Ultrastructural immunocytochemical localization of fibronectin in the developing rat lung

Increased virulence of a fibronectin-binding protein mutant of Staphylococcus aureus in a rat model of pneumonia

Fibronectin-binding proteins mediate Staphylococcus aureus internalization into nonphagocytic cells in vitro. We have investigated whether fibronectin-binding proteins are virulence factors in the pathogenesis of pneumonia by using S. aureus strain 8325-4 and isogenic mutants in which fibronectin-binding proteins were either deleted (DU5883) or overexpressed [DU5883(pFnBPA4)]. We first demonstrated that fibronectin-binding proteins mediate S. aureus internalization into alveolar epithelial cells in vitro and that S. aureus internalization into alveolar epithelial cells requires actin rearrangement and protein kinase activity. Second, we established a rat model of S. aureus-induced pneumonia and measured lung injury and bacterial survival at 24 and 96 h postinoculation. S. aureus growth and the extent of lung injury were both increased in rats inoculated with the deletion mutant (DU5883) in comparison with rats inoculated with the wild-type (8325-4) and the fibronectin-binding protein-overexpressing strain DU5883(pFnBPA4) at 24 h postinfection. Morphological evaluation of infected lungs at the light and electron microscopic levels demonstrated that S. aureus was present within neutrophils from both 8325-4- and DU5883-inoculated lungs. Our data suggest that fibronectin-binding protein-mediated internalization into alveolar epithelial cells is not a virulence mechanism in a rat model of pneumonia. Instead, our data suggest that fibronectin-binding proteins decrease the virulence of S. aureus in pneumonia.

Pneumocystis carinii attachment increases expression of fibronectin-binding integrins on cultured lung cells

Pneumocystis carinii is an extracellular pathogen which requires attachment to alveolar epithelial cells for growth and replication. Previous studies have demonstrated that the extracellular matrix protein fibronectin (Fn) facilitates attachment of P. carinii to lung cells. This study addresses the role of cell surface Fn receptors (integrins) as mediators of P. carinii attachment and demonstrates the effect of P. carinii attachment on integrin expression on cultured lung cells. To determine the role of Fn-binding integrins in P. carinii attachment, attachment of 51Cr-labelled P. carinii organisms to the lung epithelial cell line A549 was quantified in the presence or absence of anti-integrin antibodies. Antibodies to the alpha v and alpha 5 integrin subunits significantly inhibited P. carinii attachment, while addition of antibody to the alpha subunit of a non-Fn-binding integrin, alpha 2, did not affect P. carinii attachment. To further investigate the role of Fn-binding integrins in P. carinii attachment, the effect of P. carinii attachment on expression of the alpha v and alpha 5 integrin subunits was determined. A549 cells incubated with either P. carinii organisms or with the P. carinii major surface glycoprotein gp120 demonstrated a 3- to 10-fold increase in expression of the alpha 5 integrin subunit; however, neither P. carinii nor gp120 affected the expression of alpha v integrin. Furthermore, the effects of P. carinii on A549 cell alpha 5 integrin expression were attenuated by the addition of an anti-gp120 antibody which blocks P. carinii attachment to A549 cells. Therefore, P. carinii attachment to lung epithelial cells appears to be mediated by alpha v- and alpha 5-containing integrins expressed on the epithelial cell surface, and P. carinii attachment results in increased expression of the alpha 5 integrin subunit.

Cell differentiation of alveolar epithelium in the developing rat lung: ultrahistochemical studies of glycoconjugates on the epithelial cell surface

Glycoconjugates on the surface of pulmonary epithelial cells were ultrahistochemically examined in the fetal, neonatal and adult rat lung. Lectin and colloidal iron staining procedures were performed in combination with digestion using carbohydrate-degrading enzymes or methylation. The glycoconjugate composition of columnar cells at 16 days gestation was similar to that of cuboidal cells at 19 days gestation. Glycoconjugate differentiation on the cell surface occurred at 20 days gestation, and especially the loss of soybean agglutinin (SBA) binding sites could be detected on type II cells. The contents of Ricinus communis agglutinin-I (RCA-I) and Concanavalin A (Con A) binding sites on type II cells also began to decrease. On the contrary, the content of sulfated saccharides decreased on the surface of type I cells during development. Glycoconjugate differentiation on both type I and II cells was completed with the disappearance of hyaluronic acid and peanut agglutinin (PNA) binding sites; type I and II cells acquired a similar histochemical composition to that on adult type I and II cells at 5 days after birth. Both type I and II cells share a common early precursor cell, that is, the cuboidal epithelial cell at the canalicular stage.

The hepatic extracellular matrix. I. Components and distribution in normal liver

The unique nature of the hepatic extracellular matrix (ECM) is predicated by the special configuration of the space of Disse. Whereas other epithelial organs have two basement membranes (BM) and a substantial ECM interposed between endothelial and epithelial cells, the liver lobule has no BM and only an attenuated ECM, consisting mostly of fibronectin, some collagen type I, and minor quantities of types III, IV, V, and VI. This configuration, together with the abundant fenestrations and gaps of the sinusoidal endothelial cells, seems ideally suited to facilitate the rapid bidirectional exchange of macromolecules normally taking place between plasma and hepatocytes. During organogenesis, the liver anlage is vascularized by continuous capillaries with BM, but by day 13.5 of development (in the rat) the vessels in the immediate proximity of hepatocytes become fenestrated, lacking specialized junctions and BM, suggesting that the hepatocytes produce signals capable of modulating the endothelial phenotype. In regeneration, hepatocyte proliferation precedes vascular proliferation resulting in the formation of hepatocyte clusters that, temporarily, lack sinusoids. Eventually, vascular proliferation follows and the normal hepatocyte-vascular relationships are restored. During this period laminin synthesis by Ito cells is prominent. As soon as hepatocytes become stable, secretion of the sinusoid phenotype-maintaining factors resumes and laminin synthesis and secretion terminates. The interplay between extracellular matrix and liver cells is essential for normal homeostasis and its modification results in deranged hepatic function.

Pulmonary disease in AIDS patients

Pulmonary disease remains a major complication of the human immunodeficiency virus (HIV). Over the past decade several changes in the pattern of disease have occurred. Pneumocystis carinii pneumonia (PCP) remains the most common opportunistic pathogen in AIDS patients, though its incidence on bronchoscopy has declined and empiric therapy often occurs without a specific diagnosis. Changes in the management of patients with PCP have included different dosages and routes of administration for chemotherapy, improved overall survival, and a recent increase in the number of patients surviving episodes of respiratory failure. In addition, infection with mycobacteria tuberculosis (M.Tb.) has emerged as a major public health problem. The pattern of M.Tb. is distinct from non-immunocompromised patients though response to therapy usually occurs.

Role of fibronectin in Pneumocystis carinii attachment to cultured lung cells

Attachment of pathogens to host cells is a prerequisite for the development of many infections. Pneumocystis carinii (PC) pneumonia is characterized by attachment of PC trophozoites to the alveolar epithelium. The mechanism of this process is unknown. Fibronectin (Fn) is a glycoprotein present in the alveolar space known to mediate cell-cell attachment, including the attachment of certain pathogens to host epithelial cells. In this study the binding of Fn to PC trophozoites has been characterized in vitro using 125I-Fn. Fn binds saturably and specifically to 6.4 x 10(5) binding sites per organism with an apparent binding constant, Kd, of 1.2 x 10(-8) M. Fn binding to PC was inhibited by the addition of Arg-Gly-Asp-Ser (RGDS), a tetrapeptide containing the active site of the cell-binding domain of Fn. PC attachment to an alveolar epithelial cell line was quantified using 51Cr-labeled PC trophozoites. Attachment was decreased from 24 +/- 1.9% to 12.1 +/- 1% (P less than 0.01) by the addition of an anti-Fn antibody, an effect that could be overcome by the addition of excess free Fn. It is concluded that binding of Fn to PC may be an important initial step in the attachment of the organism to alveolar epithelial cells. Furthermore, it appears that PC recognizes and binds to the RGDS cell attachment site of Fn.

Lamellar body formation precedes pulmonary surfactant apoprotein expression during embryonic mouse lung development in vivo and in vitro

The purpose of this investigation was to determine whether lamellar inclusion body (LB) formation and surfactant apoprotein (SP-35) production are directly coordinated by temporal and positional information during development. In the present study we report a comparison between embryonic B10.A mouse lung morphogenesis and cytodifferentiation in vivo with that observed during organ culture in serumless medium. Precursor LB were first detected at embryonic day 12 (E12d), and progressively larger numbers and forms were produced during subsequent differentiation of respiratory alveolar duct epithelium. SP-35 was first detected during the canalicular period (E16.5d). Lung cultures (E12d) showed pseudoglandular and canalicular periods of morphogenesis, and both ciliated epithelial and type II cell differentiation. Nonciliated cells produced increasing numbers of lamellar inclusion bodies throughout the culture period. SP-35 was detected at 9 days in vitro (d.i.v.). These observations indicate (i) precursor LB formation precedes SP-35 expression and is not dependent on apoprotein synthesis; (ii) E12d lung development in vitro using serumless medium proceeds at a rate equivalent to 0.5 days in vivo through 11 d.i.v.; and (iii) morphogenesis and differentiation occur in the absence of exogenous hormones and growth factors. The cell-cell interactions that play a role in morphogenesis and cell differentiation appear to be intrinsic to the developmental program for embryonic lung development and are likely to be mediated by autocrine and/or paracrine factors.

The ultrastructure of epithelial cells of the distal lung

This review has focused on the structural and functional characteristics of those epithelial cells that line the walls of the lower respiratory bronchioles, alveolar ducts, and alveoli. In all, five cells types were considered: Clara cells, types I, II, and III pneumocytes, and alveolar macrophages. In addition, a very brief mention of the structure and influence of the basement membrane in alveolar development and repair was included, as well as a brief review of the role of epithelial cells in response to selected deleterious influences. No attempt was made to extend this review to cover the structure and functions of the epithelial lining of the conducting portions of the respiratory system, or the exciting and expanding complexities and interrelationships of the septal stroma. Since the volume of literature encircling this subject has virtually exploded during the last 15 years, it becomes almost impossible to review all reports. However, attempts were made to be selective in citations. Insofar as future developments are concerned, much remains to be understood concerning (1) the responses of all cell types to cytotoxic influences, including their respective abilities to repair induced damage, (2) cell-cell and cell-extracellular matrix relationships in response to injury, (3) the uniqueness of the basement membrane in the lung in controlling permeability and gaseous exchange, (4) the role(s) of alveolar macrophages in response to injury and their relationships to the septal macrophage population, (5) the aberrations in the respective cell types that can give rise to neoplastic growth, and (6) the role of the immune system in responding to the general defense of the lung. Indeed much has been learned in the past 2 decades, and it is expected that a review of this sort 1 or 2 decades hence will elucidate many of the functions and structural modifications of the lung.

Changes in lung tissue fibronectin content and synthesis during postnatal lung growth

We studied changes in lung tissue fibronectin content and synthesis during postnatal lung growth in rats. We reasoned that fibronectin, which is important in cell differentiation, migration, and adhesion, and in the organization of the extracellular matrix, might play a role in the rapid cell proliferation and alveolar septal formation that occurs postnatally in mammalian lungs. Newborn rats were sacrificed at 4, 7, 11, 14, and 21 days after birth. The lungs were perfused and lavaged, tissue fibronectin was extracted using urea and heparin (Bray et al, Science 1981; 214:793) and the extracted fibronectin was measured by enzyme-linked immunoassay. Tissue fibronectin synthesis was measured by the in vivo incorporation of 35S-methionine into fibronectin that was extracted from lung tissue and immunoprecipitated. Lavage fibronectin and albumin content and lung tissue collagen (hydroxyproline) content were also determined. Lung tissue fibronectin content per g dry lung almost doubled between days 4 and 7 after birth, was slightly higher at day 14 than at day 7, and decreased sharply between days 14 and 21. Lung tissue fibronectin synthesis per g dry lung increased steadily between days 4 and 14 to reach a peak value of about 2.5 times the 4-day value; it then decreased sharply between days 14 and 21. The period of increased fibronectin content and synthesis (4 to 14 days) coincided with the period during which lung cell proliferation and secondary alveolar septa formation are known to be the most active, and the sharp decrease in fibronectin content and synthesis (between 14 and 21 days) coincided with the period during which lung growth and remodeling markedly decrease.(ABSTRACT TRUNCATED AT 250 WORDS)

Localization and accumulation of fibronectin in rabbit fetal lung tissue

An interaction between mesenchyme and epithelium is required for the normal differentiation of fetal lung tissue. This morphogenic interaction may be mediated, in part, by changes in the composition and/or structure of the extracellular matrix. Therefore, we characterized the localization and accumulation of fibronectin, an extracellular-matrix component, during several stages of lung development in the rabbit fetus in vivo as well as in day-21 rabbit fetal lung explants maintained in vitro. Fibronectin was detected immunocytochemically in the basement-membrane zone beneath the epithelial ducts in lung tissue obtained from rabbit fetuses at 19 and 21 days of gestation. In fetal lung tissue obtained at these early stages of lung development, mesenchymal cells were stained only at their periphery. Immunostaining for connective-tissue fibronectin increased greatly between days 24 and 31 of gestation. A similar increase in the intensity of immunostaining for connective-tissue fibronectin was observed in rabbit fetal lung explants that had been maintained in vitro for 7 days. The concentration of fibronectin in fetal lung tissue obtained at different days of gestation was determined using a specific enzyme-linked immunoadsorbent assay (ELISA) and was found to increase from 1.7 ng/micrograms protein in fetal lung tissue obtained at day 19 of gestation to 7.3 ng/micrograms protein in fetal lung tissue obtained at day 24 of gestation. The levels of fetal lung fibronectin then remained relatively constant through to day 31 of gestation. A similar increase in fibronectin concentration was observed in day-21 fetal lung explants maintained in vitro for 7 days.(ABSTRACT TRUNCATED AT 250 WORDS)

Cytochemistry of the gas-exchange area in vertebrate lungs

Considerable progress has been made in the localization of chemical substances within the gas-exchange zones of vertebrate lungs since cytochemical techniques suitable for use with the electron microscope have been developed. The light microscope, an instrument with an effective resolution limit of about 0.2 micron, is ill-suited for studying regions such as these where small tissue elements are arranged in a complex manner. A wide range of acid hydrolases have been detected in the vacuoles and dense bodies of alveolar macrophages by means of cytochemical techniques. The enzymes demonstrated in this way include acid phosphatase, aryl sulphatase, cathepsin D, beta-glucuronidase, acetyl glucosaminidase, nonspecific esterase, dipeptidyl peptidase II and dipeptidyl peptidase IV. Such enzymes are, of course, to be expected in the lysosomes of cells which have a primary phagocytic role. Nevertheless, it must be confessed that very little is yet known about the actual mechanism of phagocytosis or of the fate of the digested material. It is fortunate, however, that some of the tools which are likely to be of value in research on these aspects of macrophage function are currently being developed. Of particular interest in this connection are the immunocytochemical techniques which permit the localization of surface-associated antigens and intracellular contractile proteins. It must be emphasized that phagocytosis is not the only function of macrophages in the gas-exchange zone of the lung. These cells are thought to be involved in the presentation of exogenous antigenic material to the reactive cells of the lymphoid system. Recent research has also indicated that mammalian alveolar macrophages synthesize a diverse range of substances. Furthermore, the elastases associated with pulmonary macrophages are now thought to be involved in the pathogenesis of emphysema. All of the above-mentioned activities are of great biological and clinical significance and, consequently, merit the cytochemists' attention in future. The epithelial lining of the greater part of the pulmonary gas-exchange area is composed of type I pneumonocytes. In terms of ultrastructure, these are very specialized cells; their extensive and highly-attenuated cytoplasmic processes form the outer layer of the air-blood barrier. No special carrier systems have been identified within type I pneumonocytes and this is in keeping with the claims that oxygen is transferred across the alveolar tissue barrier by a process of simple diffusion. Type II pneumonocytes, in contrast, have considerable metabolic activity.(ABSTRACT TRUNCATED AT 400 WORDS)

Coupled expression and colocalization of 140K cell adhesion molecules, fibronectin, and laminin during morphogenesis and cytodifferentiation of chick lung cells

We have analyzed the expression and distribution of fibronectin, laminin, and the 140K cell adhesion molecules (140K complex) in embryonic chick lung cells by a combination of biochemical and immunofluorescent approaches. The 140K complex was identified by monoclonal antibody JG22E as a complex of glycoproteins averaging 140,000 Mr and has been implicated in vitro as a receptor for fibronectin and laminin. Our studies provide the first description that the 140K complex is developmentally regulated, and that the 140K complex appears to be involved in adhesion of epithelial and endothelial cells during morphogenesis. We have shown that the 140K complex is expressed in high quantity in embryonic lung cell types, but is markedly reduced in all of the differentiated cell types except smooth muscle. Embryonic lung cells are enriched in 140K complex on portions of cells in close proximity to areas rich in fibronectin. For example, during the formation of airways and alveolar tissues, 140K complex is concentrated at the basal surfaces of epithelial cells adjacent to fibronectin. Likewise, during the angiogenic invasion of capillaries into lung mesenchyme, the 140K complex becomes localized at sites on the basal surfaces of endothelial cells in close contact with fibronectin. Finally, cytodifferentiating lung smooth muscle cells show unusually high levels of 140K complex, fibronectin, and laminin that persist into the adult. In contrast to fibronectin, laminin is found to be uniformly distributed in the basement membranes of differentiating epithelial cells. It becomes prominent in adult alveolar epithelium and airway epithelium concomitant with a reduction or loss of 140K complex and fibronectin at cell-basement membrane attachment sites. Surprisingly, laminin is also present in a punctate pattern in the mesenchyme of early lung buds, however, laminin, fibronectin, and 140K complex are greatly reduced or lost during mesenchymal maturation. Our results are consistent with the active participation of the 140K complex in cell-to-matrix adhesion during morphogenesis of alveolar walls and cytodifferentiation of mesenchymal and smooth muscle cells.

Cell-cell matrix interactions in induced lung injury. II. X-irradiation mediated changes in specific basal laminar glycosaminoglycans

The thoraces of male LAF1 mice were irradiated at doses of 5, 9, or 13 Gy. The animals were killed at times of 1 hr, 1 day, 1 wk, 4 wks, and 12 wks postirradiation (PI). The lungs were removed, enzymatically or detergent digested, fixed with ruthenium red for demonstration of anionic sites, and processed for electron microscopy. Untreated (0 Gy, 0 time) and sham irradiated control groups were also processed. Sections of lungs were examined and changes in alveolar basal laminar anionic sites were quantitated. Changes in three groups of glycosaminoglycans (GAGs) were identified: chondroitin 4 and 6 sulfate-dermatan sulfate, hyaluronate, and other GAGs (principally heparan sulfate). At 1 hr PI, all groups showed a marked decrease in site number over controls, which continued to 1 wk. By 4 wks there was a marked relative increase in heparan sulfate containing sites for doses of 13 Gy and a moderate increase for the other doses. At 12 wks the level of heparan sulfate was considerably above normal for doses of 13 Gy and just above normal for the other doses. Chondroitin-dermatan sulfate had recovered by 12 wks for doses of 13 Gy, but was still subnormal for other doses; however, hyaluronate-containing sites recovered only slightly by 12 wks. The implications for this change on basal laminar permeability and the induction of fibrosis are discussed.

Ultrastructural and immunofluorescence studies of basal-lamina alterations during mouse-lung morphogenesis

Epithelial differentiation during lung development appears to be influenced by mesenchyme-derived instructions coupled with hormonal regulations. The basal lamina which is associated with progenitor and differentiating epithelia during mouse embryogenesis (Theiler-stages 16-28) was examined by transmission electron microscopy and indirect-immunofluorescence microscopy. During the embryonic phase of lung development, progenitor epithelia for the pulmonary acinus projected microvilli or cytoplasmic "feet" through the basal lamina, which resulted in discontinuities and a close approximation of the adjacent mesenchymal-cell processes. These changes were also associated with the transitory polarization of mesenchymal cells perpendicular to the plane of the basal lamina, which resulted in a sheet of cuboidal mesenchymal cells adjacent to the developing acinar-tubule epithelium. During the embryonic phase of lung development, these specific interstitial or mesenchymal cells stained for heparan-sulfate proteoglycans; no other cell types were immunostained. By Theiler-stage 25, the acinar-tubule epithelia had differentiated into type-II pneumonocytes which contained lamellar bodies and significant amounts of glycogen. Fibronectin, laminin, and heparan-sulfate proteoglycan were localized in the basement membranes during the embryonic, canalicular, and terminal sac phases of lung morphogenesis. A diffuse localization of fibronectin of the interstitial cell surfaces was observed. These observations indicate that major changes in the structure and composition of basal lamina occur during the embryonic and fetal phases of pulmonary-acinus epithelial-cell differentiation and the production of pulmonary surfactant. The major changes in the basal lamina may be partly mediated by mesenchyme-derived instructions for type-II epithelial-cell differentiation.