Small-granule (neuro)endocrine cells in the infracardiac lobe of a hamster lung. Number, subtypes, and distribution

Alteration of pulmonary neuroendocrine cells during epithelial repair of naphthalene-induced airway injury

Whole-mount airway preparations isolated from the lungs of mice treated by intraperitoneal injection of naphthalene and allowed to recover for 5 days were examined for the distribution and abundance of solitary pulmonary neuroendocrine cells (PNECs) and neuroepithelial bodies (NEBs) along the main axial pathway of the right middle lobe. Sham mice treated with corn oil vehicle were examined in a similar manner. An antibody to calcitonin gene-related peptide, a neuroendocrine cell marker, was used to identify the location, size, and number of PNECs and NEBs in the airways. After naphthalene treatment and epithelial repair, NEBs were significantly increased along the walls of the airways as well as on branch point ridges. The surface area covered by NEBs composed of 20 or fewer PNECs was significantly enlarged after naphthalene treatment compared with control NEBs of an equivalent cell number. The PNEC number per square millimeter was also increased more than threefold above control values after naphthalene treatment. These findings provide further support for a key role of neuroendocrine cells in the reparative process of airway epithelial cell renewal after injury.

Neuroepithelial bodies as airway oxygen sensors

Since the discovery of neuroepithelial bodies (NEB) in the late 1930s, evidence has accumulated to suggest that these cells may function as hypoxia-sensitive airway sensors. Until recently, this hypothesis was based largely on morphological observations. The use of in vitro models of isolated NEB, combined with electrophysiological approaches, have provided direct evidence that NEB cells express a membrane-bound O2 sensor and are the transducers of hypoxic stimulus. Here, we review the historical evidence and current state of knowledge of the oxygen-sensing properties of NEB cells, comparison with other O2 sensing cells, as well as recent advances that have been made using molecular and electrophysiological techniques. The possible role of NEB in perinatal pulmonary pathophysiology is also discussed.

Exploration of the pulmonary circulation. Festschrift to Professor Donald Heath

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Ontogeny of endocrine cells in the respiratory system of Syrian golden hamsters. II. Intrapulmonary airways and alveoli

Results of this and the preceding study reveal 3 patterns of endocrine cell development in hamster airway. The first, a prenatal wave, begins in the larynx and sweeps down the extra- and intrapulmonary conducting airway to the bronchioloalveolar portals. Cells differentiate singly and in groups (presumptive neuroepithelial bodies, pNEBs), colocalize immunoreactivity for serotonin (5-HT) and calcitonin gene-related peptide (CGRP), and persist throughout adulthood. Postnatally a few cells also express calcitonin (CT). Appearance of 5-HT and CGRP staining correlates with the onset of local, NEB-associated mitogenesis in fetal hamster airway epithelium. The second pattern begins after birth and is unique to the larynx and cartilaginous trachea. It involves differentiation of single cells which stain for CGRP but not 5-HT. Later, a proportion also stain for CT. This pattern seemingly accounts for the predominance of single cells in laryngotracheal epithelium of adult animals. In the third pattern, cells immunoreactive for peptide YY (PYY) differentiate, singly at first and later among cells of tiny pNEBs. This begins postnatally in alveoli, spreading centripetally with retrograde differentiation of alveolar epithelium back into the bronchiolar terminations. Restricted distribution and lack of immunoreactivity for 5-HT, CGRP, or CT suggest that the PYY-positive endocrine cells form a regional subset performing special roles in pulmonary homeostasis.

Ultrastructure and immunocytochemistry of the neuroepithelial bodies in the lung of the tiger salamander, Ambystoma tigrinum (Urodela, Amphibia)

Light and electron microscopy of the lungs of Ambystoma tigrinum (Urodela) revealed a relatively complex pattern of the neuroendocrine (NE) cells. In the apical parts of smaller septa single NE cells not associated with nerve fibres were covered and surrounded by pneumocytes. The larger septa possessed small areas of ciliated epithelium, in which the NE cells were grouped in a form of neuroepithelial bodies (NEB) consisting of 3-5 cells and covered by goblet cells. NE cells possessed a large nucleus with patches of condensed chromatin, clear cytoplasm, and membrane-bound vesicles of variable morphology and size, containing an electron dense interior surrounded by a lucent space. The size of these dense core vesicles (DCV) ranged from 70-140 nm, while rarely the larger ones exhibited a diameter of 300-600 nm. In some NEB a second type of NE cells was observed for the first time in an amphibian species: these cells communicated with the air space and exhibited on their surface microvilli and a single modified cilium with a 8 + 1 microtubule arrangement. Their cytoplasm contained two types of DCV: dense core granules with a diameter of 140-260 nm and vesicles 320-700 nm in diameter with a moderately electron dense interior. The NEB were associated with intracorpuscular, sensory nerve terminals morphologically afferent and efferent. By immunocytochemistry, the NE cells revealed the presence of serotonin, met-enkephalin, and leu-enkephalin. A paracrine and chemoreceptor role is proposed for NEB of Ambystoma tigrinum.

The regulated expression of mRNA for Clara cell protein in the developing airways of the rat, as revealed by tissue in situ hybridization

Tissue in situ hybridization has been used on sections of developing rat lung to follow the cellular sites of mRNA expression for a protein identified only in bronchiolar Clara cells. The mRNA for this Clara cell protein (CCP) was first detected on gestational day 16 in only one of the two types of tubules existing in the lung at this developmental stage. During the next 2 days CCP mRNA expression increased uniformly only in the epithelium lining the respiratory tubules. By gestational day 19, CCP mRNA expression became limited to secretory epithelial cells lining the bronchi, and terminal bronchioles. By neonatal day 1, an intense hybridization signal was observed along all of the conducting airways, but it was irregular due to the fact that expression of the CCP gene was limited to the secretory epithelial cells. In adult rats, CCP mRNA was expressed not only in secretory cells of the intrapulmonary airways at all anatomical levels, but also in secretory epithelial cells lining the trachea and its glands, as well as in specific alveolar cells thought to be type II pneumocytes. These findings demonstrate that the regulation of the CCP gene during lung development is a complicated process and that the expression of CCP mRNA does not parallel exactly the sequential development of the airways.

Effects of vitamin A-deficiency and inflammation on the conducting airway epithelium of Syrian golden hamsters

The effects of vitamin A-deficiency and inflammation were studied in the conducting airways of Syrian golden hamsters. An important goal of the study was to characterize epithelial changes that occur early in vitamin A-deficiency, that might precede yet predispose to infection, and precipitate inflammatory changes in the lungs. Age-matched vitamin A-replete control and vitamin A-deprived hamsters were killed at 33 days of age (preweight-plateau); at 41 days of age (weight plateau-early weight loss); and at 48-55 days of age (prolonged weight plateau followed by weight loss). A tablet containing bromodeoxyuridine (BrdU) was implanted subcutaneously into each hamster 7 h before it was killed. No changes were seen in the conducting airway epithelium of vitamin A-deprived hamsters in the preweight plateau. However, labelling of secretory cells for BrdU was reduced 6-7 fold in the epithelium lining the lobar bronchus (p less than 0.0002) and the bronchioles (p less than 0.0001), and the proportions of ciliated cells were decreased (p less than 0.0001) at both airway levels in vitamin A-deficient hamsters in the weight plateau-early weight loss stage. Changes in cellular morphology were minimal in the intrapulmonary airway epithelium at this time but a few small focal patches of epidermoid metaplasia were seen in the tracheal epithelium. Small foci of inflammation were closely associated with the airways in the weight plateau, and the inflammation became more widespread when the deficiency was prolonged. The results suggest that the defense of the lungs to infection was impaired initially in the vitamin A-deficient hamsters by a widespread reduction in the numbers of ciliated cells throughout the epithelium of the conducting airways (trachea, bronchi, bronchioles). At the foci of inflammation, labelling of epithelial secretory cells for BrdU was greatly increased at all airway levels. A highly stratified cornifying epidermoid metaplasia developed in the tracheal epithelium, and goblet cell metaplasia developed in the cranial portion of the lobar bronchus, in association with submucosal inflammation. Goblet cell metaplasia appeared to be the only abnormality that was not reversed when vitamin A was restored to the diet.

Endocrine cells and brush cells at the bronchiolo-alveolar junctions of neonatal Syrian hamster lungs

Endocrine cells and brush cells at the bronchiolo-alveolar junctions of the lung of neonatal hamsters were studied by transmission electron microscopy. On both sides of the junctions (bronchiolar and alveolar), clusters of endocrine cells occur as neuroepithelial bodies (NEB). A few solitary endocrine cells are also present at the alveolar sides of the junctions. Some endocrine cells reach from the basement membrane to the air space but the area of apical cell membrane exposed to the airway is small as the cells are largely covered by Clara cells in the bronchioles and by thin attenuations of alveolar type 1 cells in the alveoli. Some Clara cells around NEB contain cytoplasmic lamellar bodies, similar to those characteristically associated with alveolar type 2 cells. A few brush cells are also seen at both sides of the junctions. Long wide microvilli with filamentous cores extend from the apices of the brush cells. Endoplasmic reticulum and Golgi apparatus are moderately developed. Well-developed bundles of intermediate filaments course throughout the cytoplasm of some of the brush cells. The functions of endocrine cells and brush cells are unknown. However, the presence of these cells at the bronchiolo-alveolar junctions of neonatal hamster lungs suggests a role in regulation of respiratory function.

The immunocytochemical detection of cytochrome P-450 monooxygenase in the lungs of fetal, neonatal, and adult hamsters

Antibodies against rabbit cytochrome P-450 reductase (reductase), cytochrome P-450 isozyme 2 (P-450 IIB), and cytochrome P-450 isozyme 5 (P-450 IVB) were used to detect homologous enzymes in the developing lung of the Syrian golden hamster. No immunocytochemical labeling was observed on gestational days 11, 12, and 13. On gestational day 14, light immunoperoxidase labeling for reductase and P-450 IIB was observed over cells lining the trachea and cranial portions of lobar bronchi. On gestational day 15, these enzymes were detected in conducting airways at all anatomic levels, and in the media of the pulmonary vein and its branches. Light labeling for P-450 IVB was first observed over cells lining the trachea and lobar bronchi on gestational day 15, but the smallest bronchioles and the media and endothelium of the pulmonary vein did not label for this enzyme until gestational day 16 (neonatal day 1). Type II pneumocytes and the pleural mesothelium first labeled for each of the three enzymes on neonatal day 1. Although the mesothelium no longer labeled for reductase or P-450 IIB in hamsters 3.5 wk old, the other labeling sites persisted in adult hamsters. Because cytochrome P-450 enzymes are associated with the endoplasmic reticulum, an ultrastructural examination of differentiating secretory cells was made to detect its appearance. At each conducting airway level, smooth endoplasmic reticulum was present in the cells 2 d before cytochrome P-450 enzymes could be detected immunocytochemically. The appearance of these enzymes paralleled the development of the hamster lung; they were first present in the trachea and lobar bronchi, then in the bronchioles, and finally in the alveoli.

Development of the conducting airway epithelium in fetal Syrian golden hamsters during normal and diabetic pregnancies

The conducting airway epithelium of fetal Syrian golden hamsters was studied from gestational day 12 to day 15, during normal and uncontrolled diabetic pregnancies. Diabetes was induced in the pregnant hamsters by injecting streptozotocin at 60 mg/kg body weight, subcutaneously, early on gestational day 10. Cells in S-phase were labelled immunochemically with bromodeoxyuridine (BrdU), and the day on which endocrine cells and ciliated cells first appeared was determined. In control fetuses, the BrdU-labelling indices (LI's) of different anatomical airway levels were significantly different from one gestational day to the next. For example, the LI of the lobar bronchus was significantly different on each gestational day (P less than .0001), and the same was true of the bronchioles. Moreover, the difference between LI's of the lobar bronchus and bronchioles-terminal buds was highly significant on day 12 (P less than .0001), and on day 13 the differences between lobar bronchus and bronchioles, lobar bronchus and terminal buds, and bronchioles and terminal buds were also highly significant (P less than .0001). However, on gestational days 14 and 15, the LI's were reduced and were comparable at different airway levels. The BrdU-labelling indices were very consistent among fetuses of the same age, and the differences between the average LI's for pups of different litters was numerically very small. Hyperglycemia (mild, moderate, severe) did not alter LI's in the fetal airway epithelial cells. Furthermore, although glycogen was not depleted from the airway epithelium of the hyperglycemic fetuses as it was in the controls, the endocrine cells first appeared on gestational days 12, 13, and 14, respectively, in the trachea, lobar bronchus and bronchioles, followed 1 day later by the ciliated cells, in the fetuses of control and diabetic mothers. In our experimental model, induction of diabetes in the pregnant hamsters on gestational day 10 did not appear to alter development or differentiation of the fetal conducting airway epithelium.

Immunochemical localization of Clara cell protein by light and electron microscopy in conducting airways of fetal and neonatal hamster lung

An antibody to a protein produced by Clara cells in adult Syrian golden hamsters has been used to monitor the development and functional differentiation of secretory cells in the conducting airway epithelium of this species. Lungs from fetal and neonatal hamsters at gestational day 11 and at intervals up to and including 3.5 weeks of age (as well as adults) were studied. The earliest time this Clara cell protein could be identified by immunoperoxidase labeling in the fetal conducting airways was at gestational day 15. On this day, labeling was observed in a few secretory cells lining the trachea, in many lining the lobar bronchi, and in virtually all secretory cells lining the bronchioles. Ciliated cells and endocrine cells were not labeled. Granules first appeared within the apical cytoplasm of the secretory cells on gestational day 15 at all airway levels. To identify the exact subcellular location of this protein, an ultrastructural labeling procedure using protein A gold was employed. The gold particles labeled only electron-dense granules within the secretory cells, indicating that they represent the specific site of this protein. Since secretory cells in the most distal conducting airways began to produce this protein on the same day in development as cells in the larger airways, including the trachea, this expression of functional maturation occurs simultaneously throughout the conducting respiratory tree rather than proceeding sequentially in a cranial to caudal direction. Consequently, secretory cells lining the smaller conducting airways mature more rapidly than those lining the larger airways.

Ontogeny of epidermal growth factor receptor and lipocortin-1 in fetal and neonatal human lungs

The ontogeny and distribution of the epidermal growth factor (EGF) receptor and lipocortin-1, a major cellular substrate of the EGF receptor, were evaluated in a developmental series of fetal and neonatal human lungs (8 to 41 weeks' gestation and stillborn to 16 days' postnatal age). The peroxidase anti-peroxidase technique with two polyclonal antibodies recognizing the EGF receptor and one polyclonal antibody recognizing lipocortin-1 were used for immunohistochemical localization. Extensive or scattered bronchiolar EGF receptor immunoreactivity appeared in the entire series of frozen lung specimens from 15 to 32 weeks' gestation. Bronchial glands exhibited EGF receptor immunostaining from 19 weeks onward, and immunoreactivity in bronchial epithelium was detected from 23 weeks onward. Most tracheas showed extensive lipocortin-1 immunoreactivity in the epithelium beginning at 10 weeks' gestation. Immunostaining was also seen in cells lining the ducts of submucosal glands after 15 weeks' gestation and in nonmucous acinar cells of tracheal glands after their appearance at 18 weeks' gestation. Bronchial epithelium exhibited lipocortin-1 immunoreactivity from 12 weeks' gestation onward. Bronchial gland necks became immunostained from 16 weeks' gestation onward, followed by acinar immunostaining as they subsequently developed. Bronchiolar epithelium was immunostained as early as 12 weeks, beginning with the largest airways, and by 24 weeks extending distally to the bronchioloalveolar portals. Lipocortin-1 immunostaining of larger conducting airway epithelium was primarily confined to ciliated cells. Neither EGF receptor nor lipocortin-1 immunoreactivity was detected in alveolar type I or type II cells, fibrocytes, chondrocytes, or smooth muscle cells at any gestational age. These developmental patterns suggest that the EGF receptor and lipocortin-1 may participate in normal growth factor-induced proliferation of the conducting airways and their glands in the human fetal lung and trachea.

Ultrastructural architecture of pulmonary small-granule cell clusters in adult Syrian golden hamster

Throughout the epithelial lining of the respiratory system is a class of cells with characteristics similar to Amine Precursor Uptake and Decarboxylation (APUD) polypeptide hormone-producing cells. In the intrapulmonary airways, these small-granule cells (SGCs) occur either singly or in organized clusters. Although no specific peptide has yet been identified, subclasses have been postulated based on granule geometry or light microscopic staining. The present study characterizes the architectonic and cellular organization of clustered SGCs in the adult Syrian golden hamster. Two morphologically distinct cells can be defined in such clusters, "light" and "dark." Thid distinction was based primarily on differences in the electron density of the cytoplasmic matrix rather than on the remarkable variations in cellular organelles or dense-core secretory vesicles. Both cell types were normal as judged by uniform spherical nuclei, chromatin organization, and distribution of cellular organelles. The "dark" cells, however, presented the profile of a cell actively involved in synthesis with a markedly dilated perinuclear cisterna and endoplasmic reticulum. Additionally, the "dark" cells contained membrane-delimited structures containing concentric membranous whorls, clear vacuoles, and lipofuscin granules. Occasionally, cells were observed to contain features of both cell types, suggesting that they may represent a continuum of common cell lineage. Accordingly, in the absence of additional morphologic or biochemical data, the "light" and "dark" cells most probably correspond to different stages of functional activity or age-related changes of a single type of cell. Unmyelinated nerve endings were occasionally interposed between cells, but synaptic specializations were not observed. Beneath the clusters, nerve fibers were also present, but they were never observed to penetrate the basal lamina or contact any of the SGCs. Of equal occurrence were elements of the vascular system and smooth muscle, suggesting that some SGCs in the adult hamster may function in a paracrine or endocrine manner. Such knowledge is essential to any study attempting to delineate the functional role or roles of these enigmatic organoids.

The ultrastructure of hamster bronchial epithelium

The central intrapulmonary bronchi of adult male Syrian hamsters were examined by electron microscopy to identify the principal types and proportions of epithelial cells. A differential count of cells displaying both a basal lamina and luminal border (transepithelial cells) showed that, on average, ciliated cells constituted 63% and granule-containing (granulated) secretory cells 25% of the total. Other transepithelial cells included nongranulated secretory cells (9%), preciliated cells (1.5%), and indeterminate cells (1%). The most frequent granulated secretory cell (77% of the population) was the Clara cell. It was identified by the presence of prominent apical smooth endoplasmic reticulum and secretory granules. It was subclassified into three types based on the presence or absence of rough endoplasmic reticulum and on granule morphology. Mucous cells (little or no smooth endoplasmic reticulum but with typical mucous granules) constituted approximately 20% of the granulated secretory cells. Serous cells were very infrequent. A differential count of nucleated epithelial cells demonstrated an average of 2% basal cells (hemidesmosomes present) and 20% pseudobasal cells (hemidesmosomes absent). Neuroepithelial bodies and solitary "small-granule" cells were infrequent. Brush cells and apoptotic bodies were rarely found but are noteworthy because their occurrence in hamster airways was not demonstrated previously. These results provide a foundation for subsequent analysis of alterations of epithelial homeostasis induced by injurious agents of exogenous and endogenous origin.

Ontogeny of small-granule APUD cells in hamster lung: a morphological study

Development of small-granule APUD cells and cell clusters was studied in 13-day to 15-day fetal hamster lungs by periodic acid-Schiff (PAS)-lead hematoxylin staining, monoamine fluorescence, and transmission electron microscopy. We examined 11-day and 12-day fetal, early postnatal, and adult animals only by PAS-lead hematoxylin. Precursors of small-granule cells first appear as PAS-negative clear cells in proximal airways of 13-day lung, occurring singly or in clusters of 2-25 cells and standing out among their undifferentiated, glycogen-laden, PAS-positive neighbors. By 14 days, developing small-granule cell clusters are prominent in main and lobar bronchi, extending 2-3 airway generations into the periphery. Clear-cell clusters, similar to those seen in 13-day lung, appear in peripheral airways and reach within one generation of developing terminal sacs. By 15 days, a few small, small-granule cell clusters are located at bronchioloalveolar junctions. Comparatively mature clusters occur in proximal airways; they are characterized by specific formaldehyde-induced monoamine fluorescence demonstrable after exposure in vitro to 5-hydroxytryptophan. In early postnatal stages, PAS-positive granules are resolvable toward the base of some endocrine cells. Ultrastructurally, pulmonary APUD cells contain numerous membrane-limited granules (180-nm diameter) of varying electron density. In 13-day lung, granules sparsely populate the cytoplasm of clear cells, but as the cells mature, the granule population increases and becomes concentrated in the basal cytoplasm. Fetal development of small-granule cells is therefore compressed into the last 4 days before birth. Most clusters appearing in neonatal lungs are not yet fully mature, and not all subtypes of this population are present until some time later.

Small-granule APUD cells in relation to airway branching and growth: a quantitative, cartographic study in Syrian golden hamsters

Small-granule APUD cell clusters and their clear-cell precursors were mapped in serial 2-micron glycol methacrylate-embedded, periodic acid-Schiff (PAS)-lead hematoxylin-stained sections of 13-, 14-, and 15-day fetal hamster lungs. Every sixth section was drawn from a camera lucida projection on tracing paper. Each tracing included the profiles of nonalveolated air passages and the locations of small-granule cell clusters and solitary clear cells. Airways containing ciliated cells and those surrounded by condensed mesoderm were also labeled. Single clear cells were rare in fetal hamster lung. Of 2,368 endocrine cell loci identified in the three fetal age groups examined, only 14 were single clear cells. A preliminary survey of the entire left and right lungs showed that the pattern of airway and small-granule cell development in the infracardiac lobe was similar to that occurring in the remainder of the lung; this lobe was accordingly considered a model for the whole lung, and the ontogeny of its small-granule cell population was quantitated and compared with results of similar quantitative mapping of this lobe in an adult animal (Hoyt et al., 1982a,b). Along the lobar bronchus of the 13-day infracardiac lobe and proximal portions of its main branches, small-granule cell clusters occurred most often near airway intersections. As the number and density increased in subsequent fetal stages, small-granule cell clusters became conspicuous along internodal bronchial segments. In distributing bronchioles, the population density of small-granule cell clusters decreased between 13 and 14 days but more than doubled by day 15. Unlike human lungs, where centrifugally developing small-granule cell clusters are firmly established in terminal bronchioles well before birth, most peripheral bronchioles in fetal hamster were devoid of small-granule cell clusters, even at 15 days, one day before birth. Comparison of numerical population densities in this lobe of fetal and adult lungs indicates that small-granule cell clusters continue to form past day 15 and suggests that they are considerably more numerous in adult than fetal lung.

Three-dimensional reconstruction of a small-granule paracrine cell cluster in an adult hamster bronchus

Amine precursor uptake and decarboxylation (APUD) small-granule cells were stained by periodic acid-Schiff (PAS)-lead hematoxylin in 0.5-micron etched Epon sections of adult hamster lung fixed for transmission electron microscopy. The leading edge of a small-granule cell cluster was identified in a segmental bronchus as a single PAS-positive cell. From 256 serial thin sections through its entirety, a three-dimensional wooden reconstruction of the cluster and morphometric estimates of the apical and basal surfaces, cell volume, and intracytoplasmic distribution of mitochondria and small granules was made. Of moderate size, the body consisted of 16 small-granule cells, 11 forming its ovoid core with five outlying cells diverging at the margin; these were pyramidal, possessing wide bases and thin apical processes. At the bronchial surface, processes from the 11-cell core emerged together, whereas the divergent cells emerged in groups of two and three. Ten Clara-like cells and one ciliated cell encircled the core. Altogether they formed a pseudostratified epithelium in contrast to the surrounding simple columnar epithelium. Deeper in the cluster, numerous cytoplasmic extensions interdigitated with those from adjacent cells, and toward the base the Clara-like and APUD cells were increasingly interposed. In marked contrast to the apical cytoplasm, the infranuclear cytoplasm of the latter was densely packed with ca. 1,000 A electron-dense granules; and the basal, presumptively secretory face of each cell was five to six times greater than the area exposed to the bronchial lumen. Judged by granule size and ultrastructure, only one APUD cell type was recognized in the reconstructed cluster. Beneath it many fibrocytic processes were separated from the APUD cells by only the thickness of the basal lamina. Two fascicles of smooth muscle approached the cluster within 0.4-0.8 micron. Unmyelinated nerve fibers came as close but contacted only the muscle. Capillaries, in contrast, came no closer than 15 micron from the base of the body. Evidently, 1) fibrocytes and smooth muscle are more likely targets for secretions from such a paracrine body than cells reached through the blood-stream, and 2) not all small-granule cell clusters are innervated.

Development of neuroepithelial bodies in intact and cultured lungs of fetal rats

Intact, 14- to 21-day fetal rat lung pairs, neonatal lungs, and cultured 15- and 16-day lung explants were examined in 2-micron-thick glycol methacrylate sections stained by PAS-lead hematoxylin. Selected stages were also studied in histochemical preparations for aliesterase and formaldehyde-induced monoamine fluorescence, as well as by scanning and transmission electron microscopy. Neuroepithelial bodies (NEBs) first appear in pseudoglandular lungs at 15 days in vivo as pyramidal groups of basal, diffusely lead-hematoxylin-positive cells in glycogen-depleted epithelium of main and lobar bronchi. By day 16, primitive NEBs occur within three to four generations of the terminal buds, and older, proximal bodies are larger and more distinctive than at 15 days. Aliesterase activity is first detected in basally located, developing NEBs on day 16. During the canalicular and alveolar sac periods, NEBs appear and mature on a proximal-to-distal gradient along the airway, as they do in developing rabbit and human lungs. As earlier-formed airways elongate, additional NEBs appear and supplement the population already present. By days 20-21, NEBs occur at all airway levels down to the bronchiolo-alveolar junctions, and many of the cells have discrete PAS- and lead-hematoxylin-positive, infranuclear granules. Near term some NEBs exhibit serotonin fluorescence after incubation in 5-hydroxytryptophan and have abundant, ca. 100-nm, electron-dense granules. These are concentrated toward the cell base like the stained granules visualized by light microscopy. Similar results were obtained from lungs placed in organ culture. From 2 days in culture to a time equivalent to term, NEB formation parallels that in vivo, indicating that developmental requirements are met in in vitro. Taken altogether, morphologic and cytochemical evidence suggests that NEBs of rats are functional in late fetal life and that their development is relatively independent of extrapulmonary influences and of the intraepithelial ingrowth of sensory nerve endings.

Morphologic and cytochemical characteristics of amine-containing globule leukocytes in rat tracheal epithelium

Amine-containing cells in the tracheal epithelium are typically of the small-granule type (diameter approximately 100 nm). However, in the rat, another amine-containing cell type has been identified that possesses the amine-handling features of the APUD-series of cells (amine precursor uptake and decarboxylation) but not the ultrastructural characteristics. It has been postulated that these cells may be related to cutaneous melanocytes. In this study, fluorescent cells were present in the laryngeal and tracheal epithelial lining of adult Sprague-Dawley rats following freeze-drying and exposure to formaldehyde vapor (FIF or formaldehyde-induced fluorescence). Microspectrofluorimetry revealed an emission maximum at 493 nm. The excitation maximum could not be calculated but appeared to be around or below 350 nm (to record spectra below requires the use of quartz optics). Yellow fluorescence also emanated from serotonin-containing mast cells (excitation and emission maxima: 401/515 nm). Tracheal segments processed according to the aqueous formaldehyde ( AFIF ) technique, for the demonstration of 5- hydroxytryptophan (5-HTP) or serotonin (5-HT), failed to identify fluorescent cells in the epithelial lining even though connective-tissue mast cells were evident. Subsequent treatment of AFIF -fixed sections with formaldehyde and HCl vapors ( AFIF -HCl) resulted in the formation of a fluorogenic compound within numerous cells in the tracheal lining (455/537 nm). This spectral shift and increase in intensity of fluorescence following acidification are characteristic for standards and/or cells that contain tryptamine, tryptophan, or peptides with NH2-terminal tryptophan and are markedly different from microspectrofluorimetric data reported for the phenylethylamines or serotonin. It is therefore postulated that these cells contain a closely related beta-(3-indolyl) ethylamine-like compound, serotonin excluded. The morphology of the fluorescent cells was similar when prepared according to the FIF or AFIF -HCl techniques. Conjunctive staining, the examination of a single section first by fluorescence microscopy and subsequently by other histochemical and cytochemical methods, demonstrated that the fluorescent granules were also methylene blue, alcian blue, periodic-acid Schiff, and ferric- fericyanide positive. Subsequent correlative electron microscopic examination of Epon-embedded AFIF -HCl-treated tracheal sections demonstrated that these amine-containing cells were globule leukocytes.

Neuroepithelial bodies (NEB) and solitary endocrine cells in the hamster lung

Periodic acid-Schiff (PAS)-positive small-granule endocrine cells identified in serial plastic sections through 95% of the infracardiac lobe of a Syrian golden hamster lung were marked on a 70X cardboard reconstruction of the airways and recorded for computerized analysis as described in the preceding paper in this volume [1]. When airways were subdivided into thirds and the resulting small pieces of airway surface were analyzed statistically, endocrine cell loci appeared to be randomly distributed in the epithelial layer. Nevertheless, loci were absent from only 10 of 209 unit airways, far short of the 28 predicted from a random distribution. Solitary endocrine cells accounted for 37% of 980 loci but only 6% of all endocrine cells; 63% of loci consisted of endocrine cell clusters, broadly defined as "neuroepithelial bodies," of from 2 to 107 cells. Although small groups were preponderant, no significant discontinuity occurred in the size distribution between 1 and 56 cells per locus. Neuroepithelial bodies predominated everywhere, but especially in the lobar bronchus and at bronchioloalveolar portals, where cuboidal bronchiolar epithelium gives way to the attenuated epithelium of the respiratory zone; 45% were related to peribronchial smooth muscle and 18% to pulmonary capillaries. Only 3.3% of solitary cells were related to capillaries, 29% to airway muscle; 68% occurred in muscle-free regions of the airway, associated preferentially with ciliated epithelial cells. We conclude that endocrine cells are distributed in such a way that virtually all airways have at least one locus. This nonrandomness suggests that these cells are in fact important to normal lung function. Furthermore, because solitary endocrine cells and "neuroepithelial" cell clusters have different intrapulmonary distributions, they may well have distinct identities and functions.

Development of neuroepithelial bodies and solitary endocrine cells in fetal rabbit lungs. II. Nonspecific esterase as an indicator of early maturation

Activity for nonspecific esterases has been demonstrated histochemically in fetal rabbit lungs using alpha-naphthyl acetate as substrate. Commencing with a homogeneous distribution in pseudoglandular lungs, activity gradually heightens in the epithelium, progresses centrifugally along the bronchial tree, and reaches full expression in postnatal lungs, when most cells in conducting airways are strongly reactive. Well before this general rise, small clusters become conspicuously reactive in the epithelium, first in the larger bronchi and later in the smaller bronchi. At 25 days' gestation most of these are neuroepithelial bodies, which are recognizable in frozen sections and occur selectively near bronchial bifurcations. Subsequently, while the bodies formed earlier continue active, other clusters and solitary cells become reactive in more recently formed airways, amounting in all to 1-2% of the epithelial cells present. Near term these and the more organized neuroepithelial bodies occur throughout the bronchial tree up to the primitive respiratory zone. The small clusters and single cells may include some mature elements; however, as they generally correspond in incidence and distribution to clear cells and clusters, identified as precursors of neuroepithelial bodies, many are incompletely differentiated. Esterase activity, a characteristic shared with APUD cells in other organs, evidently rises about the time pulmonary endocrine cells become functional. Using the histochemical method, a large population of these cells is therefore demonstrable in lungs until after birth, when the increasing activity of nonendocrine cells finally obscures it.