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ABSTRACT |
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ABSTRACT
INTRODUCTION
METHODS
RESULTS
DISCUSSION
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Treatment of hamster lungs with porcine pancreatic elastase (PPE) causes emphysema and a decrease in lung elastin content, which returns to control level by Day 30. To explore the mechanism of
alveolar wall remodeling after elastolytic injury, we examined the expression of elastin and 
1(I) collagen mRNAs by in situ hybridization at 1, 2, 3, 5, 7, and 30 d after intratracheal PPE. The lungs of
control animals displayed weak signals for elastin and 1(I) collagen mRNA in pleura, large arteries,
veins, and airways. There was little or no signal in respiratory air space walls. Increased expression of
elastin and 1(I) collagen mRNA began by Day 1 after PPE and reached an asymptote by Day 3 that was maintained by elastin until Day 7; expression of 1(I) collagen mRNA waned earlier. Elastin and,
to a lesser extent, 1(I) collagen mRNA were heavily expressed in pleura, blood vessels, and airways. Analysis of serial sections showed elastin message was minimal in the walls of respiratory air spaces
and when present, at 3, 5, and 7 d, was primarily found at the free margins of alveolar septa. Collagen message was very sparse in respiratory air space walls. By 30 d, elastin mRNA expression was
reduced but still above control levels and emphysema was widespread and severe. Rank score of elastin mRNA expression in individual subpleural air spaces showed a positive correlation with air space
size. In conclusion, most expression of elastin and 1(I) collagen mRNA occurs in the pleura, airway,
and vascular walls. In respiratory air space walls, expression of elastin mRNAs occurs in damaged tissue at free septal margins.
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INTRODUCTION |
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TOP
ABSTRACT
INTRODUCTION
METHODS
RESULTS
DISCUSSION
REFERENCES
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Emphysema is induced in hamsters and other rodents by the intratracheal instillation of porcine pancreatic elastase (PPE), human neutrophil elastase, and other elastolytic enzymes (1). Biochemical studies of the lung after PPE treatment show a sharp decrease in total lung elastin within the first 24 h (2, 3). Lung elastin content starts to increase soon after injury and reaches normal or above normal levels by 30 to 40 d (1). Morphometric ultrastructural studies show a decrease in elastic fibers in alveolar septal tips at 1 wk after PPE treatment, the earliest time studied; there are fewer breaks in the elastic fiber continuum of alveolar entrance rings at 4 and 12 wk than at 1 wk, suggesting that repair has occurred (4). Scanning electron microscopy shows abnormal air spaces formed by progressive dilation of alveolar ducts with shortening and occasionally effacement of interalveolar septa; interalveolar fenestrae are occasionally enlarged (5). However, little is known of the precise nature of the repair process.
Light microscopy reveals that within 24 h after intratracheal PPE treatment of the hamster, alveolar wall destruction and air space enlargement are extensive (6); alveolar hemorrhage and inflammation are largely cleared by Day 21 and air space enlargement has progressed (7). The total number of alveoli is decreased to about 45% of normal, the mean linear intercept doubles, and the internal surface area is decreased to about 70% of normal (8). Ultrastructurally, at 4 to 48 h, many alveolar walls are without elastic fibers. Collagen fibrils are present in swollen connective tissue spaces. Complete digestion of elastic fibers is more certain in many areas of pleura. At 4 d, small, fibrillar, newly formed elastic fibers are seen, mainly in pleura and blood vessel walls, adjacent to fibroblasts containing large amounts of rough endoplasmic reticulum and a prominent Golgi apparatus (9).
Most previous work on the elastase model of emphysema
has focused on the factors that cause elastin degradation
an
increase in the elastase burden or a decrease in the antielastase shield of the lungs. We hypothesize that whether or
not slow-paced elastin degradation gives rise to emphysema
depends on whether or not elastin damage is balanced by elastin repair. This study explores the process of repair of elastin
and Type I collagen in vivo after elastase-induced lung injury.
We used the PPE animal model of emphysema because the
model has been extensively described biochemically, physiologically, and by light and electron microscopy (1, 4).
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METHODS |
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ABSTRACT
INTRODUCTION
METHODS
RESULTS
DISCUSSION
REFERENCES
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Preparation of 35S-labeled Riboprobes
Single-stranded sense and antisense RNA probes are transcribed from
a transcription vector containing a complementary DNA (cDNA) fragment coding for type I collagen or elastin using the Riboprobe System
(Promega, Madison, WI). The elastin probe used was a 1,600 bp fragment from the 3' terminal portion of rat tropoelastin messenger RNA
(mRNA) (12). The collagen probe used in these experiments was a
600 bp fragment from the 3' untranslated region of the rat 1(I) collagen cDNA (13). This probe specifically identifies murine 1(I) collagen transcripts (14). The probes are radiolabeled with [35S]uridine
triphosphate (Dupont NEN, Boston, MA). After incubation at 37° C
for 2 h, the DNA templates are digested with 1 unit of RQ1 ribonuclease (RNase)-free deoxyribonuclease (DNase) (Promega) at 37° C
for 15 min. The sense and antisense probes are subjected to alkaline
hydrolysis to decrease their average fragment length to 150 bases. The
probes are then extracted with phenol-chloroform and precipitated in
ethanol.
Animal Treatment
Male VAF/Plus hamster (Mesocricetus auratus, LVG) from Charles River Breeding Laboratories (Wilmington, MA) were anesthetized by CO2 inhalation and given a transoral intratracheal instillation of 0.5 ml of physiological saline or 200 µg of porcine pancreatic elastase (Elastin Products, Owenville, MO) in 0.5 ml of saline solution.
Preparation of Tissue
At 1, 2, 3, 5, 7, and 30 d after treatment animals were anesthetized with pentobarbital sodium and exsanguinated by cutting the abdominal aorta. The pulmonary vessels were perfused with freshly prepared paraformaldehyde and the lungs were inflated with fixative and excised. At the end of the day the lungs were placed in fresh fixative and stored at 4° C overnight. Slabs of tissue were cut from the lung and dehydrated and embedded in Paraplast Plus (Oxford Laboratories, St. Louis, MO) embedding medium. Four-micron serial paraffin sections were cut, individually handled and numbered, and transferred to Superfrost Plus slides (Fisher Scientific, Springfield, NJ) for in situ hybridization or staining.
In Situ Hybridization
The sections were deparaffinized in xylene, hydrated, and fixed with 4% paraformaldehyde-phosphate-buffered saline. A 5-min incubation in 20 µg/ml proteinase K at 37° C or room temperature followed and the sections were then fixed briefly again in 4% paraformaldehyde. Sections were treated with acetic anhydride (0.026 M) in a 0.1 M triethanolamine bath, dehydrated and air dried for a minimum of 2 h before hybridization. The riboprobes were heated to 80° C for 2 min prior to addition to ice cold hybridization buffer (containing 50% formamide, 0.3 M NaCl, 20 mM Tris-HCl, 5 mM disodium ethylenediaminetetraacetate, 10 mM NaH2PO4, 10% dextran sulfate, 1× Denhardt's, 0.5 mg/ml transfer RNA (tRNA), and 10 mM dithiothreitol). Aliquots of 30 µl of 35S-labeled riboprobe at a concentration of 50,000 cpm/µl in hybridization buffer were spread over each section and then covered with coverslips. Slides were placed in plastic slide boxes containing a sponge soaked with 50% formamide and 4× standard sodium citrate (SSC) solution and sealed with electrical tape to provide humid conditions, and allowed to hybridize at 52° C. After 16 h of hybridization, the sections were sequentially washed in 5× SSC containing 10 mM dithiothreitol at 50° C and then in 50% formamide, 2× SSC, and 10 mM dithiothreitol at 65° C, to reduce nonspecific binding by the probe. Next, sections were incubated in 20 µg/ml RNase A at 37° C for 1 h to digest unbound probe. A second wash in 50% formamide, 2× SSC, and 10 mM dithiothreitol was done to further reduce background activity followed by washes in 2× SSC and 0.1× SSC. Slides were then dehydrated in graded ethanol in the presence of 0.3 M NH4Ac and air dried. Slides were dipped in Kodak NTB-2 (Eastman Kodak, Rochester, NY) emulsion and exposed for 3 d at 4° C in light-tight boxes containing a desiccant. Emulsion-coated slides were developed in Kodak D19 and fixed with Kodak fixer.
Staining
Hybridized sections were either stained with Gill's hematoxylin and eosin B, or left unstained. Paraffin sections, neighboring those used for in situ hybridization, were deparaffinized and stained with Harris hematoxylin and eosin Y or with Verhoeff's elastic stain with and without the van Gieson counterstain (Sigma Chemical, St. Louis, MO).
Tissue Section Analysis
Lung tissue from 44 animals was analyzed. The animals were distributed among the treatment groups as follows: 10 animals treated with saline, and 4, 4, 8, 3, 8, and 7 animals killed at 1, 2, 3, 5, 7, and 30 d, respectively, after PPE treatment. Each microscopic slide contained 1 slab of tissue from the left lung and 1 or 2 slabs of tissue from right lung lobes. The mean linear intercept was measured by projection microscopy on 20 randomly selected fields from each animal's lung sections.
An average of 4 slides per animal were hybridized for elastin and
another 4 slides were hybridized for 1(I) collagen. Stained sections
were observed and photographed with bright-field optics on a Leitz
Orthoplan microscope (Ernst Leitz GMBH, Wetzlar, Germany). Unstained hybridized tissue was observed and photographed with darkfield and phase optics with Leitz NIP Fluotar phase objectives. Identification of the cells and tissues was aided by comparison with neighboring
serial sections that were stained for elastin and collagen. For comparison of elastin and 1(I) collagen mRNA expression, neighboring serial
sections, each hybridized with one of the probes, were used. Color
photomicrographs of serial sections were taken to aid in the analysis.
Montages of photographs of alveolar ducts between terminal bronchiole and pleura were also studied.
Elastin mRNA expression was scored on 22 individual subpleural air spaces for 3 hamsters each, of saline control, 3-d PPE-treated and 30-d PPE-treated groups. The perimeter of each air space section was calculated by measuring the major and minor axes and assuming that the air spaces were elliptical in shape. Air spaces of different sizes were picked that were representative of the sizes seen in their immediate area. The pleura and septal wall segments of the air spaces were scored separately on a ranking scale as follows:
- 0 no silver grains above background
- 1 density of silver grains at least double background over some portion of the segment of interest
- 2 density of silver grains focally at least quadruple background (focal is defined as < 20% of length of segment of interest)
- 3 density of silver grains at least quadruple background over > 20% of length of the air space wall
- 4 focal, dense cluster of grains (many silver grains overlapping)
5 dense clustering of grains over > 20% of the length of segment of interest
Statistics
The Spearman rank order correlation test was used on the air space wall elastin mRNA scoring versus air space section perimeter data. The Kruskal-Wallis and Mann-Whitney rank sum tests were used to compare grouped data.
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RESULTS |
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ABSTRACT
INTRODUCTION
METHODS
RESULTS
DISCUSSION
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The mean linear intercept values (mean ± SE) for the saline-treated control hamsters and for the hamsters studied 1, 2, 3, 5, 7, and 30 d after PPE treatment were 46 ± 5, 89 ± 4, 111 ± 45, 103 ± 15, 126 ± 16, 130 ± 22, and 135 ± 35 µm, respectively, and are shown in Figure 1.
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In saline-treated control hamsters, weak signals for elastin
mRNA were seen in the pleura and in medium and large intrapulmonary arteries and veins. Weak signals for 1(I) collagen mRNA were occasionally detected in the adventitia of
large airways, arteries, and veins. Neither message was readily
detected in respiratory air space walls.
One day after PPE treatment, destruction of lung tissue
with enlargement of respiratory air spaces was extensive. Verhoeff's elastic stain showed loss of elastic fibers in respiratory
air space walls and pleura, and in the basement membrane of
airway epithelium; the elastic lamellae of large and small
blood vessels were disrupted. Elastin mRNA expression was
minimally and focally increased in the pleura and adventitia of
airways with a more general increase in the large arteries;
1(I) collagen mRNA was focally increased in the adventitia
of airways, and large and medium sized arteries.
Elastin mRNA expression was increased on Day 2 over
Day 1 and reached an asymptote by Day 3 that was maintained until Days 5 to 7; the signal for 1(I) collagen mRNA
also reached an asymptote at 3 d but appeared to decrease after 5 d. Elastin and 1(I) collagen mRNA expression in the
pleura were especially intense in areas of pleural thickening
(Figure 2). Elastin mRNA expression occurred throughout
the walls of large arteries, especially in the media (Figure 3),
but tended to be focal in large veins. In blood vessels 1(I) collagen message was confined to the adventitia. In large airways,
elastin mRNA expression occurred on both sides of the muscularis. Elastin, and especially 1(I) collagen expression were
particularly intense in the adventitia between abutting large arteries and airways (Figure 3). Elastin and 1(I) collagen
message were often seen in the walls of medium sized blood
vessels, but only elastin message was frequent in the walls of
small vessels.
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Elastin message was sparse in respiratory air space septa
and 1(I) collagen message was almost absent. Focal collections of elastin message were confined to the free margins of
respiratory septa (Figures 4-5).
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By Day 30, elastin mRNA expression was close to control
levels, although occasionally, focal, heavy expression was seen
in the pleura and in the walls of large blood vessels and airways. Expression of 1(I) collagen mRNA had returned to
control levels except for occasional foci in large arteries. Hemorrhage and debris were largely absent from the lungs and
widespread emphysema was evident. In slides stained for elastin, elastic fiber architecture was not always restored to normal in parenchyma, in the pleura, or in the elastic lamellae of
blood vessels.
The ranking of elastin mRNA expression in subpleural air spaces is given in Figure 6. The scores for the 3-d PPE group were significantly higher than that for the 30-d PPE group which were significantly higher than that for the control hamsters. There was a weak but significant correlation (r = 0.28) between score and air space size (length of perimeter) within the controls. The correlation was moderate for the 3-d group (r = 0.67) and weaker for the 30-d group (r = 0.46). The air spaces scored on control lungs had sectional perimeters ranging from 79 to 688 µm. In 3- and 30-d PPE groups, air spaces with perimeters greater than 688 µm had significantly higher scores (p < 0.01 and p < 0.05, respectively) than the air spaces within the normal range. The scores for pleura ranked significantly higher (p < 0.001) than that for septal walls for all groups (data not given).
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DISCUSSION |
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ABSTRACT
INTRODUCTION
METHODS
RESULTS
DISCUSSION
REFERENCES
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With intratracheal PPE treatment of hamsters there was a rapid increase in air space size. The mean linear intercept (MLI) nearly doubled in the first 24 h, as previously seen in treated hamsters (6). The MLI appeared to be reaching an asymptote by Day 5, but we do not know what happens beyond 30 d.
Our finding of minimal expression of elastin mRNA in the
normal lung is consistent with other studies indicating a long
half-life for elastin (15). Localization of elastin message in
large blood vessels may relate to the stress induced by pulsatile blood flow. The elastic fiber damage and enhanced expression of elastin and 1(I) collagen mRNA in blood vessel walls
after PPE treatment of hamsters is not surprising, because vascular wall inflammation and focal thrombosis have previously
been described in the first 4 d after PPE treatment (18).
The expression of elastin mRNA in respiratory air space walls after PPE treatment may relate to the direct passage of PPE through the airway wall or, as we have previously hypothesized, PPE may have spread through the lung via the interstitium during the early hours after its administration (1). We believe the pleura is more heavily labeled than septal walls because of the greater amount of elastic tissue in pleura than in air space walls.
We hypothesized that there would be a correlation between elastin mRNA expression and air space size in PPE-treated lungs because larger air spaces would be seen in regions of greater elastolytic damage; therefore they might show greater evidence of repair. As shown in Figure 6 this was indeed the case. The strength of the association between elastin mRNA score and air space size is influenced by at least two artifacts that work in opposite directions. Peripherally cut air space sections underestimate the size of air spaces and cause a decrease in the association, with high scores for spuriously small air spaces. However, the correlation may be strengthened, in part, due to the ranking method we used to quantify the silver grains that represent elastin mRNA: the longer the segment of air space wall inspected, the more likely there is to be a cluster of grains above background. It is noteworthy that the repair process was still active at 30 d and that there is still a tendency for larger air spaces to express the most elastin mRNA.
Observation of serial lung sections showed that the local and limited repair in the respiratory air space walls after PPE treatment, occurs mainly at free margins of septa. The free septal margins of the enlarged air spaces probably consist of remnants of the original alveolar entrance ring as well as margins newly created by fenestration of alveolar walls (Figure 7). Elastolytic injury may be minimal or absent in well-preserved alveolar walls and conditions may not be favorable for elastin deposition at the newly created septal margins. During development, elastin is synthesized at septal edges as a component of the alveolarization process. The finding that elastin mRNA is localized at selected sites along the alveolar duct is reminiscent of this process. Whether in fact this localization represents a partial reinitiation of the alveolarization program is unclear.
Administration of beta-aminopropionitrile, an inhibitor of lysyl oxidase and therefore of incorporation of elastin and collagen into cross-linked fibers, results in worsening of the emphysema in elastase-treatment animals (19, 20). These results suggest that, despite its highly limited extent, repair of elastic tissue in the respiratory air spaces following elastolytic injury is of functional importance.
Expression of 1(I) collagen mRNA is greatly increased in
the lungs after intratracheal treament with PPE. However, the
kinetics and location of type I collagen mRNA expression
were different from elastin. Still, we cannot distinguish the relative contribution of either of the matrix substances to overall
repair. Increased expression was evident at 1 to 2 d for both,
but collagen expression appeared not to persist as long. Collagen mRNA was not expressed over the media of arterial
walls and was less evident than expression of elastin mRNA in
pleura, alveolar tissue, and medium and small blood vessels.
This diversity was probably due to differences in the mechanisms controlling collagen and elastin production, but may
also reflect differences in severity and loci of injured collagen
as opposed to injured elastin.
PPE does not solubilize cross-linked collagen without prior exposure to mammalian collagenase (21) and in tissue culture, PPE alone solubilize less than 5% of collagen markers (22). In the in vivo PPE model, collagen injury may be mediated by inflammatory cells rather than by the direct action of PPE. Although net collagen content of the lung is little changed by PPE treatment, studies following 14C-proline administration reveal that synthesis of collagen is increased during the first 2 wk after PPE treatment (2). Transgenic mice that overexpress collagenase in the lung develop emphysema, suggesting that the degradation of collagen itself can result in air space enlargement (23). Smoke-induced emphysema in guinea pigs is associated with morphometric evidence of collagen breakdown and repair (24) and cadmium chloride-induced air space enlargement is associated with an increase in both collagen and elastin in the lungs but no decrease in the neonatally formed elastin (25).
Histochemically collagen concentration is increased in centriacinar, distal acinar, and irregular air space enlargement; biochemically elastin is decreased in all grades of panacinar emphysema and in severe centriacinar emphysema (26). In smokers with emphysema lost respiratory tissue is associated with net increase in collagen mass (27). It is apparent that although elastin degradation is important in the pathogenesis of emphysema, collagen, and probably other components of connective tissue also play important roles.
We believe that the development of emphysema in humans is the result of a balance between two competing processes. Elastin degradation may occur as a result of elastase-antielastase imbalance. If elastin degradation is balanced by elastin repair, emphysema does not result; the failure of elastin repair to keep up with elastin degradation results in emphysema.
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Footnotes |
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Supported by the Research Service, Department of Veterans Affairs and National Institutes of Health, Grants HL 46902 and HL 56386.
Correspondence and requests for reprints should be sent to Dr. Edgar C. Lucey, Pulmonary Research #151, Boston VA Medical Center, 150 South Huntington Avenue, Boston, MA 02130.
(Received in original form May 8, 1997 and in revised form February 18, 1998).
Acknowledgments: The authors thank Hiep Q. Ngo and Antoinise Dubé for expert technical assistance.
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References |
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ABSTRACT
INTRODUCTION
METHODS
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DISCUSSION
REFERENCES
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J. A. Buczek-Thomas, E. C. Lucey, P. J. Stone, C. L. Chu, C. B. Rich, I. Carreras, R. H. Goldstein, J. A. Foster, and M. A. Nugent Elastase Mediates the Release of Growth Factors from Lung In Vivo Am. J. Respir. Cell Mol. Biol., September 1, 2004; 31(3): 344 - 350. [Abstract] [Full Text] [PDF]
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S. Ito, E. P. Ingenito, S. P. Arold, H. Parameswaran, N. T. Tgavalekos, K. R. Lutchen, and B. Suki Tissue heterogeneity in the mouse lung: effects of elastase treatment J Appl Physiol, July 1, 2004; 97(1): 204 - 212. [Abstract] [Full Text] [PDF]
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K. K. Brewer, H. Sakai, A. M. Alencar, A. Majumdar, S. P. Arold, K. R. Lutchen, E. P. Ingenito, and B. Suki Lung and alveolar wall elastic and hysteretic behavior in rats: effects of in vivo elastase treatment J Appl Physiol, November 1, 2003; 95(5): 1926 - 1936. [Abstract] [Full Text] [PDF]
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P.-P. Kuang, R. H. Goldstein, Y. Liu, D. C. Rishikof, J.-C. Jean, and M. Joyce-Brady Coordinate expression of fibulin-5/DANCE and elastin during lung injury repair Am J Physiol Lung Cell Mol Physiol, November 1, 2003; 285(5): L1147 - L1152. [Abstract] [Full Text] [PDF]
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B. Suki, K. R. Lutchen, and E. P. Ingenito On the Progressive Nature of Emphysema: Roles of Proteases, Inflammation, and Mechanical Forces Am. J. Respir. Crit. Care Med., September 1, 2003; 168(5): 516 - 521. [Full Text] [PDF]
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J. E. Shea, S. C. Miller, D. C. Poole, and J. P. Mattson Cortical bone dynamics, strength, and densitometry after induction of emphysema in hamsters J Appl Physiol, August 1, 2003; 95(2): 631 - 634. [Abstract] [Full Text] [PDF]
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C. B. Rich, I. Carreras, E. C. Lucey, J. A. Jaworski, J. A. Buczek-Thomas, M. A. Nugent, P. Stone, and J. A. Foster Transcriptional regulation of pulmonary elastin gene expression in elastase-induced injury Am J Physiol Lung Cell Mol Physiol, August 1, 2003; 285(2): L354 - L362. [Abstract] [Full Text] [PDF]
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R. F. Foronjy, Y. Okada, R. Cole, and J. D'Armiento Progressive adult-onset emphysema in transgenic mice expressing human MMP-1 in the lung Am J Physiol Lung Cell Mol Physiol, May 1, 2003; 284(5): L727 - L737. [Abstract] [Full Text] [PDF]
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S. Inoue, H. Nakamura, K. Otake, H. Saito, K. Terashita, J. Sato, H. Takeda, and H. Tomoike Impaired Pulmonary Inflammatory Responses Are a Prominent Feature of Streptococcal Pneumonia in Mice with Experimental Emphysema Am. J. Respir. Crit. Care Med., March 1, 2003; 167(5): 764 - 770. [Abstract] [Full Text] [PDF]
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S. KONONOV, K. BREWER, H. SAKAI, F. S. A. CAVALCANTE, C. R. SABAYANAGAM, E. P. INGENITO, and B. SUKI Roles of Mechanical Forces and Collagen Failure in the Development of Elastase-induced Emphysema Am. J. Respir. Crit. Care Med., November 15, 2001; 164(10): 1920 - 1926. [Abstract] [Full Text] [PDF]
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