Author Report for: Kummer W

Cholinergic polymodal chemosensory cells in the mammalian urethra (urethral brush cells = UBC) functionally express the canonical bitter and umami taste transduction signaling cascade. Here, we aimed to determine whether UBC are functionally equipped for the perception of salt through ENaC (epithelial sodium channel). Cholinergic UBC were isolated from ChAT-eGFP reporter mice (ChAT = choline acetyltransferase). RT-PCR showed mRNA expression of ENaC subunits Scnn1a, Scnn1b, and Scnn1g in urethral epithelium and isolated UBC. Scnn1a could also be detected by next generation sequencing in 4/6 (66%) single UBC, two of them also expressed the bitter receptor Tas2R108. Strong expression of Scnn1a was seen in some urothelial umbrella cells and in 65% of UBC (30/46 cells) in a Scnn1a reporter mouse strain. Intracellular [Ca(2+)] was recorded in isolated UBC stimulated with the bitter substance denatonium benzoate (25 mM), ATP (0.5 mM) and NaCl (50 mM, on top of 145 mM Na(+) and 153 mM Cl(-) baseline in buffer); mannitol (150 mM) served as osmolarity control. NaCl, but not mannitol, evoked an increase in intracellular [Ca(2+)] in 70% of the tested UBC. The NaCl-induced effect was blocked by the ENaC inhibitor amiloride (IC50 = 0.47 muM). When responses to both NaCl and denatonium were tested, all three possible positive response patterns occurred in a balanced distribution: 42% NaCl only, 33% denatonium only, 25% to both stimuli. A similar reaction pattern was observed with ATP and NaCl as test stimuli. About 22% of the UBC reacted to all three stimuli. Thus, NaCl evokes calcium responses in several UBC, likely involving an amiloride-sensitive channel containing alpha-ENaC. This feature does not define a new subpopulation of UBC, but rather emphasizes their polymodal character. The actual function of alpha-ENaC in cholinergic UBC-salt perception, homeostatic ion transport, mechanoreception-remains to be determined.

Several species of the Gram-negative genus Bordetella are the cause of respiratory infections in mammals and birds, including whooping cough (pertussis) in humans. Very recently, a novel atypical species, Bordetella pseudohinzii, was isolated from laboratory mice. These mice presented no obvious clinical symptoms but elevated numbers of neutrophils in bronchoalveolar lavage fluid and inflammatory signs in histopathology. We noted that this species can occur at high prevalence in a mouse facility despite regular pathogen testing according to the FELASA-recommendations. Affected C57BL/6 J mice had, in addition to the reported pulmonary alterations, tracheal inflammation with reduced numbers of ciliated cells, slower ciliary beat frequency, and largely (>50%) compromised cilia-driven particle transport speed on the mucosal surface, a primary innate defence mechanism. In an in vitro-model, Bordetella pseudohinzii attached to respiratory kinocilia, impaired ciliary function within 4 h and caused epithelial damage within 24 h. Regular testing for this ciliotropic Bordetella species and excluding it from colonies that provide mice for lung research shall be recommended. On the other hand, controlled colonization and infection with Bordetella pseudohinzii may serve as an experimental model to investigate mechanisms of mucociliary clearance and microbial strategies to escape from this primary innate defence response.

We previously identified a population of cholinergic epithelial cells in murine, human and rat urethrae that exhibits a structural marker of brush cells (villin) and expresses components of the canonical taste transduction signaling cascade (alpha-gustducin, phospholipase Cbeta2 (PLCbeta2), transient receptor potential cation channel melanostatin 5 (TRPM5)). These cells serve as sentinels, monitoring the chemical composition of the luminal content for potentially hazardous compounds such as bacteria, and initiate protective reflexes counteracting further ingression. In order to elucidate cross-species conservation of the urethral chemosensory pathway we investigated the occurrence and molecular make-up of urethral brush cells in placental mammals. We screened 11 additional species, at least one in each of the five mammalian taxonomic units primates, carnivora, perissodactyla, artiodactyla and rodentia, for immunohistochemical labeling of the acetylcholine synthesizing enzyme, choline acetyltransferase (ChAT), villin, and taste cascade components (alpha-gustducin, PLCbeta2, TRPM5). Corresponding to findings in previously investigated species, urethral epithelial cells with brush cell shape were immunolabeled in all 11 mammals. In 8 species, immunoreactivities against all marker proteins and ChAT were observed, and double-labeling immunofluorescence confirmed the cholinergic nature of villin-positive and chemosensory (TRPM5-positive) cells. In cat and horse, these cells were not labeled by the ChAT antiserum used in this study, and unspecific reactions of the secondary antiserum precluded conclusions about ChAT-expression in the bovine epithelium. These data indicate that urethral brush cells are widespread throughout the mammalian kingdom and evolved not later than about 64.5millionyears ago.

Fluid homeostasis mediated by the airway epithelium is required for proper lung function, and the CFTR (cystic fibrosis transmembrane conductance regulator) Cl(-) channel is crucial for these processes. Luminal acetylcholine (ACh) acts as an auto-/paracrine mediator to activate Cl(-) channels in airway epithelia and evidence exists showing that nicotinic ACh receptors activate CFTR in murine airway epithelia. The present study investigated whether or not luminal ACh regulates CFTR activity in airway epithelia of pigs, an emerging model for investigations of human airway disease and cystic fibrosis (CF) in particular. Transepithelial ion currents of freshly dissected pig tracheal preparations were measured with Ussing chambers. Application of luminal ACh (100 muM) induced an increase of the short-circuit current (I(SC)). The ACh effect was mimicked by muscarine and pilocarpine (100 muM each) and was sensitive to muscarinic receptor antagonists (atropine, 4-DAMP, pirenzepine). No changes of the I(SC) were observed by nicotine (100 muM) and ACh responses were not affected by nicotine or mecamylamine (25 muM). Luminal application of IBMX (I, 100 muM) and forskolin (F, 10 muM), increase the I(SC) and the I/F-induced current were decreased by the CFTR inhibitor GlyH-101 (GlyH, 50 muM) indicating increased CFTR activity by I/F. In contrast, GlyH did not affect the ACh-induced current, indicating that the ACh response does not involve the activation of the CFTR. Results from this study suggest that luminal ACh does not regulate the activity of the CFTR in tracheal epithelia of pigs which opposes observation from studies using mice airway epithelium.

This special issue of International Immunopharmacology is the proceedings of the Fourth International Symposium on Non-neuronal Acetylcholine that was held on August 28-30, 2014 at the Justus Liebig University of Giessen in Germany. It contains original contributions of meeting participants covering the significant progress in understanding of the biological and medical significance of the non-neuronal cholinergic system extending from exciting insights into molecular mechanisms regulating this system via miRNAs over the discovery of novel cholinergic cellular signaling circuitries to clinical implications in cancer, wound healing, immunity and inflammation, cardiovascular, respiratory and other diseases.

Specialized epithelial cells in the respiratory tract such as solitary chemosensory cells and brush cells sense the luminal content and initiate protective reflexes in response to the detection of potentially harmful substances. The majority of these cells are cholinergic and utilize the canonical taste signal transduction cascade to detect "bitter" substances such as bacterial quorum sensing molecules. Utilizing two different mouse strains reporting expression of choline acetyltransferase (ChAT), the synthesizing enzyme of acetylcholine (ACh), we detected cholinergic cells in the submucosal glands of the murine larynx and trachea. These cells were localized in the ciliated glandular ducts and were neither found in the collecting ducts nor in alveolar or tubular segments of the glands. ChAT expression in tracheal gland ducts was confirmed by in situ hybridization. The cholinergic duct cells expressed the brush cell marker proteins, villin and cytokeratin-18, and were immunoreactive for components of the taste signal transduction cascade (Galpha-gustducin, transient receptor potential melastatin-like subtype 5 channel = TRPM5, phospholipase C(beta2)), but not for carbonic anhydrase IV. Furthermore, these cells expressed the bitter taste receptor Tas2r131, as demonstrated utilizing an appropriate reporter mouse strain. Our study identified a previously unrecognized presumptive chemosensory cell type in the duct of the airway submucosal glands that likely utilizes ACh for paracrine signaling. We propose that these cells participate in infection-sensing mechanisms and initiate responses assisting bacterial clearance from the lower airways.

In addition to quantal, vesicular release of acetylcholine (ACh), there is also non-quantal release at the motor endplate which is insufficient to evoke postsynaptic responses unless acetylcholinesterase (AChE) is inhibited. We here addressed potential non-quantal release in the mouse trachea by organ bath experiments and (immuno)histochemical methods. Electrical field stimulation (EFS) of nerve terminals elicited tracheal constriction that is largely due to ACh release. Classical enzyme histochemistry demonstrated acetylcholinesterase (AChE) activity in nerve fibers in the muscle and butyrylcholinesterase (BChE) activity in the smooth muscle cells. Acute inhibition of both esterases by eserine significantly raised tracheal tone which was fully sensitive to atropine. This effect was reduced, but not abolished, in AChE, but not in BChE gene-deficient mice. The eserine-induced increase in tracheal tone was unaffected by vesamicol (10(-5)M), an inhibitor of the vesicular acetylcholine transporter, and by corticosterone (10(-4)M), an inhibitor of organic cation transporters. Hemicholinium-3, in low concentrations an inhibitor of the high-affinity choline transporter-1 (CHT1), completely abrogated the eserine effects when applied in high concentrations (10(-4)M) pointing towards an involvement of low-affinity choline transporters. To evaluate the cellular sources of non-quantal ACh release in the trachea, expression of low-affinity choline transporter-like family (CTL1-5) was evaluated by RT-PCR analysis. Even though these transporters were largely abundant in the epithelium, denudation of airway epithelial cells had no effect on eserine-induced tracheal contraction, indicating a non-quantal release of ACh from non-epithelial sources in the airways. These data provide evidence for an epithelium-independent non-vesicular, non-quantal ACh release in the mouse trachea involving low-affinity choline transporters.

The thymus is the site of T cell maturation which includes positive selection in the cortex and negative selection in the medulla. Acetylcholine is locally produced in the thymus and cholinergic signaling influences the T cell development. We recently described a distinct subset of medullary epithelial cells in the murine thymus which express the acetylcholine-synthesizing enzyme choline acetyltransferase (ChAT) and components of the canonical taste transduction cascade, i.e. transient receptor potential melastatin-like subtype 5 channel (TRPM5), phospholipase Cbeta(2), and Galpha-gustducin. Such a chemical phenotype is characteristic for chemosensory cells of mucosal surfaces which utilize bitter receptors for detection of potentially hazardous compounds and cholinergic signaling to initiate avoidance reflexes. We here demonstrate mRNA expression of bitter receptors Tas2r105, Tas2r108, and Tas2r131 in the murine thymus. Using a Tas2r131-tauGFP reporter mouse we localized the expression of this receptor to cholinergic cells expressing the downstream elements of the taste transduction pathway. These cells are distinct from the medullary thymic epithelial cells which promiscuously express tissue-restricted self-antigens during the process of negative selection, since double-labeling immunofluorescence showed no colocalization of autoimmune regulator (AIRE), the key mediator of negative selection, and TRPM5. These data demonstrate the presence of bitter taste-sensing signaling in cholinergic epithelial cells in the thymic medulla and opens a discussion as to what is the physiological role of this pathway.

We recently identified a specialized cholinergic cell type in tracheal and urethral epithelium that utilizes molecules of the canonical taste transduction signaling cascade to sense potentially harmful substances in the luminal content. Upon stimulation, this cell initiates protective reflexes. Assuming a sentinel role of such cells at mucosal surfaces exposed to bacteria, we hypothesized their occurrence also in ocular mucosal surfaces. Utilizing a mouse strain expressing eGFP under the promoter of the acetylcholine synthesizing enzyme, choline acetyltransferase (ChAT-eGFP), we observed a cholinergic cell in the murine conjunctiva. Singular cholinergic cells reaching the epithelial surface with slender processes were detected in fornical, but neither in bulbar nor palpebral epithelia. These cells were found neither in the lacrimal canaliculi, nor in the lacrimal sac and the nasolacrimal duct. Cholinergic conjunctival epithelial cells were immunoreactive for components of the canonical taste transduction signaling cascade, i.e. alpha-gustducin, phospholipase Cbeta2 and the monovalent cation channel TRPM5. Calcitonin gene-related peptide- and substance P-immunoreactive sensory nerve fibers were observed extending into the conjunctival epithelium approaching slender ChAT-eGFP-positive cells. In addition, we noted both ChAT-eGFP expression and alpha-gustducin-immunoreactivity, albeit in different cell populations, in occasionally occurring lymphoid follicles of the nictitating membrane. The data show a previously unidentified cholinergic cell in murine conjunctiva with chemosensory traits that presumably utilizes acetylcholine for signaling. In analogy to similar cells described in the respiratory and urethral epithelium, it might serve to detect bacterial products and to initiate protective reflexes.

Photochromic ligands have been used to control a variety of biological functions, especially in neural systems. Recently, much effort has been invested in the photocontrol of ion channels and G-protein coupled receptors found in the synapse. Herein, we describe the expansion of our photopharmacological approach toward the remote control of an enzyme. Building on hallmark studies dating from the late 1960s, we evaluated photochromic inhibitors of one of the most important enzymes in synaptic transmission, acetylcholinesterase (AChE). Using structure-based design, we synthesized several azobenzene analogues of the well-known AChE inhibitor tacrine (THA) and determined their effects on enzymatic activity. One of our compounds, AzoTHA, is a reversible photochromic blocker of AChE in vitro and ex vivo with high affinity and fast kinetics. As such, AzoTHA can be used to control synaptic transmission on the neuromuscular endplate based on the light-dependent clearance of a neurotransmitter.

Chemosensory cells in the mucosal surface of the respiratory tract ("brush cells") use the canonical taste transduction cascade to detect potentially hazardous content and trigger local protective and aversive respiratory reflexes on stimulation. So far, the urogenital tract has been considered to lack this cell type. Here we report the presence of a previously unidentified cholinergic, polymodal chemosensory cell in the mammalian urethra, the potential portal of entry for bacteria and harmful substances into the urogenital system, but not in further centrally located parts of the urinary tract, such as the bladder, ureter, and renal pelvis. Urethral brush cells express bitter and umami taste receptors and downstream components of the taste transduction cascade; respond to stimulation with bitter (denatonium), umami (monosodium glutamate), and uropathogenic Escherichia coli; and release acetylcholine to communicate with other cells. They are approached by sensory nerve fibers expressing nicotinic acetylcholine receptors, and intraurethral application of denatonium reflexively increases activity of the bladder detrusor muscle in anesthetized rats. We propose a concept of urinary bladder control involving a previously unidentified cholinergic chemosensory cell monitoring the chemical composition of the urethral luminal microenvironment for potential hazardous content.

Specialized epithelial cells with a tuft of apical microvilli ("brush cells") sense luminal content and initiate protective reflexes in response to potentially harmful substances. They utilize the canonical taste transduction cascade to detect "bitter" substances such as bacterial quorum-sensing molecules. In the respiratory tract, most of these cells are cholinergic and are approached by cholinoceptive sensory nerve fibers. Utilizing two different reporter mouse strains for the expression of choline acetyltransferase (ChAT), we observed intense labeling of a subset of thymic medullary cells. ChAT expression was confirmed by in situ hybridization. These cells showed expression of villin, a brush cell marker protein, and ultrastructurally exhibited lateral microvilli. They did not express neuroendocrine (chromogranin A, PGP9.5) or thymocyte (CD3) markers but rather thymic epithelial (CK8, CK18) markers and were immunoreactive for components of the taste transduction cascade such as Galpha-gustducin, transient receptor potential melastatin-like subtype 5 channel (TRPM5), and phospholipase Cbeta2. Reverse transcription and polymerase chain reaction confirmed the expression of Galpha-gustducin, TRPM5, and phospholipase Cbeta2. Thymic "cholinergic chemosensory cells" were often in direct contact with medullary epithelial cells expressing the nicotinic acetylcholine receptor subunit alpha3. These cells have recently been identified as terminally differentiated epithelial cells (Hassall's corpuscle-like structures in mice). Contacts with nerve fibers (identified by PGP9.5 and CGRP antibodies), however, were not observed. Our data identify, in the thymus, a previously unrecognized presumptive chemosensitive cell that probably utilizes acetylcholine for paracrine signaling. This cell might participate in intrathymic infection-sensing mechanisms.

Nicotinic acetylcholine receptors (nAChR) influence bladder afferent activity and reflex sensitivity, and have been suggested as potential targets for treating detrusor overactivity. Mechanisms may include indirect effects, e.g. involving the urothelium, and direct action on nAChR expressed by afferent neurons. Here we determined the nAChR repertoire of bladder afferent neurons by retrograde neuronal tracing and laser-assisted microdissection/reverse transcriptase polymerase chain reaction (RT-PCR), and quantified retrogradely labelled nAChRalpha3-subunit-expressing neurons by immunohistochemistry in nAChR alpha3beta4alpha5 cluster enhanced green fluorescent protein (eGFP) reporter mice. Bladder afferents distinctly expressed mRNAs encoding for nAChR-subunits alpha3, alpha6, alpha7, beta2-4, and weakly alpha4. Based upon known combinatorial patterns of subunits, this predicts the expression of at least three basically different subunits of nAChR - alpha3( *), alpha6( *) and alpha7( *) - and of additional combinations with beta-subunits and alpha5. Bladder afferents were of all sizes, and their majority (69%; n=1367) were eGFP-nAChRalpha3 positive. Immunofluorescence revealed immunoreactivities to neurofilament 68 (NF68), transient receptor potential cation channel vanilloid 1 (TRPV1), substance P (SP) and calcitonin gene-related peptide (CGRP) in eGFP-nAChRalpha3-positive and -negative neurons. For each antigen, all possible combinations of colocalisation with eGFP-nAChRalpha3 were observed, with eGFP-nAChRalpha3-positive bladder neurons without additional immunoreactivity being most numerous, followed by triple-labelled neurons. In conclusion, more than one population of bladder afferent neurons expresses nAChR, indicating that peripheral nicotinic initiation and modulation of bladder reflexes might result, in addition to indirect effects, from the direct activation of sensory terminals. The expression of multiple nAChR subunits offers the potential of selectively addressing functional aspects and/or sensory neuron subpopulations.

AIMS: In patients with bladder outlet obstruction (BOO), dysregulation of bladder afferent neurons seems to contribute to irritative symptoms. Cholinergic receptors, addressed by both neuronal and non-neuronal (urothelial) acetylcholine, can alter neuronal excitability. Thus we investigated the influence of BOO on the expression of muscarinic (mAChR) and nicotinic (nAChR) acetylcholine receptors in the lumbosacral dorsal root ganglia (DRG) of mice. MAIN
METHODS: BOO was induced in 13 C57/BL6 mice by partial suturing of the urethra. Eleven mice were sham-operated (loose/freely movable suture around the urethra), and eleven untreated mice served as controls. Cystometry was performed five weeks later in conscious mice. DRG at segmental levels L5-S2 were dissected and real-time quantitative PCR was performed. Expression of mAChR subtypes M1-M5 and nAChR subunits alpha2-7, alpha9-10, beta2-4 was examined. KEY FINDINGS: Expression of all mAChR subtypes and nAChR subunits alpha3-7, alpha10, beta2-4 was detected. Expression of alpha2 and alpha9 was absent. Rank order of expression was M2>M4>M3>M5>M1, alpha3>/=alpha6>alpha7>alpha4>alpha10>alpha5 and beta2>beta4>beta3 in untreated animals. BOO mice presented distinct obstruction with development of residual urine. Sham mice showed only minimal BOO. Relative mRNA expression of nAChR subunits revealed significant reduction of alpha3, alpha5, alpha6, alpha10 and beta4 in sham-operated vs. untreated mice. In BOO vs. sham-operated mice, reduction of nAChR subunits alpha10 (p=0.038) and alpha5 (p=0.053) was found. SIGNIFICANCE: BOO has a considerable impact on nAChR, but not on mAChR mRNA expression in sensory neurons. We hypothesize that a reduction in mRNA expression of nAChR subunits represents a link to altered sensitivity under non-obstructive conditions.

AIMS: Alterations of the bladder sensory system are considered to contribute to detrusor overactivity (DO) when patients suffer from bladder outlet obstruction (BOO). The urothelium is one part of this sensory system and it harbors a non-neuronal cholinergic system (NNCS). We aimed to investigate if BOO causes alterations in the NNCS. MAIN
METHODS: Urothelial specimens were collected by endoscopy from six male controls and eight male patients suffering from BOO and DO. The samples were examined by immunofluorescence (IF) and real-time RT-PCR for high-affinity choline transporter-1 (CHT1), choline acetyltransferase (ChAT), vesicular acetylcholine transporter (VAChT), organic cation transporters OCT1-3, muscarinic receptor (mAChR) subtypes M1-M5 and nicotinic receptor (nAChR) subunits alpha7, alpha9 and alpha10. KEY FINDINGS: ChAT, VAChT and OCT2 are not present in the male urothelium. Real-time RT-PCR and IF detected all other investigated targets. Rank order of expression was M2>>M3=M5>M4=M1 for mAChR subtypes and alpha7>>alpha10>alpha9 for nAChR subunits. Statistical analysis of RT-PCR results did not detect significant differences between patients and controls. Only IF detected differences between both groups: alpha9-Immunolabeling was increased in all BOO/DO patients. SIGNIFICANCE: BOO does not induce considerable alterations of the human urothelial NNCS on mRNA level. Expression of mAChRs, CHT1, OCT1 and OCT3 is not significantly affected by BOO. Thus, transport mechanisms for choline and acetylcholine (ACh) stay unaltered. BOO increases immunolabeling of alpha9-nAChR but whether this sole finding contributes to the onset of DO seems questionable. Comparing the present results with our previous work, the urothelial NNCS does not differ between men and women.

AIMS: Functional nicotinic acetylcholine receptors (nAChR) have been identified in airway epithelia and their location in the apical and basolateral membrane makes them targets for acetylcholine released from neuronal and non-neuronal sources. One function of nAChR in airway epithelia is their involvement in the regulation of transepithelial ion transport by activation of chloride and potassium channels. However, the mechanisms underlying this nicotine-induced activation of ion transport are not fully elucidated. Thus, the aim of this study was to investigate the involvement of adenylyl cyclases in the nicotine-induced ion current in mouse tracheal epithelium. MAIN
METHODS: To evaluate the nicotine-mediated changes of transepithelial ion transport processes electrophysiological Ussing chamber measurements were applied and nicotine-induced ion currents were recorded in the absence and presence of adenylyl cyclase inhibitors. KEY FINDINGS: The ion current changes induced by nicotine (100 muM, apical) were not altered in the presence of high doses of atropine (25 muM, apical and basolateral), underlining the involvement of nAChR. Experiments with the transmembrane adenylyl cyclase inhibitor 2'5'-dideoxyadenosine (50 muM, apical and basolateral) and the soluble adenylyl cyclase inhibitor KH7 (10 muM, apical and basolateral) both reduced the nicotine-mediated ion current to a similar extent. Yet, a statistically significant reduction was obtained only in the experiments with KH7. SIGNIFICANCE: This study indicates that nicotine binding to nAChR in mouse tracheal epithelium activates transepithelial ion transport involving adenylyl cyclase activity. This might be important for novel therapeutic strategies targeting epithelial ion transport mediated by the non-neuronal cholinergic system.

AIM: The airway epithelial surface is constantly exposed to inhaled environmental factors and pathogens. Bitter "tasting" bacterial products such as quorum sensing molecules (QSM) can be detected by solitary chemosensory cells of the upper respiratory tract. Recently, we have shown that tracheal brush cells are cholinergic chemosensory cells affecting the respiration upon stimulation with bitter substances. Here, we explore the hypothesis that tracheal brush cells are capable of detection of bacterial products such as QSM resulting in changes in respiration and in induction of local effects, e.g. regulation of mucociliary clearance. MAIN
METHODS: Functional analyses of respiration were performed in the trachea using a newly established model for investigation of respiration in spontaneously breathing anesthetized mice upon isolated tracheal stimulation. Influence of N-3-oxododecanoyl-homoserine lactone (3-OxoC(12)-HSL) on cilia-driven particle transport speed (PTS) in the airways was investigated in acutely excised and submerged mouse tracheae. KEY FINDINGS: 3-OxoC(12)-HSL, a Pseudomonas aeruginosa quorum sensing autoinducer, caused a drop in the respiratory rate 2 min after the application at the mucosal surface. The 3-OxoC(12)-HSL-induced effect on respiration was abolished by inhibition of nicotinic receptors with mecamylamine and by removal of the respiratory epithelium. At the same concentration, 3-OxoC(12)-HSL enhanced significantly PTS on the mucosal surface. SIGNIFICANCE: We conclude that cholinergic airway epithelial cells sense bacterial QSM in the airway lining fluid and communicate this to the CNS via ACh release and nicotinic stimulation of sensory neurons. In addition, QSM enhance PTS.

The luminal composition of the auditory tube influences its function. The mechanisms involved in the monitoring are currently not known. For the lower respiratory epithelium, such a sentinel role is carried out by cholinergic brush cells. Here, using two different mouse strains expressing eGFP under the control of the promoter of choline acetyltransferase (ChAT), we show the presence of solitary cholinergic villin-positive brush cells also in the mouse auditory tube epithelium. They express the vesicular acetylcholine (ACh) transporter and proteins of the taste transduction pathway such as alpha-gustducin, phospholipase C beta 2 (PLC(beta2)) and transient receptor potential cation channel subfamily M member 5 (TRPM5). Immunoreactivity for TRPM5 and PLCbeta2 was found regularly, whereas alpha-gustducin was absent in approximately 15% of the brush cells. Messenger RNA for the umami taste receptors (TasR), Tas1R1 and 3, and for the bitter receptors, Tas2R105 and Tas2R108, involved in perception of cycloheximide and denatonium were detected in the auditory tube. Using a transgenic mouse that expresses eGFP under the promotor of the nicotinic ACh receptor alpha3-subunit, we identified cholinoceptive nerve fibers that establish direct contacts to brush cells in the auditory tube. A subpopulation of these fibers displayed also CGRP immunoreactivity. Collectively, we show for the first time the presence of brush cells in the auditory tube. These cells are equipped with all proteins essential for sensing the composition of the luminal microenvironment and for communication of the changes to the CNS via attached sensory nerve fibers.

AIMS: In the oviduct, muscarinic acetylcholine receptors (MR) are linked with motility regulation and nicotinic receptors (nAChR) with ectopic pregnancy. We here aimed to determine the repertoire of cholinergic receptor expression in the murine oviduct and their functional coupling to regulation of intracellular calcium concentration ([Ca(2+)](i)). MAIN
METHODS: Cholinergic receptor transcripts were assessed by RT-PCR in oviductal segments (ampulla, isthmus, uterotubar junction) in all cyclic stages and pregnancy, and in laser-microdissected samples of epithelium and smooth muscle, nAChR subunit alpha3 distribution in tissue sections using an appropriate genetic reporter mouse strain. [Ca(2+)](i) responses were monitored in ciliated and non-ciliated oviductal cells isolated from wild-type and MR subtypes 1 and 3 gene deficient mice. KEY FINDINGS: Transcripts for all MR subtypes (M1-M5) are constantly expressed whereas there is some variability in nAChR expression from individual to individual. The qualitative expression pattern is independent from the hormonal status of the animal, except for nAChR alpha7, which is less present during pregnancy. The epithelium expresses M1, M3, nAChR alpha7 (data from laser-assisted microdissection) and nAChR alpha3 (ultrastructural investigation of reporter mice). MR dominate over nAChR in increasing [Ca(2+)](i) with being M3 the major, but not sole subtype driving this effect. The general nAChR inhibitor mecamylamine enhances muscarinic and purinergic responses. SIGNIFICANCE: In conclusion, the murine oviduct is endowed with a multiplicity of muscarinic and nicotinic receptors subtypes that, with respect to regulation of [Ca(2+)](i), are inversely linked to each other. The major, but not sole, cholinergic receptor driving increase in [Ca(2+)](i) is M3.

In the epithelium of the lower airways, a cell type of unknown function has been termed "brush cell" because of a distinctive ultrastructural feature, an apical tuft of microvilli. Morphologically similar cells in the nose have been identified as solitary chemosensory cells responding to taste stimuli and triggering trigeminal reflexes. Here we show that brush cells of the mouse trachea express the receptors (Tas2R105, Tas2R108), the downstream signaling molecules (alpha-gustducin, phospholipase C(beta2)) of bitter taste transduction, the synthesis and packaging machinery for acetylcholine, and are addressed by vagal sensory nerve fibers carrying nicotinic acetylcholine receptors. Tracheal application of an nAChR agonist caused a reduction in breathing frequency. Similarly, cycloheximide, a Tas2R108 agonist, evoked a drop in respiratory rate, being sensitive to nicotinic receptor blockade and epithelium removal. This identifies brush cells as cholinergic sensors of the chemical composition of the lower airway luminal microenvironment that are directly linked to the regulation of respiration.

BACKGROUND: Chronic allograft vasculopathy (CAV) is an important aspect of chronic allograft injury, which limits the long-term success of renal transplantation. The pathogenesis of CAV is ill defined, and no effective therapies exist. Acute rejection episodes are a major risk factor for CAV. Recently, we demonstrated that leukocytes, which strongly accumulate in allograft blood vessels during fatal acute rejection, produce acetylcholine (ACh), which has the potential to provoke CAV. Herein, we test the hypothesis that ACh is also produced by leukocytes during the development of CAV. METHODS: Kidneys were transplanted in the Fischer 344 to Lewis rat strain combination, an established experimental model for CAV. Isografts were performed in Lewis rats. The capacity of intravascular graft leukocytes to synthesize ACh was investigated during reversible acute rejection on day 9 posttransplantation and during the process of vascular remodeling on day 42. Furthermore, allograft recipients were treated with rivastigmine, which blocks enzymatic degradation of ACh. RESULTS: The protein expression of the high-affinity choline transporter-1 and choline acetyltransferase was increased in leukocytes from allografts on day 9 and 42 posttransplantation. In addition, leukocytes accumulating in the lumina of allograft blood vessels were by far more numerous compared with isografts. In line with our hypothesis, ACh itself was detected by high-pressure liquid chromatography in graft leukocytes but not in leukocytes from untreated kidneys. Treatment with rivastigmine drastically exacerbated CAV compared with placebo. CONCLUSION: We suggest that endogenous ACh contributes to the pathogenesis of CAV and may be a promising target for novel therapies preventing CAV.

During acute rejection, large numbers of leukocytes accumulate in the blood vessels of experimental renal allografts. About 70% of them are activated, cytotoxic monocytes that appear to be involved in allograft destruction. ACh exerts anti-inflammatory effects upon monocytes/macrophages and has been proposed to be a key player in neuroimmunological interactions. Its short half-life, however, makes it unlikely that neuronal ACh affects blood leukocytes. Renal transplantation was performed in the allogeneic DA to LEW and in the isogeneic LEW to LEW rat strain combination. Intravascular leukocytes were harvested after 4 days, and the expression of CHT1, cChAT, pChAT, and nAChR subunits was investigated by RT-PCR, immunoblotting, and immunohistochemistry. Monocytes were identified by double-labeling with ED1-antibody, directed to a CD68-like antigen. ACh content was measured by HPLC. [Ca(2+)](i) was monitored by Fura-2. Intravascular graft leukocytes express CHT1 and cChAT mRNA and protein and pChAT protein. Their expression is strongly up-regulated in vivo during acute allograft rejection. Immunohistochemistry revealed CHT1, cChAT, and pChAT protein in ED1-positive monocytes. The ACh content of allograft intravascular leukocytes was sixfold higher than that of isografts. Intravascular leukocytes express nAChR subunits, and an ATP-induced increase in [Ca(2+)](i) was augmented in vitro by a nAChR inhibitor in allograft but not isograft leukocytes. Intravascular graft leukocytes, among them monocytes, up-regulate non-neuronal ACh synthesis and develop auto-/paracrine cholinergic attenuation of ATP signaling during acute allograft rejection.

The success of clinical lung transplantation is poor in comparison to other solid organ transplants and novel therapeutic approaches are badly needed. In the view of the recent discovery of anti-inflammatory pathways mediated via nicotinic acetylcholine receptors, we investigated changes in this system in pulmonary isografts and allografts by immunohistochemistry. Lung transplantation was performed in the isogeneic Lewis to Lewis rat strain combination. For allogeneic transplantation Dark Agouti rats were used as donors. Nicotinic alpha9 and alpha10 acetylcholine receptor subunits were detected on alveolar macrophages as well as in the lung parenchyma of native and transplanted lungs. The expression of both receptor subunits was up-regulated in the parenchyma of day 4 allografts. These allografts were characterized by accumulations of alveolar macrophages strongly expressing the alpha9 and the alpha10 receptor subunit. Therapeutic application of nicotinic agonists might down-modulate pro-inflammatory functions of alveolar macrophages and protect pulmonary transplants.

The bladder urothelium not only provides a diffusion barrier but it also serves a sensor function and releases signalling molecules that are considered to act in a paracrine and autocrine fashion, e.g. by acetylcholine. Its actions are conferred by two classes of receptors, i.e. G-protein-coupled muscarinic receptors (MR) and ionotropic nicotinic receptors (nAChR). In this study we set out to determine the expression and distribution of all MR subtypes (M1R-M5R) and nAChR alpha-subunits 7, 9 and 10 in the human urothelium by means of RT-PCR and immunohistochemistry, respectively. Real-time RT-PCR revealed a rank order of MR subtype expression of M2R>>M3R=M5R>M4R=M1R. Immunohistochemistry demonstrated differential distribution patterns with M1R being restricted to basal cells, M2R nearly exclusively found in umbrella cells, whereas M3R and M4R were homogenously distributed and M5R was seen in a decreasing gradient from luminal to basal. As for nAChR alpha-subunits, rank order of expression is alpha7>>alpha10>alpha9, and they were observed throughout the urothelium with a gradient decreasing from luminal to basal in intensity. In conclusion, the human urothelium carries multiple cholinergic receptor subtypes, with predominant expression of M2R, M3R and alpha7-nAChR. Their distribution as well as that of the less expressed subtypes is layer-specific in the urothelium. In view of the multiplicity of pathways to which different cholinergic receptor subtypes are coupled, we propose that this layer-specific distribution serves to stratify cholinergic regulation of human urothelial function.

Administration of recombinant human keratinocyte growth factor (rHuKGF, Delta23N-KGF, palifermin) protects the lung against a variety of injurious stimuli. The exact mechanisms leading to lung protection are unknown. Alterations in the non-neuronal cholinergic system of the lung might be involved, as vital pulmonary functions are regulated by acetylcholine. Here, we investigated the effect of KGF on the expression of nicotinic acetylcholine receptor subunits alpha7, alpha9 and alpha10 in rat lungs. Adult rats were treated via intratracheal instillation with rHuKGF or with an equivalent volume of PBS. The expression of nicotinic acetylcholine receptor subunits was analyzed by real-time RT-PCR, immunoblotting and immunohistochemistry. Treatment with rHuKGF led to a decreased expression of nicotinic receptor subunit alpha7 in the total lung. In contrast, the expression of the receptor subunits alpha9 and alpha10 was up-regulated. In conclusion, nicotinic acetylcholine receptors are differentially regulated by KGF treatment in vivo, which might result in changes in the biological effects of acetylcholine.

Keratinocyte growth factor protects the lung against various injurious stimuli. The protective mechanisms, however, are not yet fully understood. The aim of this study is to determine the influence of keratinocyte growth factor on the pulmonary capacity to synthesize acetylcholine, a potent regulator of pulmonary functions which is potentially involved in lung damage. Rats were treated twice (days 1 and 2) intratracheally with keratinocyte growth factor and analyzed at day 4. The mRNA expression of choline acetyltransferase - the acetylcholine synthesizing enzyme - was analyzed by real-time RT-PCR in the lung and in isolated alveolar epithelial type II cells. Choline acetyltransferase protein was assessed by immunoblotting and immunohistochemistry. Finally, pulmonary acetylcholine content was assessed biochemically. Keratinocyte growth factor-treatment led to decreased levels of choline acetyltransferase mRNA in the lung and in isolated alveolar epithelial type II cells. Accordingly, pulmonary choline acetyltransferase protein levels were reduced and pulmonary acetylcholine content declined from 2.8 nmol (control) to 0.4 nmol acetylcholine per gram of wet weight. In conclusion, the present data show that the potent regulator of pulmonary functions, acetylcholine, is produced by the major pulmonary target cell of keratinocyte growth factor, that is alveolar epithelial type II cells. Acetylcholine synthesis is down-regulated by keratinocyte growth factor administration which might contribute to lung protection and to harmonize surfactant homeostasis under conditions of keratinocyte growth factor-induced alveolar epithelial type II cell hyperplasia.

Acetylcholine (ACh), derived both from nerve fibres and from non-neuronal sources such as epithelial cells, is a major regulator of airway function. There is evidence that dysfunction of the neuronal cholinergic system is involved in the pathogenesis of asthma. Here, we asked whether the pulmonary non-neuronal ACh-synthesis and release machinery is altered in a rat and a mouse model of allergic airway disease. Animals were sensitized against ovalbumin, challenged by allergen inhalation, and sacrificed 24 or 48 h later. Targets of investigation were the high-affinity choline transporter-1 (CHT1), that mediates cellular uptake of choline, the ACh-synthesizing enzyme choline acetyltransferase (ChAT), the vesicular ACh transporter (VAChT), and the polyspecific organic cation transporters (OCT1-3), which are able to translocate choline and ACh across the plasma membrane. With cell-type specific distribution patterns, immunohistochemistry identified these proteins in airway epithelial cells and alveolar macrophages. Real-time RT-PCR revealed significant decreases in ChAT-, CHT1-, VAChT-, OCT-mRNA in the lung of sensitized and allergen challenged animals. These data were supported by immunohistochemistry, demonstrating reduced labeling intensity of airway epithelial cells. ChAT-, CHT1-, VAChT-, and OCT1-mRNA were also significantly reduced in cells recovered by bronchoalveolar lavage from sensitized and challenged rats. In conclusion, the pulmonary non-neuronal cholinergic system is down-regulated in acute allergic airway inflammation. In view of the role of ACh in maintenance of cell-cell-contacts, stimulation of fluid-secretion and of ciliary beat frequency, this down-regulation may contribute to epithelial shedding and ciliated cell dysfunction that occur in this pathological condition.

OBJECTIVES: Previous studies provided indirect evidence for urothelial synthesis and release of acetylcholine (ACh). We aimed to determine directly the ACh content in the urothelium and to characterize the molecular components of its synthesis and release machinery.
METHODS: The study was performed on mouse bladder and abraded urothelium, and human mucosal bladder biopsies. ACh content was measured by high-performance liquid chromatography-electrochemical. Reverse transcriptase-polymerase chain reaction (RT-PCR) and immunohistochemistry served to investigate expression of ACh-synthesizing enzymes-choline acetyltransferase (ChAT) and carnitine acetyltransferase (CarAT)-vesicular ACh transporter (VAChT), and polyspecific organic cation transporters (OCTs; isoforms 1-3). Transfected cells served to investigate whether the anticholinergic drug trospium chloride interferes with ACh-transporting OCTs.
RESULTS: ACh is present in the urothelium in a nanomolar range per gram of wet weight. RT-PCR data support the presence of CarAT but not ChAT. VAChT, used by neurons to shuffle ACh into synaptic vesicles, is detected in subepithelial cholinergic nerve fibres, but not by RT-PCR or immunohistochemistry in the urothelium. OCT1 and OCT3 are expressed by the urothelium. The quarternary ammonium base trospium chloride inhibits cation transport by OCTs with a potency rank order of OCT2 (IC(50)=0.67+/-0.42micromol/l)>OCT1 (IC(50)=6.2+/-2.1micromol/l)>OCT3 (IC(50)=871+/-177micromol/l).
CONCLUSIONS: This study demonstrates a urothelial non-neuronal cholinergic system that differs widely from that of neurons with respect to molecular components of the ACh synthesis and release machinery. Consequently, these two systems might be differentially targeted by pharmacologic approaches.

Acetylcholine (ACh) and its receptors play a crucial role in bladder physiology. Here, we investigated the presence of muscarinic receptor subtypes (MR) and nicotinic acetylcholine receptor (nAChR) alpha-subunits in the mouse urothelium by RT-PCR and immunohistochemistry. With RT-PCR, we detected mRNAs coding for all of the five different MR subtypes and for the nicotinic receptor subunits alpha2, alpha4, alpha5, alpha6, alpha7, alpha9 and alpha10, whereas the alpha3-subunit was not expressed. Using immunohistochemistry, we localised a panel of acetylcholine receptors in the different layers of the murine bladder urothelium, with predominant appearance in the basal plasma membrane of the basal cell layer and in the apical membrane of the umbrella cells. M2R and subunit alpha9 were observed exclusively in the umbrella cells, whereas the MR subtypes 3-5 and the nAChR subunits alpha4, alpha7 and alpha10 were also detected in the intermediate and basal cell layers. The subunit alpha5 was localised only in the basal cell layer. In conclusion, the murine urothelium expresses multiple cholinergic receptors, including several subtypes of both MR and nAChR, which are differentially distributed among the urothelial cell types. Since these receptors have different electrophysiological and pharmacological properties, and therefore are considered to be responsible for different cellular responses to ACh, this differential distribution is expected to confer cell type-specificity of cholinergic regulation in the bladder urothelium.

Neuronal nicotinic acetylcholine receptors (nAChRs) play an essential role in immunomodulation of macrophages. In particular, the alpha7 subunit confers inhibition of the systemic inflammatory response to bacterial lipopolysaccharide, thereby being the crucial element of the cholinergic anti-inflammatory pathway (Borovikova et al., 2000; Pavlov et al., 2003; Wang et al., 2003). In the murine lung, nicotine also exerts anti-inflammatory effects (Blanchet et al., 2004), but at least in murine alveolar macrophage cell lines the alpha7 subunit has not been detected (Matsunaga et al., 2001). On this background we investigated the expression of the nAChR subunits (alpha2-alpha7, alpha9, alpha10, beta2-beta4) on freshly isolated murine alveolar macrophages by immunohistochemistry and RT-PCR.

Acetylcholine (ACh) has been shown to modulate the function of mononuclear leukocytes, both by muscarinic and nicotinic ACh receptors. Acute stimulation of lymphocytes with ACh or muscarinic agonists enhances proinflammatory functions, whereas chronic application of the ACh agonist nicotine has an anti-inflammatory effect (Geng et al., 1996; Kawashima and Fujii, 2003). In macrophages, acute treatment with nicotine down-modulates effector functions (Wang et al., 2003, 2004). ACh regulating leukocytes might originate from the nervous system. However, once released, ACh is quickly degraded. Relevant concentrations occur only in the direct vicinity of nerve endings. Non-neuronal ACh acting in a paracrine or autocrine fashion is more likely to influence immune functions. Lymphocytes express all enzymes needed for ACh synthesis, including choline acetyltransferase (ChAT). In the rat, alternative splicing generates common ChAT and peripheral ChAT (pChAT). Up to now, ChAT expression by monocytes has not been demonstrated. We investigate pChAT in monocytes in an experimental model of acute renal allograft rejection. Inside the blood vessels of the transplant, huge numbers of activated, cytotoxic monocytes accumulate and probably contribute to graft destruction (Grau et al., 2001).

BACKGROUND: It has been proposed that serotonin (5-HT)-mediated constriction of the murine trachea is largely dependent on acetylcholine (ACh) released from the epithelium. We recently demonstrated that ACh can be released from non-neuronal cells by corticosteroid-sensitive polyspecific organic cation transporters (OCTs), which are also expressed by airway epithelial cells. Hence, the hypothesis emerged that 5-HT evokes bronchoconstriction by inducing release of ACh from epithelial cells via OCTs.
METHODS: We tested this hypothesis by analysing bronchoconstriction in precision-cut murine lung slices using OCT and muscarinic ACh receptor knockout mouse strains. Epithelial ACh content was measured by HPLC, and the tissue distribution of OCT isoforms was determined by immunohistochemistry.
RESULTS: Epithelial ACh content was significantly higher in OCT1/2 double-knockout mice (42 +/- 10 % of the content of the epithelium-denuded trachea, n = 9) than in wild-type mice (16.8 +/- 3.6 %, n = 11). In wild-type mice, 5-HT (1 microM) caused a bronchoconstriction that slightly exceeded that evoked by muscarine (1 microM) in intact bronchi but amounted to only 66% of the response to muscarine after epithelium removal. 5-HT-induced bronchoconstriction was undiminished in M2/M3 muscarinic ACh receptor double-knockout mice which were entirely unresponsive to muscarine. Corticosterone (1 microM) significantly reduced 5-HT-induced bronchoconstriction in wild-type and OCT1/2 double-knockout mice, but not in OCT3 knockout mice. This effect persisted after removal of the bronchial epithelium. Immunohistochemistry localized OCT3 to the bronchial smooth muscle. CONCLUSION: The doubling of airway epithelial ACh content in OCT1/2-/- mice is consistent with the concept that OCT1 and/or 2 mediate ACh release from the respiratory epithelium. This effect, however, does not contribute to 5-HT-induced constriction of murine intrapulmonary bronchi. Instead, this activity involves 1) a non-cholinergic epithelium-dependent component, and 2) direct stimulation of bronchial smooth muscle cells, a response which is partly sensitive to acutely administered corticosterone acting on OCT3. These data provide new insights into the mechanisms involved in 5-HT-induced bronchoconstriction, including novel information about non-genomic, acute effects of corticosteroids on bronchoconstriction.

For the murine trachea, it has been reported that constriction evoked by serotonin (5-HT) is largely dependent on acetylcholine (ACh) released from the epithelium, owing to the sensitivity of the 5-HT response to epithelium removal, sensitivity to atropine, and insensitivity to tetrodotoxin (Moffatt et al., 2003). Consistent with this assumption, the respiratory epithelium contains ACh, its synthesizing enzyme, and the high-affinity choline transporter CHT1 (Reinheimer et al., 1996; Pfeil et al., 2003; Proskocil et al., 2004). Recently, we demonstrated that ACh can be released from non-neuronal cells by corticosteroid-sensitive polyspecific organic cation transporters (OCTs), which are also expressed by airway epithelial cells (Lips et al., 2005). Hence, we proposed that 5-HT evokes release of ACh from epithelial cells via OCTs and that this epithelial-derived ACh induces bronchoconstriction. We tested this hypothesis in a well-established model of videomorphometric analysis of bronchial diameter in precision-cut murine lung slices utilizing epithelium removal to assess the role of the epithelium, OCT mouse knockout (KO) strains to assess the role of OCT isoforms, and muscarinic receptor M2/M3 double-KO mice to assess the cholinergic component of 5-HT induced bronchoconstriction, as bronchi of this strain are entirely unresponsive to cholinergic stimulation(Struckmann et al., 2003).

Fast excitatory synaptic transmission in sympathetic ganglia is mediated by nicotinic acetylcholine receptors (nAChRs). Although it is known that the nAChR alpha7-subunit occurs in sympathetic ganglia, the expression of the recently cloned subunit alpha10 (Elgoyhen et al., 2001; Lustig et al., 2001; Sgard et al., 2002) has not been analyzed. Until now, functional receptors containing alpha10-subunits have been found only in combination with alpha9-subunits (Elgoyhen et al., 2001; Lustig et al., 2001; Sgard et al., 2002). The alpha9-subunit exhibits a restricted expression pattern, whereas the alpha10-subunit is expressed more widely. This broad distribution resembles more closely that known for subunit alpha7 than for subunit alpha9. On this background, we investigated the distribution of nAChR subunits alpha7, alpha9, and alpha10 in rat sympathetic ganglia and studied a possible interaction between subunit alpha7 and potential partners by double-labeling immunofluorescence and fluorescence resonance energy transfer (FRET) (Kam et al., 1995; Jares-Erijman and Jovin, 2003).

Nociceptive primary afferent neurons carry nicotinic acetylcholine receptors (nAChRs). Using RTPCR, mRNAs for all alpha-subunits have been identified in rat dorsal root ganglia (DRG) (Genzen et al., 2001; Lips et al., 2002), but the responses of nociceptive neurons to nicotine are not uniform and the cellular distribution of nAChRs within DRG, in general, and among functionally different subtypes of primary afferent neurons, in particular, are only partially resolved (Rau et al., 2005). These diverse actions might suggest the presence of various nAChR isoforms that are operative under different conditions. The present study was aimed to extend previous studies on nAChRs that contain subunits alpha4, alpha7, and alpha10 in providing data for alpha3- and alpha5-subunit-containing nAChRs (Haberberger et al., 2004; Papadopolou et al., 2004). To this end, calcium-imaging and double-labeling immunofluorescence with nAChR alpha-subunit-specific antibodies, in combination with markers for nociceptive neurons (TRPV1, I-B4), were applied.

Smoking during pregnancy causes low birth weight, premature delivery, neonatal morbidity, and mortality. Nicotine is a main pathogenic compound of cigarette smoke, and depresses active amino-acid uptake by human placental villi. It binds to the acetylcholine binding site of the alpha-subunits of nicotinic acetylcholine receptors (nAChR). Eight different neuronal nAChR alpha-subunits have been identified in mammals. Here, we investigated their localisation and distribution in the human and rat placenta by RT-PCR and immunofluorescence. The mRNAs of all alpha-subunits are expressed in the human and rat placenta. Immunohistochemically, subunits alpha2-5, alpha7, alpha9 and alpha10 are localised in different combinations in rat cytotrophoblast, human and rat syncytiotrophoblast, vascular smooth muscle cells, endothelial cells, Hofbauer cells, human amnion epithelium and rat visceral yolk sac epithelium. Thus, all human and rat placental cell types exhibit receptor subunits with binding sites for the endogenous ligand ACh and nicotine. ACh is suggested to be an important placental signalling molecule that, through stimulation of nAChR, controls the uptake of nutrients, blood flow and fluid volume in placental vessels, and the vascularisation during placental development. Chronic stimulation of nAChR by nicotine might result in unbalanced receptor activation or functional desensitisation followed by the known pathological effects of smoking.

We investigated the occurrence and distribution of the ligand-binding alpha-subunits of nicotinic acetylcholine receptors in the rat arterial system in situ by means of RT-PCR and immunohistochemistry. Except the alpha9-subunit, all other mammalian non-muscular alpha-subunits were expressed in the arterial wall--either in endothelial or in smooth muscle cells--suggesting it as a direct target of nicotine and endogenous acetylcholine. The distribution pattern of alpha-subunits found in smooth muscle cells varied considerably among the individual elastic, muscular and intraparenchymal arteries investigated, suggesting that non-neuronal cholinergic signalling via nicotinic receptors in the vascular wall includes components that are highly specific for individual arteries.

Uptake of choline by the high-affinity choline transporter CHT1 is the rate-limiting step in neuronal acetylcholine (ACh) synthesis. Here, we investigated by RT-PCR, in-situ hybridisation, immunohistochemistry, and Western blotting whether CHT1 is also expressed in cholinergic epithelia. CHT1-mRNA and -protein were detected in keratinocytes of human skin, rat skin and tongue, the human keratinocyte cell line HaCaT, and the ciliated cells of the rat tracheal epithelium. Immunohistochemically, CHT1 was predominantly localized to the epithelial cell membranes, in case of ciliated tracheal cells it was restricted to the apical membrane. This is the first study to demonstrate the expression of CHT1 in non-neuronal cells. The close apposition of CHT1 to reported sites of localization of choline acetyltransferase in these cells is strongly in favour of ACh synthesis being fuelled by choline uptake via CHT1 in these epithelia.

Several ganglionic nicotinic acetylcholine receptor (nAChR) types are abundantly expressed in nonneuronal locations, but their functions remain unknown. We found that keratinocyte alpha7 nAChR controls homeostasis and terminal differentiation of epidermal keratinocytes required for formation of the skin barrier. The effects of functional inactivation of alpha7 nAChR on keratinocyte cell cycle progression, differentiation, and apoptosis were studied in cell monolayers treated with alpha-bungarotoxin or antisense oligonucleotides and in the skin of Acra7 homozygous mice lacking alpha7 nAChR channels. Elimination of the alpha7 signaling pathway blocked nicotine-induced influx of 45Ca2+ and also inhibited terminal differentiation of these cells at the transcriptional and/or translational level. On the other hand, inhibition of the alpha7 nAChR pathway favored cell cycle progression. In the epidermis of alpha7-/- mice, the abnormalities in keratinocyte gene expression were associated with phenotypic changes characteristic of delayed epidermal turnover. The lack of alpha7 was associated with up-regulated expression of the alpha3 containing nAChR channels that lack alpha5 subunit, and both homomeric alpha9- and heteromeric alpha9alpha10-made nAChRs. Thus, this study demonstrates that ACh signaling through alpha7 nAChR channels controls late stages of keratinocyte development in the epidermis by regulating expression of the cell cycle progression, apoptosis, and terminal differentiation genes and that these effects are mediated, at least in part, by alterations in transmembrane Ca2+ influx.

The occurrence and distribution of the muscarinic M2-receptor subtype (M2R) was investigated in rat thoracic dorsal root ganglia (DRG). Messenger RNA for M2R was demonstrated by RT-PCR in total RNA from DRG. Immunoreactivity to M2R-protein was localized to 26% of sensory neurons, the majority of them (85%) belonging to the size class of 25-40 microm in diameter. Double-labeling (immuno)histochemistry revealed that all M2R-immunoreactive neurons bind the lectin, I-B4, whereas they are generally devoid of substance P-immunoreactivity. These data show the presence of M2R on a subpopulation of presumably nociceptive primary afferent neurons, thereby extending previous pharmacological and electrophysiological studies that indicated a role of M2R and/or M4R in inhibition of calcium channel currents in rat sensory neurons (Wanke, E., Bianchi, L., Mantegazza, M., Guatteo, E., Macinelli, E. and Ferroni, A., Muscarinic regulation of Ca2+ currents in rat sensory neurons: channel and receptor types, dose-response relationships and cross-talk pathways. Eur. J. Neurosci., 6 (1994) 381-391).