Immunohistochemical demonstration of villin in the normal human pancreas and in chronic pancreatitis

Human pancreatic tissue was investigated by immunohistochemistry using a polyclonal antibody against the actin binding protein villin, which participates in the formation of actin filament bundles in the microvilli. In cells of the different parts of the pancreatic duct system as well as in the acinar cells villin immunoreactivity was located mainly at the apical cell surface. This was confirmed by the ultrastructural demonstration of microvilli on the surface of duct and acinar cells, which exhibited the typical actin bundles. In chronic pancreatitis the staining for villin in duct-like structures of degenerative pancreatic tissue was irregular or even absent. This correlated with the electron microscopic observation of duct-like structures known as tubular complexes composed of cells devoid of microvilli at the apical cell surface. At the light microscopical level degenerative structures without lumen and of unknown origin showed a strong staining for villin at their basal cell surface.     

Identification of brush cells in the alimentary and respiratory system by antibodies to villin and fimbrin

Summary Brush cells represent a population of epithelial cells with unknown function, which are scattered throughout the epithelial lining of both the respiratory system and the alimentary system. These cells are reliably distinguished from other epithelial cells only at the ultrastructural level by the presence of an apical tuft of stiff microvilli and extremely long microvillar rootlets that may project down to the perinuclear space. In the present study we show that brush cells can be identified in tissue sections even at the light microscopic level by immunostaining with antibodies against villin and fimbrin, two proteins that crosslink actin filaments to form bundles. In brush cells, villin and fimbrin are not only present in the actin filament core bundles of apical microvilli and their long rootlets but, in addition, both proteins are also associated with microvilli extending from the basolateral cell surface of the brush cells. Basolateral immunostaining specific for villin and fimbrin does not occur in any other epithelial cell type of the respiratory and alimentary tract. Thus immunostaining with antibodies against both proteins allows unequivocal identification of individual brush cells even in sectional planes that do not contain the brightly stained apical tuft of microvilli and their long rootlets.     

Distribution of actin and the actin-associated proteins myosin, tropomyosin, alpha-actinin, vinculin, and villin in rat and bovine exocrine glands

Actin, myosin, and the actin-associated proteins tropomyosin, alpha-actinin, vinculin, and villin were localized in acinar cells of rat and bovine pancreas, parotid, and prostate glands by means of immunofluorescent staining of both frozen tissue sections and semithin sections of quick-frozen, freeze-dried, and plastic-embedded tissues. Antibodies to actin, myosin, tropomyosin, alpha-actinin, and villin reacted strongly with a narrow cytoplasmic band extending beneath the luminal border of acinar cells. The presence of villin, which has so far been demonstrated only in intestinal and kidney brush border, was further confirmed by antibody staining of blotted electrophoresis gels of whole acinar cell extracts. Fluorescently labelled phalloidin, which reacts specifically with F-actin, gave similar staining, within the cell apex to that obtained with antibodies to actin, myosin, tropomyosin, alpha-actinin, and villin. In contrast, immunostaining with antibodies to vinculin was restricted to the area of the junctional complex. Ultrastructurally, the apical immunoreactive band corresponded to a dense web composed of interwoven microfilaments, which could be decorated with heavy meromyosin. Outside this apical terminal web, antibodies to myosin and tropomyosin gave only a weak immunostaining (confined to the lateral cell borders) whereas antibodies to actin and alpha-actinin led to a rather strong bead-like staining along the lateral and basal cell membrane most probably marking microfilament-associated desmosomes. Anti-villin immunofluorescence was confined to the apical terminal web. It is suggested that the apical terminal web is important for the control of transport and access of secretory granules to the luminal plasma membrane and that villin, which is known to bundle or sever actin filaments in a Ca(++)-dependent manner, might participate in the regulation of actin polymerization within this strategically located network of contractile proteins.     

Immunohistological study of small Rho GTPases and β-catenin during regeneration of the rat submandibular gland

Our study immunohistochemically evaluated the localization patterns of small Rho GTPases and β-catenin during regeneration of the rat submandibular gland. After 7?days of obstruction, regenerating glands were collected at days 0, 3, 7, 11 and 14 after duct release to study regeneration. RhoA was detected strongly and RhoC was detected weakly in the cytoplasm of newly formed acinar cells from day 3 to 7, and both RhoA and RhoC at the basal site and cytoplasm were detected moderately from day 11 to 14. RhoB was detected strongly and moderately in the cytoplasm of newly formed and matured acinar cells, respectively, and detected strongly in duct-like structures (DLSs) and intercalated ducts (ICDs). Rac1 was detected at the cell–cell and subcellular region, but β-catenin was not observed in newly formed acinar cells. Rac1 immunolabeling gradually reduced, and the β-catenin staining pattern became stronger. p-Rac1, a phosphorylated form of Rac1, was observed in the cytoplasm of newly formed acinar cells. At apical and subcellular region of DLSs and ICDs, Rac1 and β-catenin were detected. These findings suggest that RhoA and RhoC might be involved in the actin cytoskeleton at the basolateral site of regenerating acinar cells, and RhoB might play a unique role in regenerating acinar cells and in DLSs and ICDs. Rac1 and β-catenin at the cell–cell region might play important roles in cell–cell adhesion and the differentiation of regenerating acinar cells, as well as actin reconstruction at apical and subcellular regions of DLSs and ICDs.     

Villin as a structural marker to study the assembly of the brush border

Summary Brush borders which are localized at the apical face of enterocytes, are composed of thousands of stiff microvilli containing bundles of microfilaments made of actin. Their assembly occurs during terminal differentiation of the enterocytes when these cells migrate along the villus of the intestinal mucosa. The cell line HT 29 derived from a human colonic adenocarcinoma whose differentiation can be induced, can also be used as a model to study in culture the assembly of the intestinal brush border.Villin is one of the actin binding proteins found in microvilli which compose brush borders. Villin is expressed in the adult and in the embryo before the appearance of the brush border. Villin can be used as a tissue-specific marker for normal diffentiated and undifferentiated cells derived from gastrointestinal tractus in the adult as well as in the embryo. Since villin is a good marker for intestinal cells and plays a structural role in the assembly of the brush border we have analysed its expression and its localization in HT 29 cells. In HT 29 cells, as in the tissue, villin is synthesized at low levels before the appearance of the brush border. The high rate of synthesis and the recruitement of villin at the apical pole of the cells can be correlated with the existence of a well developed brush border.     

Microinjection of villin into cultured cells induces rapid and long- lasting changes in cell morphology but does not inhibit cytokinesis, cell motility, or membrane ruffling

Villin, a Ca2(+)-regulated F-actin bundling, severing, capping, and nucleating protein, is a major component of the core of microvilli of the intestinal brush border. Its actin binding properties, tissue specificity, and expression during cell differentiation suggest that it might be involved in the organization of the microfilaments in intestinal epithelial cells to form a brush border. Recently, Friederich et al., (Friederich, E., C. Huet, M. Arpin, and D. Louvard. 1989. Cell. 59:461-475) showed that villin expression in transiently transfected fibroblasts resulted in the loss of stress fibers and the appearance of large cell surface microvilli on some cells. Here, we describe the effect of villin microinjection into cells that normally lack this protein, which has allowed us to examine the immediate and long-term effects of introducing different concentrations of villin on microfilament organization and function. Microinjected cells rapidly lost their stress fibers and the actin was reorganized into abundant villin containing cortical structures, including microspikes and, in about half the cells, large surface microvilli. This change in actin organization persisted in cells for at least 24 h, during which time they had gone through two or three cell divisions. Microinjection of villin core, that lacks the bundling activity of villin but retains all the Ca2(+)-dependent properties, disrupted the stress fiber system and had no effect on cell surface morphology. Thus, the Ca2(+)-dependent activities of villin are responsible for stress fiber disruption, and the generation of cell surface structures is a consequence of its bundling activity. Microinjection of villin led to the reorganization of myosin, tropomyosin, and alpha-actinin, proteins normally associated with stress fibers, whereas both fimbrin and ezrin, which are also components of microvillar core filaments, were readily recruited into the induced surface structures. Vinculin was also redistributed from its normal location in focal adhesions. Despite these changes in the actin cytoskeleton, cells were able to divide and undergo cytokinesis, move, spread on a substratum, and ruffle. Thus, we show that a single microfilament-associated protein can reorganize the entire microfilament structure of a cell, without interfering with general microfilament-based functions like cytokinesis, cell locomotion, and membrane ruffling.     

Differential localization of villin and fimbrin during development of the mouse visceral endoderm and intestinal epithelium

The apical surface of transporting epithelia is specially modified to absorb nutrients efficiently by amplifying its surface area as microvilli. Each microvillus is supported by an underlying core of bundled actin filaments. Villin and fimbrin are two actin-binding proteins that bundle actin filaments in the intestine and kidney brush border epithelium. To better understand their function in the assembly of the cytoskeleton during epithelial differentiation, we examined the pattern of villin and fimbrin expression in the developing mouse using immunofluorescence and immunoelectron microscopy. Villin is first detected at day 5 in the primitive endoderm of the postimplantation embryo and is later restricted to the visceral endoderm. By day 8.5, villin becomes redistributed to the apical surface in the visceral endoderm, appearing in the gut at day 10 and concentrating in the apical cytoplasm of the differentiating intestinal epithelium 2-3 days later. In contrast, fimbrin is found in the oocyte and in all tissues of the early embryo. In both the visceral endoderm and gut epithelium, fimbrin concentrates at the apical surface 2-3 days after villin; this redistribution occurs when the visceral endoderm microvilli first contain organized microfilament bundles and when microvilli first begin to appear in the gut. These results suggest a common mechanism of assembly of the absorptive surface of two different tissues in the embryo and identify villin as a useful marker for the visceral endoderm.     

Structural and compositional analysis of early stages in microvillus assembly in the enterocyte of the chick embryo

Morphological and immunocytochemical techniques were used to examine the distribution of villin, with respect to actin, during the early events of brush border morphogenesis in the embryonic chicken intestine. Immunolocalization studies indicate that actin and villin exist as a cortical array in the apical domain of embryonic enterocytes at a time when few surface microvilli are visible by scanning and transmission electron microscopic techniques. A population of villin is also localized at the level of the junctional complex. With time, the density of microvilli increases and the cells begin to flatten. In these cells, villin is detected in the newly formed microvilli and also in the subjacent cortex, where microvillar rootlets are beginning to appear. The significance of actin-villin associations in the process of brush border assembly is discussed in the light of the functional properties of villin.     

Ionic components of secretory cell surfaces in relation to secretory function

Synopsis Rat pancreas was examined by ultrastructural cytochemical methods for localizing cations and anions, as well as polyanions and, more specifically, sulphated mucosubstance. Exceptionally abundant antimonate-precipitable cation was demonstrated between pancreatic acinar cells and at the base of the centro-acinar and other duct epithelial cells. Precipitates of nuclear heterochromatin appeared lighter whereas those of mitochondria and cytoplasm were coarser and more conspicuous in acinar that duct cells. Stimulation with synthetic secretin at a low level diminished antimonate reactivity of nuclei as well as the precipitation at the basement membrane of centro-acinar cells. At a higher dose, secretin selectively eliminated precipitation between and below centro-acinar and other duct cells while inducing increased antimonate-reactive cation in centro-acinar cells and the acinar lumens. Pancreozymin stimulation elimated antimonate-precipitable cations between acinar cells and, to a much lesser extent, those between duct cells and increased cytoplasmic precipitates on granular reticulum of acinar cells.Silver-precipitable anions were localized on the luminal surface of the apical plasma lemma and the outer surface of the latero-basal plasmalemma of centro-acinar cells but not on acinar cell surfaces. Silver precipitates also occurred on junctional complexes of acinar and duct epithelial cells and at tight junctions of acinar cells and on the inner face of the lateral plasmalemma of acinar cells.Dialysed iron staining demonstrated the most number of sites of acid mucosubstance on the luminal surface of the plasmalemma of acinar cells. Lateral and basal plasmalemmas of centro-acinar and more distal duct cells stained lightly with dialysed iron but those of acinar cells did not. Dialysed iron visualized acid mucosubstance in the lamina lucida of the basement membrane of duct but not of acinar cells. Dialysed iron staining of the plasma membranes succumbed to prior sialidase treatment whereas that of basement membrane resisted digestion. High iron diamine staining demonstrated sulphated mucosubstance in the lamina lucida of the duct basement membrane exclusively. The cytochemical results implicate centro-acinar cells as primarily responsible for contributing fluid and electrolytes to pancreatic secretion.     

Molecular heterogeneity of the actin filament cytoskeleton associated with microvilli of photoreceptors,Müller's glial cells and pigment epithelial cells of the retina

The present study addressed the question as to whether the four different actin-associated proteins that are associated with the actin core bundle in intestinal microvilli (i.e. villin, fimbrin, myosin I and ezrin) are essential components of all microvilli of the body. The retina provides an excellent example of a tissue supplied with three different sets of microvilli, namely those of Müller's glial cells (Müller baskets), photoreceptors (calycal processes), and pigment epithelial cells. The main outcome of this study is that none of these microvilli contain all four actin-associated proteins present in intestinal microvilli. Müller cell microvilli contain villin, ezrin and myosin I (95 kDa isoform) but not fimbrin. Calycal processes of photoreceptors contain fimbrin but not villin, myosin I and ezrin. Finally, microvilli of pigment epithelial cells are positive for ezrin but not for villin, fimbrin and myosin I. Beoause of limited cross-reactivities of the antibodies to myosin I and ezrin, the myosin I data refer to the chicken retina whereas the findings with anti-ezrin were obtained with the rat retina. A further outcome of this study is that the actin filament core bundles in microvilli of chicken pigment epithelial cells are presumed to contain a crosslinking protein, which is not immunologically related to either villin, fimbrin or myosin I of the intestinal brush border.     

Immunodetection of the microvillous cytoskeleton molecules villin and ezrin in the parasitophorous vacuole wall of Cryptosporidium parvum (Protozoa: Apicomplexa)

Microvilli - actin - villin - ezrin - Cryptosporidium parvum The sporozoites and merozoites of the Apicomplexan protozoan Cryptosporidium parvum (C. parvum) invade the apical side of enterocytes and induce the formation of a parasitophorous vacuole which stays in the brush border area and disturbs the distribution of microvilli. The vacuole is separated from the apical cytoplasm of the cell by an electron-dense layer of undetermined composition. In order to characterize the enterocyte cytoskeleton changes that occur during C. parvum invasion and development, we used both confocal immunofluorescence and immunoelectron microscopy to examine at the C.parvum-enterocyte interface the distribution of three components of the microvillous skeleton, actin, villin and ezrin. In infected cells, rhodamine-phalloidin and anti-villin and anti-ezrin antibodies recognized ring-like structures surrounding the developing parasites. By immunoelectron microscopy, both villin and ezrin were detected in the parasitophorous vacuole wall surrounding the luminal and lateral sides of the intracellular parasite. In contrast, anti-beta and anti-gamma actin antibodies showed no significant labelling of the vacuolar wall. These observations indicate that the parasitophorous vacuole wall contains at least two microvillus-derived components, villin and ezrin, as well as a low amount of F-actin. These data suggest that C.parvum infection induces a rearrangement of cytoskeleton molecules at the apical pole of the host cell that are used to build the parasitophorous vacuole.     

Distribution of sialoglycoconjugates on acinar cells of the mammalian pancreas

Using the sialic acid-specific lectin, limulin (LPA; from Limulus polyphemus hemolymph), the distribution and nature of sialoglycoconjugates on the surface of rat pancreatic cells has been investigated. Binding of rhodaminated LPA (Rh-LPA) or horseradish peroxidase-conjugated LPA (HRP-LPA) to fixed-frozen sections of adult rat pancreas resulted in intense linear staining of the apical surface of acinar cells with fainter staining on the basal but not the lateral cell surfaces. LPA binding was specific in that it could be abolished by 1) pretreatment of tissue sections with neuraminidase or periodic acid; 2) competition with sialic acid; and 3) incubation in Ca2+ -free buffers. Pretreatment of sections with proteases abolished LPA binding to the apical surfaces of acinar cells and also enhanced LPA binding to the lateral cell surface. Lipid extraction of sections following protease treatment markedly reduced LPA binding to the acinar cell periphery. These results suggest that LPA binding sites on the acinar cell apical surface may be primarily sialoglycoproteins, while those on the basolateral surfaces may consist in part of gangliosides. Electron microscopy of collagenase-dispersed acini exposed to HRP-LPA confirmed binding of LPA to the basal plasmalemma and, in addition, revealed staining of basal lamina when present. LPA binding to the acinar cell surface was not affected by digestion of tissue sections with hyaluronidase, heparinase, collagenase, or 6 M guanidine-HCl. Control experiments indicated that rat pancreatic secretory proteins contain undetectable amounts of sialoglycoproteins and thus that the apical localization of LPA is not due to adherent secretory proteins. Islets of Langerhans were always uniformly and heavily stained with LPA conjugates; this staining was protease insensitive. Appearance of LPA binding sites was examined on embryonic pancreatic epithelia. At day 15 of gestation, Rh-LPA stained the entire periphery of the epithelial cells, including the lateral cell surface, although more intense staining was already noted on the apical surface. This pattern persisted through day 17 of gestation, but by day 19 an adult staining pattern was observed with loss of staining of the lateral cell surfaces.     

p53-dependent acinar cell apoptosis triggers epithelial proliferation in duct-ligated murine pancreas

The mechanisms linking acinar cell apoptosis and ductal epithelial proliferation remain unknown. To determine the relationship between these events, pancreatic duct ligation (PDL) was performed on p53(+/+) and p53(-/-) mice. In mice bearing a wild-type p53 allele, PDL resulted in upregulation of p53 protein in both acinar cells and proliferating duct-like epithelium. In contrast, upregulation of Bcl-2 occurred only in duct-like epithelium. Both p21(WAF1/CIP1) and Bax were also upregulated in duct-ligated lobes. After PDL in p53(+/+) mice, acinar cells underwent widespread apoptosis, while duct-like epithelium underwent proliferative expansion. In the absence of p53, upregulation of p53 target genes and acinar cell apoptosis did not occur. The absence of acinar cell apoptosis in p53(-/-) mice also eliminated the proliferative response to duct ligation. These data demonstrate that PDL-induced acinar cell apoptosis is a p53-dependent event and suggest a direct link between acinar cell apoptosis and proliferation of duct-like epithelium in duct-ligated pancreas.     

A new role for the architecture of microvillar actin bundles in apical retention of membrane proteins

Actin-bundling proteins are identified as key players in the morphogenesis of thin membrane protrusions. Until now, functional redundancy among the actin-bundling proteins villin, espin, and plastin-1 has prevented definitive conclusions regarding their role in intestinal microvilli. We report that triple knockout mice lacking these microvillar actin-bundling proteins suffer from growth delay but surprisingly still develop microvilli. However, the microvillar actin filaments are sparse and lack the characteristic organization of bundles. This correlates with a highly inefficient apical retention of enzymes and transporters that accumulate in subapical endocytic compartments. Myosin-1a, a motor involved in the anchorage of membrane proteins in microvilli, is also mislocalized. These findings illustrate, in vivo, a precise role for local actin filament architecture in the stabilization of apical cargoes into microvilli. Hence, the function of actin-bundling proteins is not to enable microvillar protrusion, as has been assumed, but to confer the appropriate actin organization for the apical retention of proteins essential for normal intestinal physiology.     

Sequence of human villin: a large duplicated domain homologous with other actin-severing proteins and a unique small carboxy-terminal domain related to villin specificity

Villin is a calcium-regulated actin-binding protein that caps, severs, and bundles actin filaments in vitro. This 92,500-D protein is a major constituent of the actin bundles within the microvilli of the brush border surface of intestinal and kidney proximal tubule cells. Villin is a very early marker of cells involved in absorption and its expression is highly increased during intestinal cell differentiation. The amino acid sequence deduced from the cDNA sequence revealed that human villin is composed of three domains. The first two domains appear as the result of a duplication: their structural organization is similar. We can then define a basic unit in which a slightly hydrophilic motif is followed by three hydrophobic motifs, similar between themselves and regularly spaced. The duplicated domain is highly homologous to three other actin-severing proteins and this basic structure represents the whole molecule in severin and fragmin, while two basic units compose gelsolin. The third domain which is carboxy terminal is villin specific: it is unique among actin modulating proteins so far known. It could account for its actin-binding properties (dual regulation by calcium of severing and bundling activities). We propose that it may also be related to the subcellular localization of villin in different epithelial cell types.     

Monoclonal antibodies as probes for plasma membrane domains in the exocrine pancreas

Monoclonal antibodies (mAb) were generated as probes for the plasma membrane domains of pancreatic acinar cells. Primary monolayer cultures of mouse pancreatic acinar cells, which have an expanded apical surface relative to normal pancreas, were used to immunize rats. With conventional immunization and fusion protocols, 3% of the hybridomas were positive against the acinar lumen by indirect immunofluorescence of mouse pancreas cryosections. Culturing of spleen cells from an immunized rat on the apical surface of acinar cell monolayer cultures before fusion with the myeloma (an in vitro boost) doubled the percentage of hybridomas producing apical membrane-specific mAb. Monoclonal antibodies were characterized by immunofluorescence, ultrastructural immunoperoxidase cytochemistry, immunoprecipitation, and immunoblotting. One antibody, acinar-1 (IgG2a), labeled the apical membranes of pancreatic acinar cells, hepatocytes, salivary and lacrimal gland acinar cells, and the brush border of small intestine enterocytes. This mAb precipitated and blotted a protein of 94 KD. Acinar-2 (IgM) also labeled pancreatic acinar cell apical membranes but did not label other tissues and did not precipitate or blot. Acinar-3 labeled pancreatic acinar cell lateral membranes. Duct-1 (IgM) labeled pancreatic duct apical membrane and ducts in liver and salivary glands but did not precipitate or blot. These domain-specific mAb demonstrate that common antigenic determinants occur in the apical surfaces of several exocrine epithelia and may be important in secretion.     

Actin filaments during terminal differentiation of urothelial cells in the rat urinary bladder

The localisation of actin filaments was studied in rat urothelial cells during differentiation which accompanied regeneration after cell damage induced by cyclophosphamide (CP). By immunofluorescence it was established that actin filaments equally stained along the cell circumference in basal and intermediate cells, while basolateral cell membrane expression was found in terminally differentiated superficial cells. During regeneration, after CP treatment, simple urothelial hyperplasia developed with smaller cuboidal superficial cells, in which actin filaments were equally distributed under the apical and basolateral plasma membranes. As demonstrated by immunoelectron microscopy, the apical surface of these superficial cells was covered with microvilli containing bundles of actin filaments. Within 1 week, the urothelium reverted to its normal three-layer thickness. Superficial cells became larger and flattened and the unthickened apical plasma membrane matured into a thick asymmetric unit membrane. Concomitantly actin filaments disappeared from apical areas of superficial cells while remaining abundant at basolateral areas. Our results indicate that in the urothelium subcellular distribution of actin filaments can be considered as a marker of cell differentiation. Accepted: 16 September 1999     

Caenorhabditis elegans chaperonin CCT/TRiC is required for actin and tubulin biogenesis and microvillus formation in intestinal epithelial cells

Intestinal epithelial cells have unique apical membrane structures, known as microvilli, that contain bundles of actin microfilaments. In this study, we report that Caenorhabditis elegans cytosolic chaperonin containing TCP-1 (CCT) is essential for proper formation of microvilli in intestinal cells. In intestinal cells of cct-5(RNAi) animals, a substantial amount of actin is lost from the apical area, forming large aggregates in the cytoplasm, and the apical membrane is deformed into abnormal, bubble-like structures. The length of the intestinal microvilli is decreased in these animals. However, the overall actin protein levels remain relatively unchanged when CCT is depleted. We also found that CCT depletion causes a reduction in the tubulin levels and disorganization of the microtubule network. In contrast, the stability and localization of intermediate filament protein IFB-2, which forms a dense filamentous network underneath the apical surface, appears to be superficially normal in CCT-deficient cells, suggesting substrate specificity of CCT in the folding of filamentous cytoskeletons in vivo. Our findings demonstrate physiological functions of CCT in epithelial cell morphogenesis using whole animals.     

Colocalization of cytokeratin 18 and villin in type III alveolar cells (brush cells) of the rat lung

Alveoli of the rat lung are lined by three different cell types, the flat type I cells and the cuboidal type II and type III cells. Type III cells differ from type II cells by the presence of an apical tuft of microvilli and the absence of lamellar type secretory granules. In the present study we show by double immunolabelling that type III cells of the rat lung can be identified at the light-and electron microscope level by antibodies against both cytokeratin 18 and the actin-crosslinking protein villin. At the ultrastructural level, microvilli and their rootlets in the apical cytoplasm were labelled by the anti-villin antibodies, whereas a monoclonal antibody against cytokeratin 18 (Ks18.04) labelled bundles of intermediate filaments. In conclusion, antibodies against villin and certain monoclonal antibodies specific for cytokeratin 18 can be used as tools for selective visualization of type III cells in the rat lung.