Different lung responses to cigarette smoke in two strains of mice sensitive to oxidants.

The development of cigarette smoke-induced pulmonary changes in C57 Bl/6J and DBA/2 mice was investigated. Both strains are sensitive to oxidants and C57Bl/6J mice are moderately deficient in serum alpha1-proteinase inhibitor. Following chronic exposure to cigarette smoke, patchy emphysema was present in mice of both strains, but developed faster in DBA/2 mice. A positive reaction for mouse neutrophil elastase was seen on the septa of both strains. Additionally, the DBA/2 mice developed a uniform parenchymal dilation that was preceded by the appearance of apoptotic cells in areas with a low signal for vascular endothelial growth factor-receptor 2. Fibrotic areas scattered throughout the parenchyma, coupled with a positive immunohistochemical reaction for transforming growth factor-beta was seen only in DBA/2 mice. Both DBA/2 and C57Bl/6J strains showed epithelial cell injury and areas of deciliation in their airways. However, the appearance of goblet cell metaplasia was common in C57Bl/6J mice but rare in DBA/2 mice. A positive immunohistochemical reaction for interleukin (IL)-4, IL-13 and MUC5AC was seen only in the airways of C57Bl/6J mice. Strain characteristics (alpha1-proteinase inhibitor levels, sensitivity to oxidants, and constitutive levels of vascular endothelial growth factor-receptor 2) and phenotypical responses (apoptosis and cytokine distribution) may condition parenchymal and airway changes to cigarette smoke.

Collagen phagocytosis by lung alveolar macrophages in animal models of emphysema.

Under steady state conditions the intracellular pathway is the major route of collagen catabolism in tissues characterised by rapid collagen turnover. In the lung, the collagen is subject to continuous remodelling and turnover however, the intracellular pathway of collagen degradation is unusual under physiological conditions. The current authors previously described crystalloid inclusions in alveolar macrophages of mice with genetic emphysema at the time of septal disruption. Using an immunogold technique these inclusions were identified as collagen-derived products and related to intracytoplasmic collagen degradation. To examine whether a different degree of protease burden in lung interstitium may influence the route of intracellular collagen degradation, collagen phagocytosis by alveolar macrophages was studied in various mouse models of emphysema at the time when emphysema develops. Evident collagen by-products in alveolar macrophages were observed in destructive processes characterising spontaneous models of emphysema either with negligible (blotchy mouse) or moderate (pallid mouse) elastase burden. On the other hand, intracellular collagen by-products were appreciated only in a few macrophages from tight-skin mice with high elastolytic burden and could not be observed in mice with a very severe burden after elastase instillation. In conclusion, the interstitial level of proteases burden can affect the way by which the collagen is cleared (intracellularly versus extracellularly).

Effects of cigarette smoke in mice with different levels of alpha(1)-proteinase inhibitor and sensitivity to oxidants.

The role of strain difference in the response to cigarette smoke was investigated in mice. Mice of the strains DBA/2 and C57BL/6J responded to acute cigarette smoke with a decrease of the antioxidant defenses of their bronchoalveolar lavage (BAL) fluids. On the other hand, under these conditions ICR mice increased their BAL antioxidant defenses. Mice of these three strains were then exposed to cigarette smoke (three cigarettes/d, 5 d/wk) for 7 mo. Lung elastin content was significantly decreased in C57BL/6J and DBA/2 but not in ICR mice. Also, emphysema, assessed morphometrically using three methods, was present in C57BL/6J and DBA/2 but not in ICR mice. In an additional study pallid mice, with a severe serum alpha(1)-proteinase inhibitor (alpha(1)-PI) deficiency and that develop spontaneous emphysema, were exposed to cigarette smoke for 4 mo. This resulted in an acceleration of the development of the spontaneous emphysema assessed with morphometrical and biochemical (lung elastin content) methods. All these results indicate that sensitivity to the effects of cigarette smoke is strain-dependent and cigarette smoke accelerates the effects of alpha(1)-PI deficiency.

Human SLPI inactivation after cigarette smoke exposure in a new in vivo model of pulmonary oxidative stress.

The role of oxidative stress in inactivating antiproteases is the object of debate. To address this question, we developed an in vivo model of pulmonary oxidative stress induced by cigarette smoke (CS) in mice. The major mouse trypsin inhibitor contrapsin is not sensitive to oxidation, and the mouse secretory leukoprotease inhibitor (SLPI) does not inhibit trypsin. Instead, human recombinant (hr) SLPI inhibits trypsin and is sensitive to oxidation. Thus we determined the effect of CS in vivo on hrSLPI antiproteolytic function in the airways of mice. CS caused a significant decrease in total antioxidant capacity in bronchoalveolar lavage fluid (BALF) and significant changes in oxidized glutathione, ascorbic acid, protein thiols, and 8-epi-PGF(2alpha). Intratracheal hrSLPI significantly increased BALF antitryptic activity. CS induced a 50% drop in the inhibitory activity of hrSLPI. Pretreatment with N-acetylcysteine prevented the CS-induced loss of hrSLPI activity, the decrease in antioxidant defenses, and the elevation of 8-epi-PGF-(2alpha). Thus an inactivation of hrSLPI was demonstrated in this model. This is a novel model for studying in vivo the effects of CS oxidative stress on human protease inhibitors with antitrypsin activity.

Genetic deficiency of alpha1-PI in mice influences lung responses to bleomycin.

It has recently been suggested that proteinase inhibitors modulate the fibrotic response in the lung. This study investigated the development of bleomycin-induced pulmonary changes in pallid mice, deficient in serum alpha1-proteinase inhibitor, and with a lower elastase inhibitory capacity, and in congenic C57Bl/6J mice. Male pallid and C57Bl/6J mice received a single intratracheal instillation of either saline or bleomycin. The investigation was carried out by means of biochemical, morphological and morphometrical methods. In both strains, 21 and 72 h after bleomycin, the lungs showed foci of inflammatory cell infiltration associated with emphysema. Fibrosis developed with time after bleomycin. At 14 days fibrosis affected 23.46+/-9.48% (mean +/- SD) and 40.62+/-13.34% (p < 0.01) of the lungs of C57Bl/6J and pallid mice, respectively. Emphysema affected 3.68+/-3.11% and 12.57+/-4.13% (p<0.01) of lung in C57Bl/6J and pallid mice, respectively. In C57Bl/6J mice bleomycin increased lung hydroxyproline content by 34% and desmosine content by 44% (p < 0.01 for both). In pallid mice these increases were only 21% (p < 0.01) and 6% which may reflect parenchymal loss. Thus, the lung destructive response (emphysema) and the subsequent proliferative reaction (fibrosis) to bleomycin are potentiated in alpha1-proteinase inhibitor deficiency.

Tumor necrosis factor receptor deficiency alters matrix metalloproteinase 13/tissue inhibitor of metalloproteinase 1 expression in murine silicosis.

Murine exposure to silica is associated with enhanced tumor necrosis factor alpha (TNF-alpha) expression and matrix deposition. The regulation of TNF is mediated through TNF receptor (TNFR) activation of transcription factors. In the present work we have studied the importance of the individual TNFR in silica-induced lung inflammation and matrix deposition in mice. We studied RNA expression of TNF, alpha1(I) collagen, interstitial collagenase (MMP-13), and its inhibitor (TIMP-1) in the lungs of silica-treated mice. Furthermore, we correlated MMP-13/TIMP-1 RNA abundance with activation of the transcription factors AP-1 and NF-kappaB in the lungs of C57BL/6 mice, and of mice deficient in one of the two types of TNFR (p55(-/-) or p75(-/-)), exposed to silica (0.2 g/kg) or saline by intratracheal instillation. Animals were killed 28 d after exposure and lung hydroxyproline (HP), TNF, alpha1(I) collagen, MMP-13, and TIMP-1 RNA abundance was measured. AP-1 and NF-kappaB activation was studied by gel-shift assays. Compared with C57BL/6 mice, p55(-/-) and p75(-/-) mice significantly (*p < 0.05) decreased lung HP accumulation in response to silica. All murine strains enhanced TNF and alpha1(I) collagen mRNA in response to silica. Enhanced (p < 0.05) MMP-13 RNA expression was also observed in all murine strains in response to silica. Enhanced (p < 0.05) TIMP-1 RNA expression was observed in C57BL/6 mice, but not in p55(-/-) or p75(-/-) mice, in response to silica. NF-kappaB activation was observed in all murine strains, whereas AP-1 activation was observed only in C57BL/6 mice after silica treatment. These data suggest that TNFR deletion modifies MMP-13/ TIMP-1 expression in favor of matrix degradation.

Ultrastructure of lung elastin and collagen in mouse models of spontaneous emphysema.

The tight-skin (Tsk) and beige (bg) mutants of the C57B1/6J strain of mouse spontaneously develop air-space enlargement reminiscent of human emphysema. To determine if this enlargement is accompanied by matrix destruction, as in the human disease, we examined the elastin and collagen matrices of the lungs of both mutants. The ultrastructure of these matrix components was separately visualized by scanning electron microscopy following controlled alkali digestion, which preserves collagen, and formic acid digestion, which enables visualization of elastin. Significant elastin destruction suggestive of an elastolytic process was observed in the lungs of Tsk mice. Thickening of elastin lamellae was observed in the lungs of bg mice, suggesting that congenital matrix remodeling may underlie air-space enlargement in this strain.

Upregulation of the p75 but not the p55 TNF-alpha receptor mRNA after silica and bleomycin exposure and protection from lung injury in double receptor knockout mice.

We have investigated a potential role for tumor necrosis factor (TNF)-alpha and its two receptors (p55 and p75) in lung injury. We used several varieties of mice exposed endotracheally to two fibrogenic agents, silica (0.2 g/kg) and bleomycin (4 U/kg). The lungs were analyzed at 14 and 28 d after exposure to bleomycin or silica, respectively, for TNF and TNF receptor (TNFR) messenger RNA (mRNA), hydroxyproline content, and histopathology. Silica induced increased (over saline-treated animals) expression of TNF mRNA in double TNFR knockout (Ko), C57BL/6, BALB/c, and 129/J mice. In contrast, bleomycin increased expression in all but BALB/c mice, which are resistant to the fibrogenic effects of this drug. mRNA expression of both receptors was constitutively expressed in all of the normal murine strains. Silica upregulated expression of the p75 receptor, but not the p55 receptor, in the C57BL/6, BALB/c, and 129/J mice. In comparison, bleomycin had little effect on either receptor in the bleomycin-resistant BALB/c mice. Hydroxyproline content of the lungs after treatment followed this same pattern, with significant increases caused by silica in the C57BL/6, BALB/c, and 129/J mice, whereas bleomycin caused no apparent increases in the BALB/c mice. Even though silica and bleomycin induced increases in TNF in the TNFR Ko mice, the mice were protected from the fibrogenic effects of these agents. This study supports the concept that TNF is a central mediator of interstitial pulmonary fibrosis.

Neutrophil influx into the lungs of beige mice is followed by elastolytic damage and emphysema.

The beige mouse is currently used as a model of elastase and cathepsin G deficiency to demonstrate or exclude the role of these proteases in a variety of pathologic conditions. We recently demonstrated that beige cathepsin G is tightly bound to neutrophil lysosomal membranes but is released in near normal quantities during exocytosis. Also, beige neutrophils contain a latent form of elastase that undergoes spontaneous activation when released under in vitro or in vivo conditions. However, the pathogenic potential of this enzyme in matrix degradation has not been ascertained previously. The possibility that in beige mice elastolytic proteases from neutrophils recruited into the lung have the capability to damage alveolar septa was investigated following an intratracheal instillation of N-formyl-L-methionyl-L-leucyl-L-phenylalanine (200 microg). Neutrophil influx was followed by a decrease in lung elastin content (-18%) and by a significant increase of the mean linear intercept (+30%) and of morphologic emphysema. The onset of pulmonary lesion was preceded by a marked increase of neutrophil elastase burden on the alveolar interstitium. The appearance of emphysema was prevented by administration of the serine protease inhibitor 4-(2-aminoetyl)-benzenesulfonyl fluoride hydrochloride (2. 4 microg/ml saline). These results demonstrate that the lung elastin degradation and emphysema can occur in beige lungs. The fact that the beige mouse does develop lung elastolytic changes after neutrophil recruitment indicates that this mutant cannot be considered a model of neutrophil function deficiency and used as a model of elastase deficiency.

Lung injury and degradation of extracellular matrix components by Aspergillus fumigatus serine proteinase.

Aspergillus fumigatus produces a variety of extracellular proteinases that are believed to be virulence factors towards Aspergillus-related lung disease. Among Aspergillus proteinases, the serine proteinase is thought to play a major virulent role because of its widespread production. Nevertheless, evidence of direct pulmonary injury caused by the A. fumigatus serine proteinase is still lacking. The purpose of our work was: (1) to provide evidence for a pivotal role of A. fumigatus serine proteinase in producing lung injury in an animal model, and (2) to investigate the broadness of the substrate specificity of the proteinase towards extracellular matrix components. To achieve this aim, the proteinase from an A. fumigatus strain isolated from human airways was purified by a four-step procedure, including cation exchange and hydrophobic interaction. High-performance capillary electrophoresis, SDS-PAGE, determination of K(m) towards synthetic substrates, and inhibitory studies were used to further characterize the A. fumigatus serine proteinase. With reference to extracellular matrix components, the A. fumigatus serine proteinase was shown to degrade human lung elastin at a higher rate than an equimolar amount of human neutrophil elastase. Human lung collagen, type I and type III collagens, as well as fibronectin, were quickly digested by the A. fumigatus serine proteinase. Finally, mice intratracheally injected with the proteinase showed a significant degree of lower respiratory tract destruction. We conclude that the A. fumigatus serine proteinase is capable per se of hydrolyzing the major structural barriers of the lung.

Neutrophils in beige mice secrete normal amounts of cathepsin G and a 46 kDa latent form of elastase that can be activated extracellularly by proteolytic activity.

Among other phenotypic defects, the beige mouse is susceptible to infection and has large neutrophil granules that apparently secrete a decreased amount of elastolytic activity. We have shown using in vitro methods that cytosolic inhibitors in beige neutrophils are normal. Although cathepsin G is tightly bound to lysosomal membranes, normal amounts of activity are released in response to degranulating agents. Decreased elastolytic activity is secreted by beige neutrophils because elastase is present in the granules as a 46 kDa proenzyme, which can be activated extracellularly by a protease-dependent mechanism. The current experiments were undertaken to explore the in vivo functions of neutrophils from C57 BI/6J (bg/bg) beige mice using the model of casein-induced acute peritonitis; normal C57 BI/6J (+/+) mice served as controls. The kinetics of neutrophil accumulation in the peritoneum were normal, suggesting normal neutrophil migration. Cathepsin G activity in the cell-free supernatant of peritoneal lavage fluid was normal; elastolytic activity was initially very low but increased to about twice baseline level after 4 h at 25 degrees C and to about 20-fold at 36 h. The appearance of this activity was inhibited to varying degree (54 to 83%) by different protease inhibitors (pepstatin, antipain, aprotinin, leupeptin and chymostatin). We conclude that the decreased amount of elastolytic activity secreted by beige neutrophils into an inflammatory exudate is due to a genetic defect that results in production of a 46 kDa proelastase rather than the normal 29 kDa active elastase; the proelastase can be spontaneously activated by a protease-dependent mechanism. In light of these data, the use of the beige mouse as a model for the Chediak-Higashi syndrome, and as a model in which neutrophils do not produce elastase, must be reconsidered.

Neutrophil recruitment into the lungs is associated with increased lung elastase burden, decreased lung elastin, and emphysema in alpha 1 proteinase inhibitor-deficient mice.

The possibility that polymorphonuclear leukocytes (PMN) recruited into the lung have the capability to damage alveolar septa was investigated in several strains of mice with different serum alpha 1 proteinase inhibitor levels and PMN lysosomal functions. After an intratracheal instillation of FMLP (200 micrograms), all strains of mice showed a similar PMN influx in alveolar spaces with an increase (approximately 4- to 5-fold) in bronchoalveolar lavage total cell count, which peaked at 24 to 48 hours. At this time, differential cell count in all strains revealed an approximately 40-fold increase in neutrophils. In C57BL/6J and pallid mice but not in NMRI mice, PMN influx was followed by a decrease in lung elastin content (-17% and -37%, respectively) and by the development of significant emphysema (mean linear intercept, +28% and +56%, respectively). The onset of the pulmonary lesion was preceded by a marked increase of neutrophil elastase burden in alveolar interstitium. Compared with NMRI mice, C57BL/6J and pallid mice have lower serum elastase inhibitory capacity levels. The degree of lung destruction was inversely correlated with elastase inhibitory capacity levels. Lung elastin degradation and emphysema may be induced by eliciting PMN into the lungs only in animals with a deficient anti-elastase screen. Compared with C57BL/6J mice, pallid mice showed a significantly greater lung elastin loss and a higher degree of emphysema after FMLP treatment. These differences may be accounted for by the higher baseline levels of interstitial elastase burden. It may be assumed that an enzymatically active elastase was already working on the lung interstitium before FMLP instillation in pallid mice.

A scanning electron microscopic investigation of genetic emphysema in tight-skin, pallid, and beige mice, three different C57 BL/6J mutants.

Three mutants of the C57 BL/6J strain, i.e., the tight-skin (Tsk), pallid (pa), and beige (bg) mice have been reported to develop spontaneous emphysema. However, the pathogenic mechanisms of this lesion may be different in the three mutants. Differences and similarities of these models were investigated by means of scanning electron microscopy. A light microscopic investigation provided the background for the SEM study. C57 BL/6J (control), pa, Tsk, and bg mice were killed when they were 1, 12, and 24 months old. At light microscopic investigation the lungs of the controls appeared normal at all ages. Those of the pa mice had normal appearance at 1 month, showed a few areas of air space enlargement with destruction of alveolar septa at 12 months, and had a generalized enlargement of the air spaces associated with distortion of alveolar septa at 24 months. The Tsk mice had a generalized panlobular emphysema at all ages. The lungs of the bg mice showed at all ages a generalized enlargement of the air spaces not accompanied by changes of the alveolar septa. At scanning electron microscopy the lung parenchyma of control mice was essentially normal at all ages. Both alveolar ducts and alveoli increased in size (the latter also in depth) with age. The number of interalveolar pores (Np) increased by 54% between 1 and 12 months of age and by 49% between 12 and 24 months. The parenchyma of pa mice did not differ significantly from that of the controls at 1 month. At 12 months the alveoli appeared to be larger. At 24 months in some fields alveolar ducts were enlarged, the alveoli were also enlarged and very shallow. Np was not different from controls at 1 month but greater at 12 (+ 49%) and 24 (+ 26%) months. The parenchyma of Tsk mice of all ages appeared distorted with enlargement of alveolar ducts and sacs and with alveoli with a large number of pores. These changes increased with age. Np was larger than the controls at all ages (+ 59% at 1 month, + 119% at 12 months, and + 80% at 24 months). The parenchyma of the bg mice of all ages appeared disorganized with large alveoli of different shapes. There was a deterioration with age. No difference in Np was seen at any age between bg and control mice. Parenchymal changes characterized by distortion and enlargement of alveolar ducts and sacs were observed, even if with different onset and extent, in all mutants. However, an increase in Np, which is considered to represent the early development of emphysema, was found only in Tsk and pa mice. In Tsk mice, high Np values were observed at all ages, whereas in pa mice Np was increased only late in life when the pulmonary lesion develops. These differences indicate different pathogenetic mechanisms for these three mutants.

Pallid mice with genetic emphysema. Neutrophil elastase burden and elastin loss occur without alteration in the bronchoalveolar lavage cell population.

BACKGROUND: According to a current hypothesis, pulmonary emphysema results from damage to the elastic fiber network caused by an imbalance within the lower respiratory tract between elastase(s) and protease inhibitors. This hypothesis is based largely on studies of persons with genetic deficiency of serum alpha 1-proteinase inhibitor. We recently reported a spontaneously occurring emphysema in the pallid mouse with an inherited deficiency of serum alpha 1-proteinase inhibitor. This animal reproduces important features of the human condition. We describe here the changes in alveolar elastolytic burden and in the bronchoalveolar lavage (BAL) cell population, which precede and accompany the development of emphysema in pallid mice. EXPERIMENTAL DESIGN: A possible correlation between the levels of lung elastase burden and the loss of lung elastin content was investigated in the period of development of emphysema in pallid mice. Changes in alveolar cells were investigated for specimens from BAL fluids and lung tissue by cytologic, histologic, and immunogold-electron microscopic methods. RESULTS: An immunogold-positive reaction for elastase was observed on elastin within the alveolar walls of pallid mice from 2 months onward. The average of gold particle density progressively increased with age, reaching high values at 12 and 16 months of age, the age at which parenchymal destruction was previously reported to occur. Lung elastin content had normal values at 2, 4, and 8 months of age. However, it was significantly lower at 12 and 16 months of age. The immunogold values of elastase burden correlated inversely with the decrease in lung elastin content. Total and differential cell counts from BAL fluids of pallid mice did not differ significantly at any time in life and were similar to age-matched controls. However, in pallid mice from 8 months of life onward, pulmonary macrophages contained characteristic intracytoplasmic crystalloid inclusions, which were electrondense and bounded by a single membrane. Using electron microscopy and an immunogold-labeling technique with anti-mouse I-III collagen IgG, these inclusions were identified as collagen-derived products. CONCLUSIONS: The data reported in this paper suggest that emphysematous lesions in pallid mice are associated with a progressive increase of elastase in alveolar intestitium and with loss of lung elastin. Surprisingly, the number of neutrophils in BAL fluids does not increase with the increase of lung elastolytic burden. However, intracytoplasmic crystalloid inclusions related to collagen degradation were observed in pulmonary macrophages of pallid mice at the time of septal disruption. The presence of similar structures in alveolar macrophages from mice or other animal species may be indicative of connective tissue breakdown or remodeling of tissue collagen.

Purification and N-terminal amino-acid sequence analysis of rabbit neutrophil cathepsin G.

Cathepsin G was isolated from granules of rabbit bloodstream leukocytes and purified to apparent homogeneity by a multi-step procedure consisting of ammonium sulphate precipitation, affinity chromatography on elastin-Sepharose, and finally by ion-exchange chromatography on a CM-52 column. The molecular weight of the enzyme, as determined by sodium dodecyl sulphate-polyacrylamide gel electrophoresis (SDS-PAGE), was 27,000. The first 24 N-terminal amino-acids were determined and showed 96%, 92% and 79% identity respectively to those of human, dog and rat cathepsin G. Despite the difference in the total amino-acid composition of cathepsin G between rabbit and other mammalian species, close similarities have been found in their substrate specificity and inhibition profile. The kcat/Km values of rabbit cathepsin G with Suc-Ala2-Pro-Phe-NA and Suc-Ala2-Pro-Leu-NA are quite similar to those reported for human cathepsin G under the same conditions. The inhibition profile of the isolated enzyme indicates that cathepsin G from rabbits, like that from other mammalians species belongs to the group of serine proteinases. Finally, like human cathepsin G, catalytically active rabbit enzyme is able to induce platelet aggregation.

Elastin production and degradation in cutis laxa acquisita.

A case of cutis laxa acquisita was studied with the aim of defining the molecular defects involved and comparing them with those of an inherited form of cutis laxa. In the acquisita form of cutis laxa ultrastructural and biochemical observations confirmed a dramatic reduction of dermal elastin, whereas collagen content was normal. Elastin mRNA expression as well as tropoelastin production by dermal fibroblasts, in vitro, were normal compared with control cells, as revealed by in situ hybridization and enzyme-linked immunosorbent assay, respectively. Lysyl oxidase activity, measured on cultured fibroblasts, was reduced to 60% compared with age-matched control subjects. Unlike control skin fibroblasts or fibroblasts from inherited cutis laxa, the affected skin cells from cutis laxa acquisita predominantly expressed an elastolytic activity identified as cathepsin G. Patient serum also has reduced elastase inhibitory capacity and reduced levels of alpha 1-antiproteinase inhibitor (alpha 1-antitrypsin). Although cutis laxa acquisita is a heterogeneous group of disorders, findings in this patient were consistent with excessive loss of cutaneous elastin due to the combined effects of several factors, such as low lysyl oxidase activity together with high levels of cathepsin G and reduction of circulating proteinase inhibitor(s).

Cardiac collagen changes during the development of right ventricular hypertrophy in tight-skin mice with emphysema.

The tight-skin (Tsk) mouse is a genetic model of pulmonary emphysema. In this mouse, right ventricular hypertrophy (RVH) starts to develop at approximately 8 months of age, probably as a consequence of the emphysema. The aim of the present study was to investigate cardiac collagen synthesis, content, and types both before and during the development of RVH. Collagen synthesis, assessed by the [3H]proline incorporation method, was significantly increased in the right ventricle of 3-month-old Tsk mice. This was accompanied by a marked increase in right ventricle collagen content. Collagen typing showed no difference from controls. At 8 months of age collagen synthesis had returned to control values, right ventricular collagen content was elevated but held lower values than at 3 months, and collagen typing showed a prevalence of the more compliant type III. By 16 months of age, right ventricular collagen content had returned to control values and there was a shift in collagen types due to a relative increase of the more rigid type I. At 24 months of age right ventricular collagen content was increased again and collagen type I continued to predominate. These results suggest a dynamic role for collagen both before and during the development of RVH secondary to emphysema.

Collagen breakdown products and lung collagen metabolism: an in vitro study on fibroblast cultures.

BACKGROUND: In fibrotic diseases such as pulmonary fibrosis there is evidence suggesting enhanced synthesis and degradation of lung connective tissue components, including collagen. It has therefore been hypothesised that products of collagen degradation may have a role in the promotion of collagen deposition. In support of this hypothesis, it has recently been shown that intravenous injection of lung collagen degradation products in experimental animals stimulated collagen synthesis leading to increased collagen deposition and diffuse interstitial lung disease. METHODS: Rabbit and human fibroblast cultures from lung and skin were used as an in vitro model to study the responses of these cells to rabbit collagen degradation products. The effects of an acute exposure to collagen degradation products on synthesis of collagen and noncollagenous protein have been studied in confluent cultures by [3H]-proline incorporation. The effects of collagen degradation products on fibroblast proliferation and production of genetic types of collagen have also been investigated. RESULTS: The acute exposure of rabbit lung fibroblast cultures to collagen degradation products significantly increased collagen synthesis without affecting non-collagenous protein synthesis. This effect was dose related, specific for lung fibroblasts, and species specific. Collagen degradation products altered the rate of synthesis of genetic types of collagen with a consequent decrease of type III/I+III collagen ratio (0.26 (0.04) treated with collagen degradation products; 0.45 (0.02) controls). These effects occurred without the intervention of serum factors. In addition, collagen degradation products neither affected fibroblast proliferation nor selected specific clones emphasising one type of collagen. CONCLUSIONS: These results suggest that collagen degradation products can influence lung collagen metabolism by stimulating collagen synthesis. The regulation of collagen mass by collagen degradation products may be of importance in lung collagen homeostasis in vivo.

Neutrophil lysosomal dysfunctions in mutant C57 Bl/6J mice: interstrain variations in content of lysosomal elastase, cathepsin G and their inhibitors.

In this paper we report the serum antiprotease screening and the biochemical and functional characteristics of neutrophils in a variety of mouse strains with different susceptibilities for developing a protease-mediated injury. C57Bl/6J mice and their mutants tight-skin and pallid have a lower serum elastase inhibitory capacity (-30, -65 and -70% respectively) than other inbred strains (i.e. NMRI and Balb/c, which both have similar values). We demonstrate that these values are a consequence of a decreased concentration of the alpha 1-protease inhibitor for elastase [PI(E)], which is the major serum inhibitor of elastase and cathepsin G. In addition, neutrophil lysosomal dysfunctions characterized by abnormally high contents of elastase and cathepsin G, or defective lysosomal secretion are observed in tight-skin and pallid mice respectively. Another C57Bl/6J mutant with lysosomal abnormalities is the beige mouse. Negligible amounts of elastase and cathepsin G, as well as defective neutrophil degranulation, have been described previously in this strain. We found, however, discrete amounts of a latent form of neutrophil elastase that undergoes a spontaneous activation by a protease-dependent mechanism. We also report that neutrophil cathepsin G in this mouse is tightly bound to lysosomal membranes, but is released in near normal quantities during exocytosis. Cytosolic elastase and cathepsin G inhibitors, which were previously reported as being specific for the beige neutrophils, have also been detected in all the examined strains. Neutrophil functions, lysosomal enzyme content and serum antiprotease screening may represent key elements in the protease-antiprotease balance and may explain the different interstrain susceptibility to developing lesions in which an elastolytic activity has been implicated.

Lung collagen synthesis and deposition in tight-skin mice with genetic emphysema.

The tight-skin (Tsk) mouse is a genetic model of pulmonary emphysema linked to a deficiency of serum antielastase. In this mouse occurrence of connective tissue abnormalities in various organs (systemic scleroderma) has been reported. The aim of the present work was to study lung collagen synthesis and deposition in Tsk mice. No differences in the collagen synthesis rate and morphology at the ultrastructural level were found in Tsk mice at birth. At 2 months of age, a marked increase in collagen was observed within the alveolar septa. At this time, an increased lung collagen synthesis, assessed by determining prolyl hydroxylase activity and incorporation of radiolabeled proline, was found in Tsk mice with respect to control mice. However, due to the ongoing parenchymal destruction, the values of total lung collagen at 6 and 12 months of age were only moderately but significantly increased with respect to those observed at 2 months. As a consequence, a progressive accumulation of lung collagen fibers was observed in the residual septa. The increase in collagen deposition was accompanied by a relative increase in type I collagen. Although the data in the literature would suggest a genetic cause for the lung collagen change in Tsk mice, the data presented here indicate that the change in lung collagen metabolism may be a part of a remodeling process taking place after lung destruction.