cannot be utilized to determine the expression of non-excitable proteins in peripheral sensory nerve fibers. Therefore, immunostaining of peripheral/visceral tissue samples for sensory nerve fivers provides the best possible way to determine the expression of specific proteins of interest in these nerve fibers. So far, most of the protein expression studies in sensory neurons have utilized immunostaining procedures in sensory ganglia, where the information is limited to the expression of specific proteins in the cell body of specific types or subsets of sensory neurons. Here we report detailed methods/protocols for the preparation of peripheral/visceral tissue samples for immunostaining of peripheral sensory nerve fibers. We specifically detail methods for the preparation of skin or plantar punch biopsy and bone (femur) sections from mice for immunostaining of peripheral sensory nerve fibers. These methods are not only key to the qualitative determination of protein expression in peripheral sensory neurons, but also provide a quantitative assay method for determining changes in protein expression levels in specific types or subsets of sensory fibers, as well as for determining the morphological and/or anatomical changes in the number and density of sensory fibers during various pathological states. Further, these methods are not confined to the staining of only sensory nerve fibers, but can also be used for staining any types of nerve fibers in the skin, bones and other visceral tissue.     

Evidence for GABAergic fibers entering the superior cervical ganglion of rat from the preganglionic nerve trunk

Summary The origin of gamma-aminobutyric acid immunoreactive (GABA-IR) nerve fibers present in the superior cervical ganglion (SCG) of rat was investigated. With immunocytochemical techniques many nerve fibers showed GABA-like positivity in the cervical sympathetic trunk, whereas similar staining could not be revealed in the internal carotid nerve or in the external carotid nerve. Ligation of the cervical sympathetic trunk for 24 h resulted a dramatic reduction in the staining density in the ganglion and in the cervical sympathetic trunk distal to the ligature. After transection of the preganglionic nerve fibers for eleven days or more, very few fibers staining for GABA were seen in the ganglion. The immunohistochemical results suggest that a major source of GABA within the SCG is a population of GABAergic axons entering from the preganglionic trunk.