Oxygen Sensing in Early Life.

From birth, animals should possess functional machinery to appropriately regulate its respiration. This machinery has to detect the available oxygen quantity in order to efficiently modulate breathing movements in accordance with body requirements. The chemosensitivity process responsible for this detection is known to be mainly performed by carotid bodies. However, pulmonary neuroendocrine cells, which are mainly gathered in neuroepithelial bodies, also present the capability to exert chemosensitivity. The goal of this article is to put in perspective the potential complementarity in the activity of these two peripheral chemosensors in the context of neonatal oxygen chemosensitivity.

Pulmonary neuroepithelial bodies are polymodal airway sensors: evidence for CO2/H+ sensing.

Pulmonary neuroepithelial bodies (NEB) in mammalian lungs are thought to function as airway O2 sensors that release serotonin (5-HT) in response to hypoxia. Direct evidence that NEB cells also respond to airway hypercapnia/acidosis (CO2/H(+)) is presently lacking. We tested the effects of CO2/H(+) alone or in combination with hypoxia on 5-HT release from intact NEB cells in a neonatal hamster lung slice model. For the detection of 5-HT release we used carbon fiber amperometry. Fluorescence Ca(2+) imaging method was used to assess CO2/H(+)-evoked changes in intracellular Ca(2+). Exposure to 10 and 20% CO2 or pH 6.8-7.2 evoked significant release of 5-HT with a distinct rise in intracellular Ca(2+) in hamster NEBs. This secretory response was dependent on the voltage-gated entry of extracellular Ca(2+). Moreover, the combined effects of hypercapnia and hypoxia were additive. Critically, an inhibitor of carbonic anhydrase (CA), acetazolamide, suppressed CO2/H(+)-mediated 5-HT release. The expression of mRNAs for various CA isotypes, including CAII, was identified in NEB cells from human lung, and protein expression was confirmed by immunohistochemistry using a specific anti-CAII antibody on sections of human and hamster lung. Taken together our findings provide strong evidence for CO2/H(+) sensing by NEB cells and support their role as polymodal airway sensors with as yet to be defined functions under normal and disease conditions.

NOX2 (gp91phox) is a predominant O2 sensor in a human airway chemoreceptor cell line: biochemical, molecular, and electrophysiological evidence.

Pulmonary neuroepithelial bodies (NEBs), composed of clusters of amine [serotonin (5-HT)] and peptide-producing cells, are widely distributed within the airway mucosa of human and animal lungs. NEBs are thought to function as airway O(2)-sensors, since they are extensively innervated and release 5-HT upon hypoxia exposure. The small cell lung carcinoma cell line (H146) provides a useful model for native NEBs, since they contain (and secrete) 5-HT and share the expression of a membrane-delimited O(2) sensor [classical NADPH oxidase (NOX2) coupled to an O(2)-sensitive K(+) channel]. In addition, both native NEBs and H146 cells express different NADPH oxidase homologs (NOX1, NOX4) and its subunits together with a variety of O(2)-sensitive voltage-dependent K(+) channel proteins (K(v)) and tandem pore acid-sensing K(+) channels (TASK). Here we used H146 cells to investigate the role and interactions of various NADPH oxidase components in O(2)-sensing using a combination of coimmunoprecipitation, Western blot analysis (quantum dot labeling), and electrophysiology (patchclamp, amperometry) methods. Coimmunoprecipitation studies demonstrated formation of molecular complexes between NOX2 and K(v)3.3 and K(v)4.3 ion channels but not with TASK1 ion channels, while NOX4 associated with TASK1 but not with K(v) channel proteins. Downregulation of mRNA for NOX2, but not for NOX4, suppressed hypoxia-sensitive outward current and significantly reduced hypoxia -induced 5-HT release. Collectively, our studies suggest that NOX2/K(v) complexes are the predominant O(2) sensor in H146 cells and, by inference, in native NEBs. Present findings favor a NEB cell-specific plasma membrane model of O(2)-sensing and suggest that unique NOX/K(+) channel combinations may serve diverse physiological functions.

Novel insights in the neurochemistry and function of pulmonary sensory receptors.

Afferent nerves in the airways and lungs contribute to optimisation of the breathing pattern, by providing local pulmonary information to the central nervous system. Airway sensory nerve terminals are consequently tailored to detect changes readily in the physical and chemical environment, thereby leading to a variety of respiratory sensations and reflex responses. Most intrapulmonary nerve terminals arise from fibres travelling in the vagal nerve, allowing a classification of "sensory airway receptors", based on their electrophysiologically registered action potential characteristics. Nowadays, at least six subtypes of electrophysiologically characterised vagal sensory airway receptors have been described, including the classical slowly and rapidly adapting (stretch) receptors and C-fibre receptors. The architecture of airways and lungs makes it, however, almost impossible to locate functionally the exact nerve terminals that are responsible for transduction of a particular intrapulmonary stimulus. With the advances in immunohistochemistry in combination with confocal microscopy, airway sensory receptor end organs can now be examined and evaluated objectively. Based on their "neurochemical coding", morphology, location and origin, three sensory receptor end organs are currently morphologically well characterised: smooth muscle-associated airway receptors (SMARs), neuroepithelial bodies (NEBs) and visceral pleura receptors (VPRs). The present information on the functional, morphological and neurochemical characteristics of these sensory receptors leads to important conclusions about their (possible) function. Currently, ex vivo lung models are developed that allow the selective visualisation of SMARs, NEBs and VPRs by vital staining. The described ex vivo models will certainly facilitate direct physiological studies of the morphologically and neurochemically identified airway receptors, thereby linking morphology to physiology by identifying in situ functional properties of a given receptor end organ.

Pulmonary neuroepithelial bodies as airway sensors: putative role in the generation of dyspnea.

The neuroepithelial bodies (NEB) of the intrapulmonary airways (AW) are multimodal AW sensors responding to a variety of stimuli including hypoxia, hypercarbia, and mechanical stretch. NEBs are richly innervated by a diverse population of mostly vagal afferent nerve fibers and owing to their early developmental maturation may be especially important during the perinatal period. This article reviews recent findings of NEB functional morphology and innervation, and postulates a role in the generation of dyspnea. This is based on their potential for transduction of dyspneic stimuli and findings of NEB cell abnormalities in a number of pulmonary disorders presenting with this symptom.

Purinergic signaling in the pulmonary neuroepithelial body microenvironment unraveled by live cell imaging.

Pulmonary neuroepithelial bodies (NEBs) are densely innervated groups of complex sensory airway receptors involved in the regulation of breathing. Together with their surrounding Clara-like cells, they exhibit stem cell potential through their capacity to regenerate depopulated areas of the epithelium following lung injury. We have employed confocal live cell imaging microscopy and novel electrophysiological techniques in a new ex vivo lung slice model to unravel potential purinergic signaling pathways within the NEB microenvironment. Quinacrine histochemistry indicated high amounts of vesicular ATP in NEB cells. Using a "reporter-patching" method adapted to create a uniquely sensitive and selective biosensor for the direct detection of ATP release from NEBs ex vivo, we demonstrated quantal ATP release from NEBs following their depolarization. Enhancing enzymatic extracellular ATP hydrolysis or inhibiting P2 receptors confirmed the central role of ATP in paracrine interactions between NEB cells and Clara-like cells. Combined calcium imaging, pharmacology, and immunohistochemistry showed that ligand-binding to functional P2Y(2) receptors underpins the activation of Clara-like cells. Hence, NEB cells communicate with their cellular neighbors in the NEB microenvironment by releasing ATP, which rapidly evokes purinergic activation of surrounding Clara-like cells. Besides ATP acting on the P2X(3) receptor expressing vagal sensory nerve terminals between NEB cells, local paracrine purinergic signaling within this potential stem cell niche may be important to both normal airway function, airway epithelial regeneration after injury, and/or the pathogenesis of small cell lung carcinomas.

Functional live cell imaging of the pulmonary neuroepithelial body microenvironment.

Pulmonary neuroepithelial bodies (NEBs) are densely innervated groups of neuroendocrine cells invariably accompanied by Clara-like cells. Together with NEBs, Clara-like cells form the so-called "NEB microenvironment," which recently has been assigned a potential pulmonary stem cell niche. Conclusive data on the nature of physiological stimuli for NEBs are lacking. This study aimed at developing an ex vivo mouse lung vibratome slice model for confocal live cell imaging of physiological reactions in identified NEBs and surrounding epithelial cells. Immunohistochemistry of fixed slices demonstrated that NEBs are almost completely shielded from the airway lumen by tight junction-linked Clara-like cells. Besides the unambiguous identification of NEBs, the fluorescent dye 4-Di-2-ASP allowed microscopic identification of ciliated cells, Clara cells, and Clara-like cells in live lung slices. Using the mitochondrial uncoupler FCCP and a mitochondrial membrane potential indicator, JC-1, increases in 4-Di-2-ASP fluorescence in NEB cells and ciliated cells were shown to represent alterations in mitochondrial membrane potential. Changes in the intracellular free calcium concentration ([Ca2+](i)) in NEBs and surrounding airway epithelial cells were simultaneously monitored using the calcium indicator Fluo-4. Application (5 s) of 50 mM extracellular potassium ([K+](o)) evoked a fast and reproducible [Ca2+](i) increase in NEB cells, while Clara-like cells displayed a delayed (+/- 4 s) [Ca2+](i) increase, suggestive of an indirect, NEB-mediated activation. The presented approach opens interesting new perspectives for unraveling the functional significance of pulmonary NEBs in control lungs and disease models, and for the first time allows direct visualization of local interactions within the NEB microenvironment.

Selective visualisation of neuroepithelial bodies in vibratome slices of living lung by 4-Di-2-ASP in various animal species.

Pulmonary neuroepithelial bodies (NEBs) are extensively innervated organoid groups of neuroendocrine cells that lie in the epithelium of intrapulmonary airways. Our present understanding of the morphology of NEBs is comprehensive, but direct physiological studies have so far been challenging because the extremely diffuse distribution of NEBs makes them inaccessible in vivo and because a reliable in vitro model is lacking. Our aim has been to optimise an in vitro method based on vibratome slices of living lungs, a model that includes NEBs, the surrounding tissues and at least part of their complex innervation. This in vitro model offers satisfactory access to pulmonary NEBs, provided that they can be differentiated from other tissue elements. The model was first optimised for living rat lung slices. Neutral red staining, reported to stain rabbit NEBs, proved unsuccessful in rat slices. On the other hand, the styryl pyridinium dye, 4-(4-diethylaminostyryl)-N-methylpyridinium iodide (4-Di-2-ASP), showed brightly fluorescent cell groups, reminiscent of NEBs, in the airway epithelium of living lung slices from rat. In addition, nerve fibres innervating the NEBs were labelled. The reliable and specific labelling of pulmonary NEBs by 4-Di-2-ASP was corroborated by immunostaining for protein gene-product 9.5. Live cell imaging and propidium iodide staining further established the acceptable viability of 4-Di-2-ASP-labelled NEB cells in lung slices, even over long periods. Importantly, the in vitro model and 4-Di-2-ASP staining procedure for pulmonary NEBs appeared to be equally reproducible in mouse, hamster and rabbit lungs. Diverse immunocytochemical procedures could be applied to the lung slices providing an opportunity to combine physiological and functional morphological studies. Such an integrated approach offers additional possibilities for elucidating the function(s) of pulmonary NEBs in health and disease.

Neuroepithelial bodies not connected to pulmonary slowly adapting stretch receptors.

Neuroepithelial bodies (NEBs) are believed to be connected with one of the known types of airway receptors. The present studies determined whether NEB afferents are pulmonary slowly adapting stretch receptors (SARs). NEBs are immunoreactive with antibodies against protein gene product (PGP) 9.5 and calcitonin gene-related peptide (CGRP), whereas SARs are reactive with antibody to Na(+)/K(+)-ATPase. Using histochemical staining in combination with confocal microscopy, we compared the morphology of NEBs and SARs in the rat. Our results show that NEBs and SARs are different in location, size, and shape. Double staining of airway tissues for PGP (or CGRP) plus Na(+)/K(+)-ATPase shows that NEBs and SARs do not co-localize. In addition, we electrophysiologically recorded single-unit activity of SARs from the cervical vagus nerve, identified their receptive fields, dissected them into blocks, and then double-stained and examined the receptor structures. We found that the blocks contain the SAR, but not NEB structures. Thus, we conclude that NEBs are not connected to SARs.

An overview of vagal airway receptors.

Breathing is critically depending on a variety of sensory feedbacks from multiple sources for its optimal performance. The sensory information from the lung and airways probably provides one of the most important feedbacks to adjust the respiratory controller to generate optimal breathing movements. Since Breuer and Hering made the seminal report regarding role of the vagus nerve in control of breathing in 1868, airway sensory receptors have been a subject for intensive and extensive studies. After more than a century investigation, our knowledge accumulates immensely, however, our understanding of the nature of these sensory receptors is still far from complete. This brief review provides an overview on this topic.

Na(+)/K(+) -ATPase as a marker for detecting pulmonary sensory receptors.

Pulmonary vagal afferents provide some of the most important breathing control inputs to the respiratory center. However, the structure of vagal receptors is not yet well known. Lack of an available and effective method to identify pulmonary receptors is the major limiting factor. Here we describe a new approach using confocal microscopy to examine the structure of immunohistochemically stained airway receptors by using Na(+)/K(+)-ATPase as a marker. This method permits detailed observation of pulmonary receptor structures and their relationship to target tissue in the rabbit. The parent axon has multiple branches that supply the receptor structure. Each structure has multiple endings that form leaf-like terminals. This technique permits examining pulmonary receptor structures in detail, and should assist in identifying the morphology of the receptors and the mechanisms of receptor activation.