Macromolecular synthesis in organ cultures of neonatal rat lung

Organ cultures of newborn rat lungs synthesize and accumulate DNA, RNA, collagen and noncollagenous proteins almost at a linear rate for at least 5 days. During this period the synthesis of collagen consistently exceeds the synthesis of noncollagenous proteins in a pattern similar to neonatal lung growth in vivo. Although some morphological characteristics of lung architecture are distorted after culture, fundamental structural similarities to lungs growing in intact animals are retained. When these cultures are maintained in atmospheres rich in oxygen, increased collagen synthesis is observed, a response similar to that of lungs in intact animals exposed to high oxygen concentrations in vivo. Our studies suggest that lung organ cultures may be a suitable system for investigating the biochemical aspects of lung tissue-environmental interaction. These studies were supported in parts by NIH Grant HL-19668, a contract (68-03-2005) from the U.S. Environmental Protection Agency, and grants from the California Lung Association.     

Effects of cis-4-hydroxy-L-proline, and inhibitor of Schwann cell differentiation, on the secretion of collagenous and noncollagenous proteins by Schwann cells

The proline analog cis-4-hydroxy-L-proline (CHP) was previously shown to inhibit both Schwann cell (SC) differentiation and extracellular matrix (ECM) formation in cultures of rat SCs and dorsal root ganglion neurons. We confirmed that CHP inhibits basal lamina formation by immunofluorescence with antibodies to laminin, type IV collagen, and heparan sulfate proteoglycan. In order to test the hypothesis that CHP inhibits SC differentiation by specifically inhibiting the secretion of collagen, cultures grown in the presence or absence of CHP were metabolically labeled with [3H]leucine and the media were analyzed for relative amounts of (a) collagenous and noncollagenous proteins by assay with bacterial collagenase and by sodium dodecyl sulfate-polyacrylamide gel electrophoresis (SDS-PAGE), or (b) triple-helical collagen by pepsin digestion followed by SDS-PAGE. The results indicate that although CHP inhibited the accumulation of secreted collagen in the culture medium and disrupted collagen triple-helix formation, it also significantly inhibited the accumulation of secreted noncollagenous proteins in the medium. CHP had no significant effect on either total protein synthesis (medium plus cell layer) or cell number. We conclude that CHP does not act as a specific inhibitor of collagen secretion in this system, and thus data from these experiments cannot be used to relate SC collagen production to other aspects of SC differentiation. We discuss the evidence for and against specificity of CHP action in other systems.     

Inhibiting effect of procollagen peptides on collagen biosynthesis in fibroblast cultures.

NH2-terminal extension peptides of type I and type III procollagens were isolated from dermatosparactic and normal fetal calfskin, respectively. Cell culture experiments showed that the globular domains of the tested procollagen peptides were biologically active but that peptides from the helical region of collagen had no effect. The peptides were added to the incubation medium of calf fibroblasts along with radioactive precursor amino acids, and the amount of newly synthesized collagen was determined. The experiments indicated that procollagen peptides exerted a feedback-like inhibitory effect specific for the synthesis of collagen. Neither degradation of collagen, hydroxylation of collagen alpha chains, nor synthesis of noncollagenous proteins were affected. Synthesis of type II collagen by calf chondrocytes was not reduced. In addition, it was shown that procollagen peptides from calf were equally effective when added to human fibroblast cultures, an observation that could be of considerable medical interest.     

Regulation of collagen production and collagen mRNA amounts in fibroblasts in response to culture conditions.

Collagen synthesis and mRNA amounts for the alpha 1 and alpha 2 polypeptide chains of Type I collagen were measured in embryonic-chick tendons and in tendon cells both in suspension and in primary cultures. The percentage of protein production represented by collagen in suspension-cultured cells was initially the same as in the intact tendon; however, on an hourly basis, there was actually a steady decline in collagen production by suspended cells. Collagen production in primary cultures of chick tendon fibroblasts was decreased when compared with intact tendon, even though ascorbate-supplemented primary cultures were able to maintain higher rates of collagen production than were non-supplemented cultures. The amounts of mRNA for alpha 1(I) and alpha 2(I) polypeptide chains of collagen responded in similar fashions to different culture conditions and were compared with the amounts of mRNA for beta-actin. In primary cultures the available alpha 1 and alpha 2 collagen mRNAs support proportionately higher collagen production than in the intact tendon. However, the ratio of alpha 1/alpha 2 mRNA and polypeptide-chain synthesis did not remain 2:1, but increased with the concomitant production of Type I trimers composed of three alpha 1 chains. Removal of fibroblasts from their environment in vivo appears to alter the amounts of mRNA for alpha 1 and alpha 2 chains and to alter the utilization of those mRNAs for polypeptide synthesis.     

Preferential usage of tRNA isoaccepting species in collagen synthesis.

A new double label technique is described for determining the usage of individual isoaccepting tRNA species by in vitro protein-synthesizing systems. Employing this method we show that of four major species of glycyl-tRNA one which is cognate to GGU and GGC is used predominantly in collagen synthesis by polysomes isolated from embryonic chick calvaria. A similar preferential usage was found for one of two alanyl-tRNA species. No preference for any particular isoaccepting tRNA species was observed in the synthesis of noncollagenous proteins by either calvaria or liver polysomes except for the disproportionate usage of one lysyl-tRNA species. Whether such preferential usage permits translational control of collagen synthesis in vivo remains to be determined.     

Biosynthesis of collagen crosslinks. II. In vivo labelling and stability of lung collagen in rats

Rat lung collagen was labelled in vivo by a single intraperitoneal injection of [3H]lysine at several key timepoints in lung development: days 11 (alveolar proliferation), 26 (start of equilibrated growth), 42 (end of equilibrated growth), and 100 (adult lung structure present). The rates of deposition of labelled hydroxylysine and the difunctional, Schiff base-derived crosslinks hydroxylysinonorleucine (HLNL) and dihydroxylysinonorleucine (DHLNL) were quantified. We also measured total lung content of the trifunctional, mature crosslink hydroxypyridinium (OHP) in these same animals. While the relative rates of accumulation of labelled collagen [3H]hydroxylysine differed by a factor of about 6 at the different times of injection of labelled precursor, quantitative and qualitative patterns of collagen crosslinking were very similar at all of the lung developmental stages studied. Furthermore, there was little or no breakdown of the lung collagen pool as defined by the presence of labelled crosslinks; changes in lung DHLNL content could be completely accounted for by its maturation to OHP, regardless of the age of the rats when injected with the radioactive precursor. We conclude that mature, crosslinked collagen in the lungs of rats, which is obligatorily an extracellular pool, is not being degraded at a measurable rate. Therefore, studies of others that have shown apparent high rates of breakdown of newly synthesized collagen in lungs of whole animals using different methods are probably not reflective of the metabolic fate of total lung collagen, and may indicate that degradation of normal lung collagen occurs predominantly or exclusively intracellularly.     

Collagen involvement in branching morphogenesis of embryonic lung and salivary gland

The possibility that extracellular collagen is involved in branching morphogenesis of mouse embryo lung and salivary glands has been explored duringin vitro organ culture. Control cultures of both rudiment types contain abundant collagen in extracellular spaces between mesenchymal cells and in the epithelial-mesenchymal interface. Branching morphogenesis of lungs and salivary glands is not perturbed by the presence of β-aminopropionitrile, implying that extracellular collagen cross-linking is not required, but is perturbed by α,α′-dipyridyl orl-azetidine-2-car?ylic acid (LACA), agents reported to interfere with collagen synthesis and secretion. Analysis of the structural and biosynthetic effects of LACA revealed a severe inhibition of collagen synthesis, as monitored by hydroxyproline synthesis, and extracellular collagen accumulation. Cell and tissue integrity was not affected, but a slight inhibition of general protein synthesis, protein accumulation, and epithelial expansion was observed. The strong correlations between collagen biosynthesis, extracellular collagen presence, and branching morphogenesis are consistent with an integral role for collagen in embryonic lung and salivary gland morphogenesis.     

Immunotargeting of glucose oxidase to endothelium in vivo causes oxidative vascular injury in the lungs

Vascular immunotargeting is a novel approach for site-selective drug delivery to endothelium. To validate the strategy, we conjugated glucose oxidase (GOX) via streptavidin with antibodies to the endothelial cell surface antigen platelet endothelial cell adhesion molecule (PECAM). Previous work documented that 1) anti-PECAM-streptavidin carrier accumulates in the lungs after intravenous injection in animals and 2) anti-PECAM-GOX binds to, enters, and kills endothelium via intracellular H(2)O(2) generation in cell culture. In the present work, we studied the targeting and effect of anti-PECAM-GOX in animals. Anti-PECAM-GOX, but not IgG-GOX, accumulated in the isolated rat lungs, produced H(2)O(2,) and caused endothelial injury manifested by a fourfold elevation of angiotensin-converting enzyme activity in the perfusate. In intact mice, anti-PECAM-GOX accumulated in the lungs (27 +/- 9 vs. 2.4 +/- 0.3% injected dose/g for IgG-GOX) and caused severe lung injury and 95% lethality within hours after intravenous injection. Endothelial disruption and blebbing, elevated lung wet-to-dry ratio, and interstitial and alveolar edema indicated that anti-PECAM-GOX damaged pulmonary endothelium. The vascular injury in the lungs was associated with positive immunostaining for iPF(2alpha)-III isoprostane, a marker for oxidative stress. In contrast, IgG-GOX caused a minor lung injury and little (5%) lethality. Anti-PECAM conjugated with inert proteins induced no death or lung injury. None of the conjugates caused major injury to other internal organs. These results indicate that an immunotargeting strategy can deliver an active enzyme to selected target cells in intact animals. Anti-PECAM-GOX provides a novel model of oxidative injury to the pulmonary endothelium in vivo.     

Similar, but not identical, modulation of expression of extracellular matrix components during in vitro and in vivo aging of human skin fibroblasts.

Regulation of the synthesis of procollagen and other extracellular matrix components was examined in human skin fibroblasts obtained from donors of various ages, from fetal to 80 years old (in vivo aged), and in fetal fibroblasts at varying passage levels (in vitro aged). Growth rates and saturation densities of fibroblasts decreased with increasing age of the donor and after passage 20 of fetal fibroblasts. The rates of collagen and proteoglycan synthesis also decreased during both types of aging to about 10-25% of the rate in early passage fetal fibroblasts, whereas the synthesis of total noncollagenous proteins was not greatly affected. Decreased collagen synthesis in both types of aging was correlated with lower steady-state levels of mRNAs for the two subunits of type I procollagen mRNA, although their regulation was not coordinate. Type III collagen mRNA levels also declined in both types of aging. The concentration of fibronectin mRNA also decreased during in vitro aging but more rapidly than the collagen mRNAs, whereas in fibroblasts from 51-80-year-old donors, it was similar to or higher than in early passage fetal fibroblasts. This study suggests that the decreased synthesis of procollagen and proteoglycans in in vivo aged fibroblasts represents changes that are responsible for intrinsic degenerative changes that occur in human skin during aging. Furthermore, although in vitro and in vivo aging were similar in many respects, they were not equivalent, as evidenced by the differences in regulation of fibronectin expression.     

Stabilization of RNA strands in protein synthesis by type I procollagen C-proteinase enhancer protein, a potential RNA-binding protein, in hepatic stellate cells.

Type I procollagen C-proteinase enhancer (PCPE) exists in hepatic stellate cells (HSCs) which can produce collagen. The deduced amino acid sequence of PCPE contains motifs specific for RNA-binding proteins. The effect of PCPE on the syntheses of collagen and noncollagenous protein was studied using an HSC clone derived from cirrhotic rat liver. When the cells were cultured in the presence of an antisense oligonucleotide (AS) against PCPE mRNA, the synthesis of noncollagenous protein as well as collagen was reduced compared to the cells cultured with addition of a nonsense oligonucleotide (NS). The extent of the reduction was similar in both syntheses. The total RNA content of the AS-treated cells and NS-treated cells did not differ. In the presence of actinomycin D, however, such total RNA content was decreased more rapidly in the AS-treated cells than in the NS-treated cells. PCPE may be involved in stabilization of RNA strands in noncollagenous protein synthesis as well as collagen synthesis.     

Assessment of tissue-level kidney functions with primary cultures

Primary cultures of renal proximal tubule have become important tools for examination of the mechanisms and control of transepithelial transport processes. The utility of the culture preparations for study of integrated tissue functions depends upon their accurate expression of in vivo transport processes. Maintenance of differentiation in culture is enhanced by contractible collagen substratum. Epithelial monolayer primary cultures of flounder and chicken proximal tubule, prepared by enzymatic and mechanical maceration with differential centrifugation, exhibit functional properties at the tissue level that generally resemble known properties of the freshly isolated or in vivo proximal tubule. Transepithelial electrical resistances and potential differences are very similar or identical to those of intact tubules. Na+-dependent glucose transport, a hallmark of proximal tubule function, has the same properties in culture as the tissue in vivo. Similarly, where appropriate comparisons are possible, amino acid, uric acid, and organic anion and cation transepithelial transport processes are qualitatively very similar in culture and in vivo. These two non-mammalian primary proximal tubule culture systems adequately reflect in vivo function, and thus provide opportunities for experimental manipulation otherwise not available.     

Modulation of collagen synthesis by tumor necrosis factor alpha in cultured vascular smooth muscle cells

Collagen synthesis in vascular smooth muscle cells (SMCs) after exposure to tumor necrosis factor alpha (TNF-alpha) was investigated using a culture system. The synthesis of collagenase-digestible proteins (CDP) and noncollagenous proteins (NCP) was evaluated by the [3H]proline incorporation. It was shown that TNF-alpha markedly suppresses the incorporation of [3H]proline into both CDP and NCP in confluent cultures of SMCs but not in sparse cultures of the cells. Such a marked suppression by TNF-alpha was not observed in confluent bovine aortic endothelial cells and human fibroblastic IMR-90 cells. In confluent SMCs, the synthesis of CDP was more strongly inhibited by TNF-alpha than that of NCP. When the CDP synthesis was stimulated by transforming growth factor beta, TNF-alpha suppressed the stimulation in both confluent and sparse SMCs. Human SMCs synthesized types I, III, IV and V collagens; TNF-alpha markedly decreased the relative proportion of types IV and V. It was therefore suggested that TNF-alpha modulates the collagen synthesis by SMCs depending on their cell density and modifies the formation of atherosclerotic lesions.     

Evidence for lactate utilization for fetal lung glycogen synthesis

Fetal rabbit lungs from 23 day gestation animals were used to investigate the potential role of lactate as a substrate for fetal lung glycogen synthesis. Fetal lactate dehydrogenase activity was approximately twice that found in the adult lung, while the activity of phosphoenolpyruvate carboxykinase was elevated fourfold over the adult value. Pyruvate carboxylase activities were similar in both fetal and adult lungs. Studies employing fetal lung explants in organ culture indicated that the presence of both glucose and lactate may be necessary for glycogen accumulation in the developing fetal lung. These data support the hypothesis that lactate is an important precursor for fetal lung glycogen.     

Fetal bovine bone cells synthesize bone-specific matrix proteins

We isolated cells from both calvaria and the outer cortices of long bones from 3- to 5-mo bovine fetuses. The cells were identified as functional osteoblasts by indirect immunofluorescence using antibodies against three bone-specific, noncollagenous matrix proteins (osteonectin, the bone proteoglycan, and the bone sialoprotein) and against type 1 collagen. In separate experiments, confluent cultures of the cells were radiolabeled and shown to synthesize and secrete osteonectin, the bone proteoglycan and the bone sialoprotein by immunoprecipitation and fluorography of SDS polyacrylamide gels. Analysis of the radiolabeled collagens synthesized by the cultures showed that they produced predominantly (approximately 94%) type I collagen, with small amounts of types III and V collagens. In agreement with previous investigators who have employed the rodent bone cell system, we confirmed in bovine bone cells that (a) there was a typical cyclic AMP response to parathyroid hormone, (b) freshly isolated cells possessed high levels of alkaline phosphatase, which diminished during culture but returned to normal levels in mineralizing cultures, and (c) cells grown in the presence of ascorbic acid and beta-glycerophosphate rapidly produced and mineralized an extracellular matrix containing largely type I collagen. These results show that antibodies directed against bone-specific, noncollagenous proteins can be used to clearly identify bone cells in vitro.     

Resistance to bleomycin-induced lung fibrosis in MMP-8 deficient mice is mediated by interleukin-10

Background

Matrix metalloproteinases (MMPs) may have pro and antifibrotic roles within the lungs, due to its ability to modulate collagen turnover and immune mediators. MMP-8 is a collagenase that also cleaves a number of cytokines and chemokines.

Methodology and Principal Findings

To evaluate its relevance in lung fibrosis, wildtype and Mmp8^−/− mice were treated with either intratracheal bleomycin or saline, and lungs were harvested at different time points. Fibrosis, collagen, collagenases, gelatinases, TGFβ and IL-10 were measured in lung tissue. Mmp8^−/− mice developed less fibrosis than their wildtype counterparts. This was related to an increase in lung inflammatory cells, MMP-9 and IL-10 levels in these mutant animals. In vitro experiments showed that MMP-8 cleaves murine and human IL-10, and tissue from knockout animals showed decreased IL-10 processing. Additionally, lung fibroblasts from these mice were cultured in the presence of bleomycin and collagen, IL-10 and STAT3 activation (downstream signal in response to IL-10) measured by western blotting. In cell cultures, bleomycin increased collagen synthesis only in wildtype mice. Fibroblasts from knockout mice did not show increased collagen synthesis, but increased levels of unprocessed IL-10 and STAT3 phosphorylation. Blockade of IL-10 reverted this phenotype, increasing collagen in cultures.

Conclusions

According to these results, we conclude that the absence of MMP-8 has an antifibrotic effect by increasing IL-10 and propose that this metalloprotease could be a relevant modulator of IL-10 metabolism in vivo.     

Effects of cis-4-hydroxy- -proline, an inhibitor of Schwann cell differentiation, on the secretion of collagenous and noncollagenous proteins by Schwann cells

The proline analog cis-4-hydroxy- -proline (CHP) was previously shown to inhibit both Schwann cell (SC) differentiation and extracellular matrix (ECM) formation in cultures of rat SCs and dorsal root ganglion neurons. We confirmed that CHP inhibits basal lamina formation by immunofluorescence with antibodies to laminin, type IV collagen, and heparan sulfate proteoglycan. In order to test the hypothesis that CHP inhibits SC differentiation by specifically inhibiting the secretion of collagen, cultures grown in the presence or absence of CHP were metabolically labeled with [³H]leucine and the media were analyzed for relative amounts of (a) collagenous and noncollagenous proteins by assay with bacterial collagenase and by sodium dodecyl sulfate-polyacrylamide gel electrophoresis (SDS-PAGE), or (b) triple-helical collagen by pepsin digestion followed by SDS-PAGE. The results indicate that although CHP inhibited the accumulation of secreted collagen in the culture medium and disrupted collagen triple-helix formation, it also significantly inhibited the accumulation of secreted noncollagenous proteins in the medium. CHP had no significant effect on either total protein synthesis (medium plus cell layer) or cell number. We conclude that CHP does not act as a specific inhibitor of collagen secretion in this system, and thus data from these experiments cannot be used to relate SC collagen production to other aspects of SC differentiation. We discuss the evidence for and against specificity of CHP action in other systems.     

Isolation and chemical characterization of collagen in bovine pulmonary tissues.

1. The contents of the fibrous proteins collagen and elastin in the pleural and parenchymal regions of bovine lungs were determined. The collagen content was approx. 70% (g/100g of salt-extracted defatted powder) in each tissue, and the elastin content was 28% in pleura and 13.5% in parenchyma. 2. Purification of the insoluble collagen from the pleura and parenchyma of bovine lungs by various methods was attempted. The collagen fractions isolated after incubation of the pulmonary tissues with the proteolytic enzymes collagenase ("collagenase-soluble" fraction) or pancreatic elastase ("elastase-insoluble" fraction) each contained approx. 87% of the total collagen initially present. 3. Both collagen fractions were chemically analysed for their amino acid and carbohydrate contents and were found to be similar to those of the intact interstitial collagens isolated from skin, bone and tendon. 4. The contents of the two aldimine cross-linking compounds, dehydrohydroxylysinonorleucine and dehydrodihydroxylysinonorleucine, were determined in the bovine pulmonary collagen fractions, and were found to decrease with increasing age of the animals, and were similar to the values found in intact collagens from bone and tendon.     

Rates of collagen synthesis in lung, skin and muscle obtained in vivo by a simplified method using [3H]proline.

Methods for measurement of rates of collagen synthesis in vivo have thus far been technically difficult and often subject to quite large errors. In this paper a simplified method is described for obtaining synthesis rates of collagen and non-collagen proteins, for tissues of rabbits. This involves an intravenous injection of [3H]proline, administered with a large dose of unlabelled proline, and measurement of the specific radioactivity of proline and hydroxyproline in body tissues up to 3 h later. The specific radioactivity of [3H]proline in plasma and the tissue free pools rises rapidly to a plateau value which is maintained for at least 2 h, when the specific radioactivity of the type I collagen precursors, isolated from the skin, was similar to that of the plasma and tissue-free pool. Furthermore, over this period, the increase in the specific radioactivity of proline in collagen and non-collagen protein was linear with respect to time. These results suggest that the large dose of proline floods the precursor pools for protein synthesis, and that this effect can be maintained for quite long periods of time. Such kinetics greatly simplified the method for obtaining collagen synthesis rates in vivo, which were calculated for lung, heart, skin and skeletal muscle, and shown to be quite rapid, ranging between about 3 and 10%/day. The lung was a particularly metabolically active tissue, with synthesis rates of about 10%/day for collagen and 35%/day for total non-collagen proteins, indicating rapid turnover of both intracellular and extracellular proteins of this tissue.     

Alteration of collagenous protein profile in congestive heart failure secondary to myocardial infarction

The rat model of myocardial infarction is characterized by progressive cardiac hypertrophy and failure. Rats with infarcts greater than 30% of the left ventricle exhibited early and moderate, stages of heart failure 4 and 8 weeks after the occlusion of the left coronary artery, respectively. As heart failure is usually associated with remodeling of the extracellular matrix, a histological and biochemical study of cardiac collagenous proteins was carried out using failing hearts. Total collagen content in the right ventricle increased at 2, 4, and 8 weeks following occlusion of the left coronary artery whereas such a change in viable left ventricle was seen after 4 and 8 weeks. Total cardiac hydroxyproline concentration was increased in both right and left ventricular samples from the infarcted animals when compared to those of control; this increase was due to elevation of pepsin-insoluble collagen fraction. The myocardial noncollagenous/collagenous protein ratio was decreased in experimental right and left ventricular samples when compared to control samples. These findings suggest that an increase in cross-linking of cardiac collagen as well as disparate synthesis of collagenous and noncollagenous proteins occurs in this model of congestive heart, failure.