Immune-mediated inflammation directly impairs pulmonary function, contributing to the pathogenesis of Pneumocystis carinii pneumonia.

The clinical severity of Pneumocystis carinii pneumonia (PCP) correlates closely with the appearance of pulmonary markers of inflammation. Therefore, a model system was developed whereby physiological studies could be performed on live mice to determine the extent to which pulmonary inflammation contributes to respiratory impairment during PCP. P. carinii-infected severe combined immunodeficient mice displayed little evidence of pulmonary inflammation and exhibited normal oxygenation and dynamic lung compliance. When comparably infected littermates were immunologically reconstituted, however, an intense immune-mediated inflammatory response was observed that resulted in significant decreases in both lung compliance and oxygenation. As the pneumonia resolved pulmonary function returned toward normal. To begin to define the cell populations contributing to inflammation-associated respiratory impairment during PCP, similar studies were performed in CD4(+) T cell-depleted mice. Mice depleted of both CD4(+) and CD8(+) cells developed infection, but they demonstrated neither abnormal lung compliance nor increased respiratory rate and displayed no markers of lung injury. In contrast, mice depleted of only CD4(+) T cells exhibited severe pulmonary inflammation and injury, decreased oxygenation and lung compliance, and increased respirations. Respiratory compromise was associated with the presence of activated CD8(+) cells and neutrophils in broncho-alveolar lavage fluid. These observations provide direct experimental evidence that the host's response to P. carinii directly impairs pulmonary function and contributes to the pathogenesis of PCP. Furthermore, CD8(+) T cells likely contribute to the respiratory compromise observed during PCP.

Insulin receptors and insulin effects on type II alveolar epithelial cells.

Type II alveolar epithelial cells (pneumocytes) were isolated to purity from adult rabbits and analyzed for the presence of cell surface insulin receptors and for effects of insulin on cells. Assays were performed on cells cultured for 24 h in Eagle's minimum essential medium. Insulin binding to cells in culture approached a steady-state level by 180 min at 15 degrees C and remained constant for at least 1 h. Competition experiments using native insulin, proinsulin and desoctapeptide supported specificity of binding. Scatchard analysis of binding revealed a class of high-affinity receptors with Kd = 1.5 X 10(-10) M and a low-affinity component with Kd = 4 X 10(-9) M. The number of receptors was estimated at 2000-4000/cell. Insulin added to cell cultures of type II pneumocytes in concentrations from 5 X 10(-11) to 5 X 10(-8) M resulted in a dose-related increase in uptake of 2-deoxyglucose by cells. Insulin also stimulated the incorporation of choline and glucose into phosphatidylcholine and disaturated phosphatidylcholine.

Studies on the binding of 1-anilino-8-naphthalene sulfonate to very low density and high density himan serum lipoproteins.

Very low density and high density lipoproteins have been isolated from human plasma and their interaction with 1-anilin0-8-naphthalene sulfonate has been studied under different conditions of pH and added salt. Intrinsic fluorescence of bound 1-anilino-8-naphthalene sulfonate was higher for high density lipoproteins then for very low density lipoproteins, but was unaffected by salt in both systems. Binding of 1-anilino-8-naphthalene sulfonate by both these lipoproteins was saturable and was higher in the presence of added NaCl or CaCl2, Ca2+ having a greater effect than Na+ in enhancing fluorescence. The binding data were analyzed by Scatchard plots; the number of binding sites and the affinity of 1-anilino-8-naphthalene sulfonate for the site increased with increasing salt concentration. Fluorescence pH curves were similar to those published for phospholipids. From these and previous observations it is suggested that the phospholipids probably represent the major binding sites for 1-anilino-8-naphthalene sulfonate.

Properties of freshly isolated type II alveolar epithelial cells.

The biochemical characteristics of type II alveolar epithelial cells dissociated from adult rabbit lung by instillation of low concentrations of an elastase trypsin mixture are reported. Cells studied immediately (within 4 h) after isolation were found to incorporate the radioactively labelled precursors [U-14C]glucose, [methyl-3H]choline and [3H]palmitate into cellular phosphatidylcholine at rates 2-10-fold higher than previously reported for cells not subject to short-term cell culture. Secretion of phosphatidylcholine was stimulated by beta-adrenergic agonists. Measurement of specific activities of enzymes of phospholipid biosynthesis in subcellular fractions of isolated lung cells showed a significant enrichment of acyl coenzyme A-lysophosphatidylcholine acyltransferase, an enzyme believed to be involved in pulmonary surfactant phosphatidylcholine remodeling, in the endoplasmic reticulum of type II cells. These observations support the utility of freshly isolated type II cells as a model system for the study of the functions of the alveolar epithelium.

De novo fatty acid synthesis in developing rat lung.

The rate of de novo fatty acid synthesis in developing rat lung was measured by the rate of incorporation of 3H from 3H2O into fatty acids in lung slices and by the activity of acetyl-CoA carboxylase in fetal, neonatal and adult lung. Both tritium incorporation and acetyl-CoA carboxylase activity increased sharply during late gestation, peaked on the last fetal day, and declined by 50% 1 day after birth. In the adult, values were only one-half the peak fetal rates. In vitro regulation of acetyl-CoA carboxylase activity in fetal lung was similar to that described in adult non-pulmonary tissues: activation by citrate and inhibition by palmitoyl-CoA. Similarly, incubation conditions that favored enzyme phosphorylation inhibited acetyl-CoA carboxylase activity in lung while dephosphorylating conditions stimulated activity. Incorporation of [U-14 C]glucose into lung lipids during development was influenced heavily by incorporation into fatty acids, which generally paralleled the rate of tritium incorporation into fatty acids. The relative utilization of acetyl units from exogenous glucose for overall fatty acid synthesis was greater in adult lung than in fetal or neonatal lung, suggesting that other substrates may be important for fatty acid synthesis in developing lung. In fetal lung explants, de novo fatty acid synthesis was inhibited by exogenous palmitate. Taken together, these data suggest that de novo synthesis may be an important source of saturated fatty acids in fetal lung but of lesser importance in the neonatal period. Furthermore, the regulation of acetyl-CoA carboxylase activity and fatty acid synthesis in lung may be similar to non-pulmonary tissues.

De novo fatty acid synthesis by freshly isolated alveolar type II epithelial cells.

Fatty acid synthesis was studied in freshly isolated type II pneumocytes from rabbits by 3H2O and (U-14C)-labeled glucose, lactate and pyruvate incorporation and the activity of acetyl-CoA carboxylase. The rate of lactate incorporation into fatty acids was 3-fold greater than glucose incorporation; lactate incorporation into the glycerol portion of lipids was very low but glucose incorporation into this fraction was approximately equal to incorporation into fatty acids. The highest rate of de novo fatty acid synthesis (3H2O incorporation) required both glucose and lactate. Under these circumstances lactate provided 81.5% of the acetyl units while glucose provided 5.6%. Incubations with glucose plus pyruvate had a significantly lower rate of fatty acid synthesis than glucose plus lactate. The availability of exogenous palmitate decreased de novo fatty acid synthesis by 80% in the isolated cells. In a cell-free supernatant, acetyl-CoA carboxylase activity was almost completely inhibited by palmitoyl-CoA; citrate blunted this inhibition. These data indicate that the type II pneumocyte is capable of a high rate of de novo fatty acid synthesis and that lactate is a preferred source of acetyl units. The type II pneumocyte can rapidly decrease the rate of fatty acid synthesis, probably by allosteric inhibition of acetyl-CoA carboxylase, if exogenous fatty acids are available.

Characterization of the plasma and mitochondrial membrane potentials of alveolar type II cells by the use of ionic probes.

The lipophilic cation triphenylmethylphosphonium (TPMP+) and the potassium analog Rb+, were used to monitor the membrane potential (delta psi) of freshly isolated rabbit type II alveolar epithelial cells. Type II cells were found to accumulate TPMP+ rapidly at 37 degrees C in Hanks' balanced-salt solution with 5 microM tetraphenyl boron, but this accumulation was partially due to non-membrane potential dependent binding of TPMP+ to the cell. Lysophosphatidylcholine (lysoPC) was found to abolish delta psi and permitted correction for bound TPMP+ or Rb+. TPMP+ remaining in the cell following correction for binding represents the sum of mitochondrial and plasma membrane potential dependent accumulation. The accumulation of Rb+ by the type II cell was found to be independent of the mitochondrial membrane potential and indicated a trans-plasma membrane Rb+ distribution potential of -62.9 +/- 4 mV. A similar value was obtained by estimating the plasma membrane potential dependent accumulation of TPMP+ in type II cells whose mitochondria were depolarized with carbonylcyanide m-chlorophenylhydrazone (CCCP). The release of TPMP+ due to CCCP treatment also permitted an estimation for the trans-mitochondrial membrane potential of -141.8 +/- 10 mV. These techniques of membrane potential measurements were found to be sensitive to changes in delta psi induced by a number of inhibitors and ionophores. The ability to measure the membrane potential of the type II pneumocyte, and the changes caused by various agents, should be useful in characterizing the functional responses of this pulmonary surfactant producing cell.

Arterial influx, efflux and tissue content of albumin in rabbits in vivo.

The uptake, in vivo, of 125I-labelled rabbit serum albumin by the thoracic intima-media of rabbits was determined at different times after single injection of the tracer. Plasma decay of radioactivity was monitored until sacrifice. Kinetic analysis of the plasma decay by a three compartment model gave the values of the fractional rates of catabolism and of transfers between intra- and two extravascular compartments. The uptake data were analysed by a similar compartmental model involving transfers between plasma and arterial tissue. kin, the fractional rate of influx into the tissue and kout, the fractional rate of efflux from the tissue were calculated by a procedure proposed earlier. The values of kin and kout (0.055 microliter X cm-2 X h-1 and 0.2 h-1), converted to proper units, are closer to the fractional rates for the slowly exchanging pool, probably representing tissues with non-fenestrated endothelium. On the basis of the model and a normal plasma level of albumin, it can be calculated that the steady state albumin content of intima-media should be about 11 micrograms X cm-2. Direct determination of arterial albumin content by electroimmunoassay gave a value consistent with this.

Early alterations in extracellular matrix and transforming growth factor beta gene expression in mouse lung indicative of late radiation fibrosis.

PURPOSE: Fibrosis, characterized by the accumulation of collagen, is a late result of thoracic irradiation. The expression of late radiation injury can be found immediately after irradiation by measuring messenger RNA (mRNA) abundance. METHODS AND MATERIALS: To determine if extracellular matrix mRNA and transforming growth factor beta abundance was affected acutely after irradiation, we measured mRNA levels of collagen I (CI), collagen III (CIII), collagen IV (CIV), fibronectin (FN), and transforming growth factor beta (TGF beta 1,2&3) in mouse lungs on day 1 and day 14 after graded doses of radiation. C57BL/6 female mice were irradiated with a single dose to the thorax of 5 or 12.5 Gy. Total lung RNA was prepared and immobilized by Northern and slot blotting and hybridized with radiolabelled cDNA probes for CI, CIII, CIV, FN, TGF beta 1,2&3 and a control probe encoding for glyceraldehyde-3-phosphate dehydrogenase (GAPDH). Autoradiographic data were quantified by video densitometry and results normalized to GAPDH. RESULTS: Changes in the expression of CI, CIII, CIV, FN and TGF beta 1,2&3 were observed as early as 1 day after exposure. Through 14 days, changes in mRNA up to 5-fold were seen for any one dose. Dose related changes as high as 10-fold were also evident. The CI:CIII ratio increased gradually for the 5 Gy dose at 14 days postirradiation while the CI:CII ratio for the 12.5 Gy dose decreased by approximately 4-fold as compared to the control. CONCLUSION: These studies suggest that alterations in expression of extracellular matrix and TGF beta mRNA occur very early after radiation injury even at low doses and may play a role in the development of chronic fibrosis.

A perpetual cascade of cytokines postirradiation leads to pulmonary fibrosis.

PURPOSE: Radiation-induced pulmonary reactions have classically been viewed as distinct phases--acute pneumonitis and, later, fibrosis--occurring at different times after irradiation and attributed to different target cell populations. We prefer to view these events as a continuum, with no clear distinction between the temporal sequence of the different pulmonary reactions; the progression is the result of an early activation of an inflammatory reaction, leading to the expression and maintenance of a cytokine cascade. In the current study, we have examined the temporal and spatial expression of cytokine and extracellular matrix messenger ribonucleic acid (mRNA) abundance in fibrosis-sensitive mice after thoracic irradiation. METHODS AND MATERIALS: Radiation fibrosis-prone (C57BL/6) mice received thoracic irradiation of 5 and 12.5 Gy. At Day 1, and 1, 2, 8, 16, and 24 weeks after treatment, animals were killed and lung tissue processed for light microscopy and isolation of RNA. Expression of cytokine and extracellular matrix mRNA abundance was evaluated by slot-blot analysis and cellular localization by in situ hybridization and immunochemistry. RESULTS: One of the cytokines responsible for the inflammatory phase (IL-1 alpha) is elevated at 2 weeks, returns to normal baseline values, then increases at 8 weeks, remaining elevated until 26 weeks when lung fibrosis appears. Transforming growth factor-beta (TGF beta), a proliferative cytokine, is elevated at 2 weeks, persists until 8 weeks, and then returns to baseline values. In parallel with the cytokine cascade, the fibrogenic markers for CI/CIII/IV (collagen genes) correlate by showing a similar early and then later elevation of activity. For instance, the collagen gene expression of CI/CIII is a biphasic response with an initial increase at 1-2 weeks that remits at 8 weeks, remains inactive from 8 to 16 weeks, and then becomes elevated at 6 months when collagen deposition is recognized histopathologically. CONCLUSION: These studies clearly demonstrate the early and persistent elevation of cytokine production following pulmonary irradiation. The temporal relationship between the elevation of specific cytokines and the histological and biochemical evidence of fibrosis serves to illustrate the continuum of response, which, we believe, underlies pulmonary radiation reactions and supports the concept of a perpetual cascade of cytokines produced immediately after irradiation, prompting collagen genes to turn on, and persisting until the expression of late effects becomes apparent pathologically and clinically.

Radiation-induced changes in bone perfusion and angiogenesis.

PURPOSE: To determine whether blood flow of bone is altered by limb irradiation and whether bFGF, an angiogenic cytokine, might alleviate any flow or growth abnormality resulting from 30 Gy single fraction irradiation. METHODS AND MATERIALS: C3H mice received whole right hind limb radiation at doses of 0 to 30 Gy. Additional groups received 30 Gy, and then beginning 1 or 5 weeks later received intravenous bFGF at a dose of 6 microg/mouse, twice a week for 4 weeks. Serial X-ray films were taken to measure the tibias. At 33 weeks, laser Doppler flow (LDF) measurements were made of both limbs. Cytokine measurements were made using ELISA and RNase protection. RESULTS: Bone growth was reduced following radiation in a dose dependent manner. bFGF improved bone growth after radiation even when begun 5 weeks after radiation, however, we detected no significant improvement in LDF of the irradiated bone or periosteum. Muscle tissue surrounding bone of the irradiated leg showed no increase in isoforms of TGFbeta, TNF, or IFN. There was also no difference in the circulating plasma TGFbeta1 in irradiated mice. In contrast, LDF increased significantly as a function of radiation dose in the nonirradiated tibia. Systemic delivery of bFGF appears to further enhance the increase in flow seen in the nonirradiated limb. CONCLUSION: Radiation induces a chronic antiangiogenic effect contributing to reduced limb growth. At 33 weeks the antiangiogenesis was not associated with local soft tissue elevations of TNF, IFN, or TGFbeta. Radiation toxicity to bone is alleviated by bFGF therapy suggesting that powerful locally-acting antiangiogenic mechanisms are involved. We postulate that the increased LDF of the contralateral tibia is due to circulating angiogenesis factors that are elevated to compensate for the radiation-induced antiangiogenesis.

Surfactant release as an early measure of radiation pneumonitis.

The immediate release of surfactant into lung alveoli following irradiation has been studied as a potential indicator for the later development of radiation pneumonitis. Utilizing single dose radiation exposure to the whole thorax in male LAF1/J mice, steep dose response curves for lavaged alveolar surfactant were identified at 7 and 28 days after exposure. Seven days after irradiation there was no elevation with doses up to and including 12 Gy; above this dose a detectable increase occurred. At 28 days the surfactant recovered by lavage was elevated compared to the levels seen at day 7 for all doses; doses greater than 12 Gy produced surfactant values significantly greater than those found in mice treated with 12 Gy or less. The radiation pulmonary lethality dose response curve assessed four months later indicated an LD50 value of approximately 13 Gy. The early biochemical effect and the later radiation pneumonitis lethalities therefore closely coincided. The evidence strongly indicates that alveolar surfactant release uncovered hours to days after radiation exposure may be an early biochemical marker that predicts for subsequent pneumonitis radiation injury.

Sequential effects of irradiation on the pulmonary surfactant system.

This study examines the effect of irradiation on lung surfactant synthesis and secretion in mice. Animals were irradiated with 650, 1300, or 1950 rad and morphological and biochemical indices of surfactant system function were followed for 18 weeks. No changes were seen at 650 rad; the results at 1300 and 1950 rad were virtually identical. Increased amounts of alveolar surfactant phospholipid were measureable by 24-hours. This persisted for four weeks and returned to normal by 18 weeks. Tissue surfactant phospholipid was initially reduced, returned to normal by four weeks and was increased at 18 weeks. At 18 weeks there was increased incorporation of surfactant precursor and increased production of alveolar surfactant. These biochemical changes were reflected in morphologic alterations showing release of lamellar body contents into alveoli in the first week and an increase in lamellar bodies in type II pneumocytes by 18 weeks. Elevated tissue protein levels and morphologic evidence of increased collagen formation were also found at 18 weeks. These findings indicate effects of irradiation on the pulmonary surfactant system and have important implications for the pathogenesis and potential therapy of radiation pneumonitis.

Radiation induced secretion of surfactant from cell cultures of type II pneumocytes: an in vitro model of radiation toxicity.

The pathogenesis of pneumonitis and fibrosis secondary to lung irradiation is incompletely understood. The role of the type II alveolar epithelial pneumocyte in these processes has been under investigation. The type II pneumocyte has been shown in vivo to respond to radiation induced injury with release of pulmonary surfactant. The effect of irradiation on cell cultures of type II pneumocytes was studied to determine if this could be reproduced in vitro. Type II pneumocytes were found to release surfactant material with a threshold of radiation dose between 1000 and 1500 rad. This is similar to the dosage range over which the same effect has been demonstrated in vivo. Experimental results support the concept that the release of surfactant is not due to either cell disruption or non-specific release of phospholipid from cell membranes. Irradiation appears to trigger membrane receptor mediated surfactant release. In addition, irradiation abolishes the ability of cells to subsequently respond to a physiologic agonist, suggesting radiation induced damage to the secretory mechanism. These studies establish that surfactant release in response to irradiation in vivo is a direct effect on type II pneumocytes. Cell cultures of type II pneumocytes can serve as a laboratory model of lung cell radiation toxicity.

Predictive biochemical assays for late radiation effects.

Surfactant precursors or other products of Type II pneumocytes have the potential to be the first biochemical marker for late radiation effects. This is particularly clinically important in the combined modality era because of the frequent occurrence of pneumonitis and pulmonary fibrosis secondary to radiation or chemotherapy. Accordingly, correlative studies have been pursued with the Type II pneumocyte as a beginning point to understand the complex pathophysiology of radiation pneumonitis and fibrosis. From our ultrastructural and biochemical studies, it is evident that Type II pneumocytes are an early target of radiation and the release of surfactant into the alveolus shortly after exposure persists for days and weeks. Through the use of lavaging techniques, alveolar surfactant has been elevated after pulmonary irradiation. In three murine strains and in the rabbit, there is a strong correlation with surfactant release at 7 and/or 28 days in vivo with later lethality in months. In vitro studies using cultures of type II pneumocytes also demonstrate dose response and tolerance factors that are comparable to the in vivo small and large animal diagnostic models. New markers are being developed to serve as a predictive index for later lethal pneumonopathies. With the development of these techniques, the search for early biochemical markers in man have been undertaken. Through the use of biochemical, histological, and ultrastructural techniques, a causal relationship between radiation effects on type II pneumocytes, pulmonary cells, endothelial cells of blood vessels, and their roles in the production of pneumonitis and fibrosis will evolve.

Serum markers for prediction of pulmonary radiation syndromes. Part I: Surfactant apoprotein.

Detection of a biochemical marker indicating radiation lung injury prior to the onset of clinical pathologic events could prove valuable in patient management. An increased level of alveolar surfactant is one of the earliest detectable changes following lung irradiation, starting within hours of irradiation and persisting a maximum of 2-6 weeks. However, because broncho-alveolar lavage is impracticable and endothelial cell damage due to radiation results in changes in permeability of vessel wall with leakage of alveolar proteins into serum, identification of serum markers was sought. A series of experiments in rabbits are described that clearly demonstrate serum surfactant apoprotein is an accurate marker and predictor for later lethal radiation pneumonitis. At 3-7 days after graded single doses to lung, surfactant was found in the serum paralleling the dose response for lethality. Control studies with a physiologic agent such as terbutaline release alveolar surfactant, but no serum surfactant was detected. Monitoring serum surfactant could direct preventive intervention prior to clinicopathologic manifestation of pulmonary radiation syndromes.

Pulmonary changes induced by combined mouse beta-interferon (rMuIFN-beta) and irradiation in normal mice--toxic versus protective effects.

This study in normal mice was undertaken to investigate possible enhancement of pulmonary toxicity by interferon-beta (IFN-beta) combined with single doses of irradiation. A pharmacokinetic study preceded the toxicity study to determine the optimal route and timing of IFN administration. Graded single doses of radiation were combined with graded doses of IFN. Pulmonary toxicity was determined using endpoints of alveolar surfactant and procollagen in lung lavage fluid at 7 days, breathing frequency, lethality and histology. Increased lethality was seen when IFN was combined with irradiation at 12.5 Gy vs. irradiation alone. This occurred between 20 and 30 weeks post treatment with no increased breathing frequency or surfactant release, suggesting independent mechanisms of injury. Increased breathing frequency after 40 weeks, usually associated with fibrosis, was less pronounced for IFN treated vs. irradiation only controls. Ultrastructural studies at 72 weeks suggest reduced fibrosis in lungs of IFN treated vs. irradiation only controls. Supporting this was the finding that Procollagen III, a biosynthetic precursor of collagen, was increased in the lavage fluid at 7 days for all radiation doses but decreased with the addition of IFN at 12.5 and 15 Gy. Interferons can act either as sensitizers or radioprotectors, depending on the biological system and type of interferon. Our study suggests that while IFN-beta may increase the acute effects of radiation in the mouse lung, some protection from radiation-induced fibrosis, possibly related to alteration of immune mechanisms, may exist.

Particulate-cell interactions and pulmonary cytokine expression.

The type II cell plays an important role in the response of the alveolar epithelium after lung injury through its synthesis and secretion of pulmonary surfactant, and by acting as the stem cell for the replacement of damaged type I epithelial cells. The nonciliated bronchiolar epithelial (Clara) cell is thought to play a similar role during repair of the bronchiolar epithelium. Recent evidence has suggested that epithelial cells may participate in aspects of the inflammatory response and regulation of fibroblast growth during pulmonary fibrosis through the production of and response to specific growth factors and cytokines. The cellular and molecular responses of epithelial cells and how they lead to the progression of events that defines the pulmonary parenchymal response to a class of particles is unclear. We used particles differing in size, chemical composition, and fibrogenicity in vivo and in vitro to elucidate early changes in proinflammatory and profibrotic cytokine and antioxidant gene expression in lung cells. Early increases in mRNA and protein for the proinflammatory cytokines interleukin (IL)-1 beta, IL-6, and tumor necrosis factor alpha have been observed in epithelial cells following exposure. These are accompanied by changes in specific epithelial genes including surfactant protein C and Clara cell secretory protein. The data indicate that effects on the epithelium are due to direct interactions with particles, not a result of macrophage-derived mediators, and suggest a more significant role in the overall pulmonary response than previously suspected. These results suggest that type II cell growth factor production may be significant in the pathogenesis of pulmonary fibrosis.

Differences in correlation of mRNA gene expression in mice sensitive and resistant to radiation-induced pulmonary fibrosis.

Fibrosis, characterized by the accumulation of collagen, is a late result of thoracic irradiation. The purpose of this study was to determine if extracellular matrix protein and transforming growth factor beta mRNA expression are altered late in the course of pulmonary fibrosis after irradiation, and then to determine if these changes differ between two strains of mice which vary in their sensitivity to radiation. Radiation-sensitive (C57BL/6) and radiation-resistant (C3H/HeJ) mice were irradiated with a single dose of 5 or 12.5 Gy to the thorax. Total lung RNA was prepared and immobilized by Northern and slot blotting and hybridized with radiolabeled cDNA probes for collagens I, III and IV, fibronectin, and transforming growth factor beta 1 and beta 3. Autoradiographic data were quantified by video densitometry and results normalized to a control probe encoding for glyceraldehyde-3-phosphate dehydrogenase. Alterations in mRNA abundance were observed in the sensitive mice at all times, while levels in the resistant mice were unaffected until 26 weeks after irradiation. The relationship between extracellular matrix protein per se and increased mRNA abundance suggests that late matrix protein accumulation may be a function of gene expression. Differences in levels of transforming growth factor beta mRNA may lead to strain-dependent variation in fibrotic response and may also contribute to the radiation-induced component of pulmonary fibrosis.

Early and persistent alterations in the expression of interleukin-1 alpha, interleukin-1 beta and tumor necrosis factor alpha mRNA levels in fibrosis-resistant and sensitive mice after thoracic irradiation.

Fibrosis, characterized by the accumulation of collagen, is a consequence of a chronic inflammatory response. The purpose of this study was to determine if tumor necrosis factor alpha (TNF-alpha), interleukin-1 alpha (IL-1 alpha) and IL-1 beta mRNA expression are altered acutely after irradiation, during the so-called "latent" phase of pulmonary injury, and to examine if these alterations persist through the development of pneumonitis and fibrosis. Further, we wished to determine if these changes differ between two strains of mice which vary in their sensitivity to radiation. Fibrosis-sensitive (C57BL/6) and fibrosis-resistant (C3H/HeJ) mice were irradiated with a single dose of 5 or 12.5 Gy to the thorax. Total lung RNA was prepared and immobilized by slot blotting and hybridized with radiolabeled cDNA probes encoding for TNF-alpha, IL-1 alpha and IL-1 beta. Autoradiographic data were quantified by video densitometry and results normalized to a control probe encoding for glyceraldehyde-3-phosphate dehydrogenase. It was found that TNF-alpha mRNA levels were increased in C57BL/6 mice at days 1 and 7 postirradiation after 5 Gy and day 14 postirradiation after both 5 and 12.5 Gy, and IL-1 alpha mRNA levels were increased in C57BL/6 mice at days 56, 112 and 182 postirradiation after both 5 and 12.5 Gy, and IL-1 beta mRNA levels in the C3H/HeJ mice were increased at days 56 and 182 postirradiation after 12.5 Gy. In summary, these studies demonstrated early and persistent alterations in TNF-alpha, IL-1 alpha and IL-1 beta mRNA levels even at the lower dose (5 Gy). The temporal relationship between the elevation of these cytokines and the strain-dependent variation in fibrosis response suggests that IL-1 alpha and TNF-alpha contribute to the radiation-induced component of pulmonary fibrosis, whereas IL-1 beta may have a protective function.