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Previous Article | Next Article 
Infection and Immunity, September 1998, p. 4431-4439, Vol. 66, No. 9
0019-9567/98/$04.00+0
Copyright © 1998, American Society for Microbiology. All rights reserved.
Induction of Fibrinogen Expression in the Lung
Epithelium during Pneumocystis carinii Pneumonia
Patricia J.
Simpson-Haidaris,1,2,3,*
Mary-Anne
Courtney,1,2
Terry W.
Wright,4
Rachel
Goss,1
Allen
Harmsen,5 and
Francis
Gigliotti4
Departments of Medicine-Vascular Medicine
Unit,1
Microbiology and
Immunology,2
Pathology and
Laboratory Medicine,3 and
Pediatrics,4 University of Rochester
School of Medicine and Dentistry, Rochester, and
Trudeau
Institute, Saranac Lake,5 New York
Received 27 January 1998/Returned for modification 10 March
1998/Accepted 30 June 1998
 |
ABSTRACT |
Pneumocystis carinii is an important pulmonary pathogen
responsible for morbidity and mortality in patients with AIDS. The acute-phase response (APR), the primary mechanism used by the body to
restore homeostasis following infection, is characterized by increased
levels of circulating fibrinogen (FBG). Although the liver is the
primary site of increased FBG synthesis during the APR, we unexpectedly
discovered that FBG is synthesized and secreted by lung
alveolar epithelial cells in vitro during an inflammatory stimulus.
Therefore, we sought to determine whether lung epithelial cells produce
FBG in vivo using animal models of P. carinii
pneumonia (PCP). Inflammation was noted by an influx of macrophages
to P. carinii-infected alveoli. Northern
hybridization revealed that 
-FBG mRNA increased two- to fivefold
in P. carinii-infected lung tissue, while RNA in situ
hybridization demonstrated increased levels of -FBG mRNA in the lung
epithelium. Immunoelectron microscopy detected lung epithelial
cell-specific production of FBG, suggesting induction of a localized
inflammatory response resembling the APR. A systemic APR was
confirmed by a two- to fivefold upregulation of the levels of hepatic
-FBG mRNA in animals with PCP, resulting in a corresponding increase
in levels of FBG in plasma. Furthermore, immunoelectron microscopy
revealed the presence of FBG at the junction of cell membranes
of trophic forms of P. carinii organisms aggregated along
the alveolar epithelium. These results implicate FBG in the
pathogenesis of PCP in a manner similar to that of the adhesive
glycoproteins fibronectin and vitronectin, which are known to
participate in intra-alveolar aggregation of organisms and adherence of
P. carinii to the lung epithelium.
| |
INTRODUCTION |
Pneumocystis carinii
pneumonia (PCP) has been demonstrated in a variety of
immunosuppressed animal models with manifestations similar to those
observed in afflicted humans (22, 27, 39, 49). Attachment of
the organisms to alveolar type I epithelium is an essential step in
establishing P. carinii infection (27, 30, 31, 41,
42). Ultrastructural studies indicate that P. carinii trophic forms attach to the surface of type I alveolar epithelial cells early in infection with limited interaction of organisms with type II cells as PCP progresses (27, 31, 32). The consequences of P. carinii attachment to the
alveolar epithelium are only beginning to be understood. In the early
stages of P. carinii infection, mononuclear cell
infiltration represents the most prominent feature of the host
inflammatory response, while little polymorphonuclear leukocyte or
lymphocyte infiltration is observed (27, 29).
Osmiophilic material, suggestive of changes in surfactant
homeostasis, is observed in areas of marked necrosis (31)
and during late stages of infection (32). Levels of
surfactant protein-D (SP-D) increase in the lower respiratory tract during PCP (37), and increased amounts of
SP-A are recovered in bronchoalveolar lavage fluids (40).
Analyses of bronchoalveolar lavage fluids from patients with PCP, both
with and without AIDS, revealed an accumulation of extracellular
phospholipid surfactant-like material suggestive of an associated
proteinosis, which was not observed in immunocompromised patients
without PCP (52).
P. carinii infection is complicated by pulmonary fibrin
deposition and the development of interstitial fibrosis
(54). In a study of lung biopsies from patients having PCP,
marked interstitial fibrosis was observed which was characterized by
the absence of intra-alveolar exudate and the atypical clustering of
cysts within the connective tissue rather than in the alveolar spaces
(54). Focal hyaline membranes, indicative of fibrin
deposition are found in PCP (54). Presently it is believed
that alveolar fibrin results from leakage of plasma fibrinogen (FBG)
followed by its conversion to fibrin in the final stages of
coagulation. Fibrin deposition influences inflammatory cell traffic and
fibroblast proliferation (24). Furthermore, FBG, fibrin, and
fibrin degradation products (FDPs), resulting from plasmin-mediated
fibrinolysis, interfere with or inactivate surfactant function
(24, 34, 45). Fibrosis in patients with PCP is characterized
by fibrous thickening and fibroblastic proliferation within the
alveolar septum (54). Patients with fibrosis on the initial
biopsy tend to have abnormal pulmonary function tests after recovery
from PCP. Thus, P. carinii infection clearly
results in a disruption of pulmonary function and homeostasis.
FBG is the major blood clotting factor involved in the maintenance of
hemostasis. During a systemic inflammatory response, FBG synthesis by
hepatocytes is upregulated 2- to 10-fold such that levels of FBG in
plasma increase from an average of 3 mg/ml to 6 to 30 mg/ml (10,
53). Increased levels of FBG in plasma and subsequent fibrin
formation serve to restore homeostasis by providing a provisional
matrix to support the cell interactions of wound healing
(7). This upregulation of FBG gene expression during
inflammation is one of a myriad of responses associated with the
disruption of homeostasis due to infection, tissue injury, or
neoplasia, collectively termed the acute-phase response or reaction
(APR) (10, 53). Recently, we showed that FBG is synthesized and secreted by lung alveolar epithelial cells in vitro
(46). Importantly, FBG synthesis by pneumocytes occurs in
response to interleukin-6 (IL-6) and dexamethasone (DEX). Our more
recent observations indicate that FBG, not fibrin, produced in vitro by
lung epithelial cells in response to IL-6-DEX treatment, is secreted
basolaterally (14) and becomes incorporated into the extracellular matrix (15). Thus, it is likely that locally
synthesized FBG functions in the maintenance or restoration of the
epithelial barrier during lung injury. We propose that increased
synthesis and secretion of lung epithelial cell-derived FBG is one of
the physiological events occurring during PCP. In this report, we demonstrate that expression of the -FBG gene is elevated in lung epithelial cells during PCP. Because subsequent fibrin deposition can occur during lung injury, these studies suggest that lung cell-type
specific expression of FBG contributes to the balance between
appropriate wound healing and the development of tissue fibrosis and
scarring.
| |
MATERIALS AND METHODS |
Animal models and sample preparation.
Ferrets were obtained
from Marshall Farms (Northrose, N.Y.). PCP was induced in ferrets fed a
normal diet by adding DEX (2 mg/liter) and tetracycline (500 mg/liter)
to the drinking water (49). Immunosuppression caused by the
steroid rendered the animals susceptible to natural infection by
P. carinii. Control animals were treated with DEX and
tetracycline or tetracycline only, as stated above, plus Bactrim (20 ml/liter) in the drinking water to prevent P. carinii
infection. C.B-17 scid/scid mice, 8 to 10 weeks old, were
obtained from the Trudeau Animal Breeding Facility (22).
These SCID mice spontaneously develop detectable P. carinii infection at about 4 weeks of age. All forms of
P. carinii were visualized by light microscopy after
various staining procedures; the cyst form of P. carinii was visualized in lung sections after Gomori's
methenamine silver (GMS) staining (19). To assess
P. carinii-infected lungs for fungal contamination and
to confirm the presence of P. carinii cysts and
trophozoites, cytospin preparations of P. carinii-infected lung homogenates deposited by cytocentrifugation onto slides were stained with modified Diff-Quik (Difco, Detroit, Mich.) (22).
Lungs and livers were harvested after sacrificing the animals with an
intraperitoneal injection of a lethal dose of Beuthanasia-D (390-mg/ml
pentobarbital-50-mg/ml phenytoin; 1 ml per animal). At times, ferrets
were exsanguinated by intracardiac puncture after the animals reached a
plane of anesthesia but before death as determined by toe pinch reflex.
Blood was anticoagulated with heparin for preparation of plasma. To
retain airway macrophages (3), infected or control tissues
used for histology and in situ hybridizations were sliced into 2- to
3-mm sections, fixed by immersion in formalin, and then embedded in
paraffin blocks.
RNA isolation and Northern analysis.
Molecular biology
reagents were obtained from Life Technologies (Gaithersburg, Md.),
chemical reagents were obtained from Sigma (St. Louis, Mo.),
radionucleotides were purchased from DuPont New England Nuclear
(Boston, Mass.), and the Zetaprobe nylon membrane was from Bio-Rad
(Centreville, N.Y.). Total RNA and poly(A)+ mRNA were
isolated as previously described (20), and Northern blot
hybridization was carried out with 32P-labeled ferret
lung-specific -FBG cDNA, pFLG3 (47), or the rat
liver-specific -FBG cDNA, pRBP18 (17).
In situ RNA:RNA hybridization.
In situ hybridization was
performed essentially as previously described (9, 16, 17, 19, 47,
51). The pFLG3 cDNA was cloned from ferret lung mRNA as
previously described (47); the sequence is deposited with
GenBank under accession no. U28494. The sense and antisense pFLG3,
-actin, and P. carinii surface glycoprotein A (gpA)
riboprobes were labeled to a specific activity of 2.93 × 107 cpm/µg by using [3H]CTP and
[3H]UTP. The riboprobe specific activity was
calculated from the specific activity of the input ribonucleotides as
previously described (1). Thus, probes generated from the
same batches of radionucleotides will have the same specific activity,
while the total mass synthesized is dependent on the efficiency of in
vitro transcription, which varies from probe to probe. The antisense
orientation of the riboprobe detects the positive expression of the
mRNA, whereas the sense orientation of the riboprobe is used to detect
background levels of silver grains in the absence of specific mRNA
expression. The slides probed in situ were exposed to NTB-2 emulsion
(Kodak, Rochester, N.Y.) for 8 weeks at 4°C. After photographic
development, slides were counterstained with Mayer's hematoxylin and
eosin (H&E) to visualize tissue and cell morphology by brightfield
microscopy; silver grains were visualized under darkfield microscopy.
Some slides upon which the in situ hybridization procedure was carried out were counterstained with GMS as previously described
(19).
SDS-PAGE and Western blot analysis of human and ferret plasma
FBG.
Human FBG was purchased from KabiVitrum (Franklin, Ohio), and
mouse and rat FBG were from Sigma. Ferret FBG was quantitatively precipitated from plasma (13) or purified as previously
described (27). Commercially obtained FBGs were purified
further to remove contaminating plasminogen and fibronectin (FN)
(46). For Western blotting, 20 µg of protein was resolved
by sodium dodecyl sulfate-polyacrylamide gel electrophoresis (SDS-PAGE)
and electroblotted to nitrocellulose. Immunoblotting was performed with
monoclonal antibody (MAb) H9B7 generated against the chain of human
FBG (18) and shown to cross-react with ferret FBG
(47). Secondary antibodies and substrate color development
were performed as previously described (18).
IEM.
Polyclonal antiserum was raised in rabbits against
purified mouse FBG, and the immunoglobulin G (IgG) fraction was
affinity purified (28, 46). P. carinii-infected SCID mice were sacrificed, and the lungs were
inflation fixed in situ with 4% paraformaldehyde-0.1% glutaraldehyde
in 0.1 M phosphate buffer, pH 7.2, as previously described
(57). Fixed lungs were removed and processed into embedding
resin, and immunoelectron microscopy (IEM) was performed as previously
described (14).
| |
RESULTS |
Establishment of P. carinii infection and
inflammatory cell response.
P. carinii infection
was documented after 4 to 6 weeks of DEX treatment by
staining of tissue sections with GMS (Fig.
1A) and H&E (Fig. 1B), cytocentrifugation
and Diff Quik staining of organisms from infected lung homogenates
(Fig. 1C), and in situ hybridization of ferret lung tissue sections for
expression of P. carinii-specific surface glycoprotein
A (gpA) mRNA (Fig. 1B and D). Positive detection of mRNA is denoted
under darkfield microscopy as abundant, white silver grains localized
to organisms. Note that not all alveoli were uniformly infected. Panels
A and B of Fig. 1 were also hybridized with the gpA antisense
riboprobe. Under brightfield illumination, the silver grains
denoting a positive signal for gpA mRNA in P. carinii
appear as black dots. In addition, P. carinii-infected
ferrets demonstrated the characteristic inflammatory cell response of
alveolar monocyte/macrophage accumulation with little detection
of polymorphonuclear leukocytes (Fig. 1A to C). The course of
P. carinii infection was similar in SCID mice (not shown).
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FIG. 1.
Pathology of P. carinii-infected lung
tissue. Alveolar macrophages (open arrows) were detected in
P. carinii-infected ferret lung tissue by GMS (A) and
H&E (B) staining (cysts, arrowheads; trophs, arrows). Diff Quik
staining demonstrates both trophic (inset, open arrow) and cyst
(arrowheads) nuclei in a cytospin preparation of infected ferret lung
homogenate (C). Note that the cyst forms of P. carinii
shown in this field (arrowheads) contain between four and eight nuclei
representative of intracystic bodies that correspond to the individual
nuclei of the trophic forms released upon excystation during a stage in
the P. carinii life cycle. The bar in panel B
represents 20 µm for panels A to C. Trophic nuclei within a
macrophage cytoplasm were occasionally detected (C, inset). (D) A
low-power darkfield exposure of P. carinii-infected
lung probed with the gpA antisense riboprobe specific for P. carinii gpA mRNA Bar, 70 µm. Arrows indicate blood vessels.
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PCP induces an acute-phase inflammatory reactant in the lung.
Because cultured lung epithelial cells synthesize and secrete
FBG, and hepatic FBG gene expression is upregulated
during an inflammatory response, we determined whether
P. carinii infection induced FBG gene expression in the
lung. The results of Northern hybridization indicated that the
expression of -FBG mRNA was elevated four- to fivefold in the lungs
of P. carinii-infected animals compared to the level in
normal animals (Fig. 2B),
indicative of a localized inflammatory response. Equal loading of
host mRNA was indicated by similar staining of the 28S rRNA by acridine orange-stained gels run in parallel (not shown). Figure 2 shows autoradiographs of liver and lung tissues exposed at room temperature for 15 min and at 
70°C for 6 h, respectively, indicating that, while the overall relative abundance of -FBG mRNA per microgram of
RNA is much lower in the lung compared to the liver, the relative induction of -FBG mRNA was four- to fivefold higher in both the lung and liver of a P. carinii-infected animal (Fig. 2A
and B, lanes 2) than in those of a control. To determine the
cell-type specificity of -FBG mRNA expression in the
infected lung, RNA:RNA in situ hybridization was performed.
In both uninfected and infected lungs, -FBG mRNA expression was
observed in the epithelium. The levels of -FBG mRNA were
increased in airway epithelial cells of infected lung tissue (Fig.
3).
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FIG. 2.
Northern blot analysis of normal and PCP ferret liver
and lung mRNAs. Poly(A)+ mRNA (5 µg) from normal (lanes
1) and P. carinii-infected (lanes 2) ferret liver (A)
and lung (B) probed with pFLG3. The positions of the host rRNAs are
indicated.
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FIG. 3.
In situ hybridization of lung tissues from normal and
P. carinii-infected ferrets. Tissue sections shown in
panels A to D were probed with pFLG3 antisense probe; insets were
probed with pFLG3 sense probe. The arrows indicate bronchial
epithelial cells in P. carinii-infected (C) and normal
(A) ferret lung tissues. H&E stains of the same fields are also shown
(B and D, respectively). Positive detection of mRNA is denoted under
darkfield microscopy as abundant, white silver grains localized to the
cytoplasm of cells (panels A and C).
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Alveolar epithelium produces FBG protein during PCP.
To
determine whether lung epithelial cells synthesize FBG protein in
vivo, IEM of P. carinii-infected lung tissue was
performed. The results showed the intracellular presence of FBG in
secretory granules of epithelium lining the fused basement
membrane of the septa between adjacent alveoli (Fig.
4A). P. carinii organisms were observed attached to alveolar epithelial cells where intracellular FBG protein was detected (Fig. 4B). While the complete life cycle of
P. carinii has not been fully elucidated due to the
lack of a continuous in vitro culture system, several developmental
stages of the organism have been identified by light and electron
microscopy (23, 27, 31, 32, 59). The two major developmental
forms of the organism, the amporhous trophic form (also known as troph, trophozoite, or intracystic body) and the rigid cyst form differ in the
composition of their cell walls (59). During the putative life cycle, the trophozoite matures into a precyst which develops up to
8 intracystic bodies. Upon excystation, these "daughter" trophs are
released to renew the cycle. In this study, the characteristic trophic
and cyst forms of P. carinii were observed by both
light (Fig. 1) and transmission electron microscopy (Fig. 4).
Furthermore, intra-alveolar FBG was detected at the junction of cell
membranes of trophic forms of P. carinii aggregated at
the apical face of the alveolar epithelium (Fig. 4D), suggesting that
FBG may participate in aggregation and adherence of the organisms to
type I epithelium.
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FIG. 4.
IEM localization of FBG in the lung epithelium. The
intracellular presence of FBG in P. carinii-infected
lung tissue was determined by IEM by using 100 µg of anti-FBG IgG/ml
detected with Protein-A-gold (diameter, 20 nm) conjugate (panels A and
B, arrows; panel D, asterisk). FBG was detected at the junction of cell
membranes of trophic forms of P. carinii organisms
(panel D, circle) aggregated (panel D, arrow) along the alveolar
epithelium (panel D, arrowheads). Purified rabbit IgG (100 µg/ml) was
used as the negative control in the primary antibody step (F). The
morphologically rigid cyst and pleomorphic trophic forms of
P. carinii organisms attached to type I epithelium and
aggregated in the alveolar spaces are shown in panels B to F. Lower
magnifications show the integrity of septal walls between alveoli (C
and F). Alveolar capillaries are indicated by the presence of the
erythrocytes (RBC). The appropriate magnification for each field is
indicated. A, alveolar lumen; Nu, nucleus; Pc, P. carinii.
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PCP induces a systemic APR.
Northern hybridization revealed
that P. carinii infection induced upregulation of the
-FBG gene as determined by increases in the steady-state levels
of liver -FBG mRNA (Fig. 2A). RNA in situ hybridization studies
demonstrated that the levels of -FBG mRNA were significantly
upregulated in all hepatocytes during PCP, while the levels of
-actin remained the same (Fig. 5).
This observation is consistent with a systemic APR to the infection. The induction of systemic inflammation in the ferret model of PCP was
further supported by increased levels of FBG in plasma (Fig.
6A), also detected by Western blot
identification of the ferret FBG -chain with the cross-reacting MAb,
H9B7 (Fig. 6B).
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FIG. 5.
In situ hybridization of liver tissue from normal and
P. carinii-infected ferrets. Normal (A and C) and
P. carinii-infected (B and D) livers were probed with
pFLG3+ (panels A and B) or -actin antisense probes
(panels C and D); insets were probed with pFLG3 sense
probe.
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FIG. 6.
SDS-PAGE and Western blot of plasma FBG. Ferret plasma
FBG was quantitatively precipitated from 8 µl of plasma and resolved
by SDS-7.5% PAGE. (A) Coomassie blue stain; (B) immunoblot with
cross-reacting anti-human chain MAb, H9B7.
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The role of P. carinii infection in the absence of
DEX immunosuppression.
To determine whether P. carinii infection in the absence of DEX immunosuppression resulted
in increased lung expression of -FBG, the SCID mouse model of PCP
was utilized. The levels of -FBG mRNA were increased twofold in
P. carinii-infected SCID mouse liver consistent with
the level of induction of FBG gene expression in a variety of in vivo
and in vitro models of inflammation. While the basal level of -FBG
mRNA was undetectable in control lung total RNA, -FBG mRNA was
detectable in P. carinii-infected lung total RNA,
indicating an increase in steady-state levels of -FBG mRNA
during P. carinii infection (Fig.
7). These results indicate that
P. carinii infection alone in the absence of DEX immunosuppression is sufficient to induce the mediator(s) of
-FBG expression locally in the lung and systemically in the
liver.
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FIG. 7.
Northern blot analysis of -FBG mRNA in P. carinii-infected SCID mouse liver and lung. (A) Total RNA (20 µg) from uninfected (CON, lanes 1 and 2) and P. carinii-infected (PCP, lanes 3 and 4) SCID mouse liver (LV, lanes
2 and 3) and lung (LG, lanes 1 and 4) was probed with -FBG cDNA
pRBP18. (B) Acridine orange-stained gel of duplicate set of
denatured RNA.
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The role of DEX immunosuppression in the absence of P. carinii infection.
To determine whether DEX treatment alone,
in the absence of P. carinii infection, resulted in
elevated -FBG gene expression, ferrets were treated with
tetracycline, Bactrim, and DEX to achieve immunosuppression but prevent
PCP; control animals were treated with tetracycline and Bactrim but not
with DEX. RNA was prepared from the lungs and livers of matched
pairs of animals 3 and 4 weeks after initiation of DEX
immunosuppression. Microscopic examination of GMS-stained histological
sections cut from the Bactrim-treated immunosuppressed and control
ferret lungs indicated that Bactrim was successful in
preventing P. carinii infection (not shown). Total RNAs (20 µg) from 4-week DEX-immunosuppressed tissues and normal tissues were probed with the ferret specific -FBG cDNA, pFLG3. Equivalent amounts of -FBG mRNA were found in
DEX-treated compared to normal ferret liver, indicating that prolonged
exposure of the animal to DEX immunosuppression did not result in
induction of -FBG gene expression (not shown). To demonstrate basal
amounts of -FBG mRNA in lung tissues of the control and
DEX-treated ferrets, reverse transcriptase (RT) PCR amplification
of total RNA (10µg) from P. carinii-infected
liver and lung tissues was carried out. The results
demonstrated that the lung tissue mRNA was intact and that basal
amounts of steady-state -FBG mRNA were present in normal lung
tissue (Fig. 8A), as shown above by
Northern (Fig. 2) and in situ hybridizations (Fig. 3). The primer pairs
used for amplification of the RNA:DNA heteroduplex resulted in a 200-bp product for -FBG and a 450-bp product for 
-actin (Fig. 8A). To
confirm the absence of P. carinii organisms at the
microscopic level, RT-PCR was performed using primer pairs specific for
ferret P. carinii gpA. The results indicated that none
of the Bactrim-treated animals were susceptible to breakthrough
infection with P. carinii, as the characteristic 220-bp
product for ferret-derived P. carinii gpA was not
obtained (Fig. 8B). Taken together, these results confirm that
the observed increase in -FBG gene expression in both liver and lung
tissues occurs only during P. carinii infection and is
not a result of prolonged DEX immunosuppression.
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FIG. 8.
RT-PCR of RNA isolated from ferrets treated in the
presence or absence of DEX and Bactrim. Bactrim-treated
DEX-immunosuppressed (DEX), control (none), and P. carinii-infected (PCP) ferret lungs and livers were amplified with
-FBG and -actin primer pairs (A). Total RNAs from the livers and
lungs of P. carinii-infected ferrets were amplified
with a gpA-specific primer pair as positive controls for the RT-PCR
(B). In both panels, no template served as the negative control
reaction. The molecular size markers are in 100-bp increments.
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DISCUSSION |
Our data show clearly that P. carinii infection
results in local and systemic inflammatory responses as measured by
increased levels of -FBG mRNA in lung and liver tissues,
respectively. Prolonged immunosuppression of animals with DEX, in the
absence of P. carinii infection, did not result in an
increase in -FBG mRNA expression in either the lung or liver. In
light of these results, the induction of FBG mRNAs in the ferret is not
likely the result of nonspecific upregulation secondary to DEX
administration but is a specific consequence of PCP. Finally, we
showed the in vivo production of FBG by the lung alveolar epithelium by
IEM and have previously demonstrated that IL-6 and DEX, known positive regulators in the induction of hepatic FBG gene expression (10, 53), induce the synthesis and secretion of intact FBG from a human lung epithelial cell line (46). Furthermore, elevated expression of FBG mRNA in the liver and lung during PCP suggested that, in addition to a systemic (liver) inflammatory reaction, a
tissue-specific (i.e., lung) inflammatory reaction akin to the APR was
induced. Haptoglobin, another APR protein whose expression was
considered liver specific, is also expressed in the lung epithelium during inflammation (58).
Until recently, little was known about the induction of an APR during
PCP. Syrjala et al. (50) monitored the levels of
C-reactive protein (CRP) in human immunodeficiency virus-infected and
immunocompromised patients with or without PCP; CRP is upregulated
several hundredfold in a systemic APR (10, 53). The levels
of CRP were elevated over 200-fold in patients with a fatal outcome of
PCP, while human immunodeficiency virus infection itself did not
significantly increase CRP levels (50). The erythrocyte
sedimentation rate was increased in PCP patients as well, indicative of
elevated levels of FBG in plasma in response to a systemic inflammation (10, 53). A review of case histories examining AIDS patients with PCP revealed that 7 of 37 cases had hypoalbuminemia
(8); albumin is downregulated during the APR (10,
53). The peripheral blood monocyte/macrophage accessory cell
population represents the body's major source of IL-6, the cytokine
which plays a central role in regulating the coordinated cytokine
response to injury or infection during the host response to acute or
chronic inflammation (53); lung cells express elevated
levels of IL-6 during PCP (2, 57). Alveolar macrophages were
the predominant inflammatory cell type observed during PCP in ferrets,
as was also shown in other animal models of PCP (29, 57).
Macrophages contribute to the control of P. carinii
infection by the production of the proinflammatory cytokines IL-1,
IL-6 and tumor necrosis factor alpha (TNF-
). During PCP, IL-1 and
TNF- are present only in the lungs (5, 6, 21), whereas
IL-6 is found in both the lungs and circulation (4, 57).
These findings suggest that TNF- and IL-1 function principally at
the site of infection, whereas IL-6 acts both at the site of
infection and systemically in the upregulation of FBG gene expression
in the lung and liver, respectively, as shown in this study. Together,
these observations indicate that P. carinii infection
induces a systemic inflammatory response. Moreover, production of FBG
by the lung epithelium is indicative of a local inflammatory response
during infection, providing the first demonstration of the extrahepatic
expression of FBG during an acute or chronic inflammatory response in
vivo.
A growing body of literature has emerged elucidating interrelationships
among inflammatory cells, cytokines, and FBG and its related products,
fibrin and FDPs, that is applicable to understanding the progression of
PCP. During P. carinii infection, elevated levels
of TNF- may induce pulmonary expression of intercellular adhesion molecule 1 (ICAM-1, CD54) (60), which is
involved in cell-cell interactions (48). It is known that
the -chain of FBG can enhance leukocyte binding to cells through a
bridging mechanism involving either two ICAM-1s on opposing cells or
through CD11b-CD18 (CR3, Mac-1) and ICAM-1 (26, 56).
Additionally, the presence of FDPs may adversely affect functional
CD4+ T lymphocytes (24, 43), which are essential
for host immunity to P. carinii infection
(39). Furthermore, FDPs induce monocytes to express both
procoagulant (tissue factor) and antifibrinolytic activities (tissue
plasminogen activator inhibitor 1) (44). These studies
demonstrate that lung-specific injury induces a systemic inflammatory
response and suggest that excessive fibrin(ogen) in lung tissue poses a
serious threat to adequate resolution of lung infection and injury.
The mechanism of P. carinii attachment and how the lung
epithelium responds to this attachment has been investigated
extensively. P. carinii surface gpA (12)
mediates attachment of the organism to the lung epithelium (30,
41, 42). Several host proteins bind to P. carinii
gpA, including SP-A (61), SP-D (37), mannose binding protein (11, 38), and the extracellular matrix
components FN (41, 42) and vitronectin (VN) (30,
55). Aside from its known functions in fibrin formation and
platelet aggregation, the chain has been shown to mediate the
adhesion of microorganisms to FBG and fibrin (2, 25).
Adhesion of microorganisms to surfaces is the critical early
event in colonization. Adherence of host proteins to the surface of
microorganisms may allow them to escape immune surveillance by
disguising themselves as "self" (25). FN (41,
42) and VN (30, 55) also affect attachment of
P. carinii to the lung epithelium by functioning as
bridging molecules. Adherence of P. carinii to host
molecules takes advantage of the well-described RGD-adhesive domains
and heparin binding domains of FN or VN (41, 55). Levels of
FN, VN (33), and now FBG have been shown to increase in the
lung during PCP. FBG also contains RGD and heparin binding domains
(35, 36) and functions as a bridging molecule in known
cell-cell interactions (26, 56). Thus, it is likely that FBG
synthesized by the lung epithelium may promote adhesion of
P. carinii and/or adhesion of inflammatory cells
to sites of infection. In support of this hypothesis, we observed FBG
immunogold staining that appeared to bridge between P. carinii organisms adhered to the alveolar epithelium. We postulate
that the FBG RGD and heparin binding domains participate
in such intra-alveolar clumping of the organisms.
Tissue response to injury involves the activation of repair mechanisms
that promote removal of debris and tissue remodeling to restore normal
architecture and function. Extensive or prolonged lung injury is likely
to result in excessive tissue destruction and development of fibrosis
(24). Synthesis of FBG in lung may serve to restore
homeostasis by aiding in wound repair or extracellular matrix
remodeling after injury, similar to the function of circulating hepatic
FBG produced in response to acute or chronic inflammation. Indeed,
neutralization of IL-6 during PCP results in more severe inflammation
and delayed clearance of the organism from the lung (4).
However, elevated levels of FBG at the sites of inflammation, particularly associated with lung injury, may result in pathogenesis caused by overactive repair mechanisms. The association of high levels
of FBG and fibrin deposition in lung disease becomes of greater concern
when considering the possibility that local synthesis of FBG could
contribute to rearranged lung architecture. Moreover, formation of
fibrin and subsequent fibrinolysis in lung tissue at sites of
inflammation may further enhance production of proinflammatory cytokines and thereby lead to pathophysiologic events. An imbalance of
procoagulant and fibrinolytic activities of resident and infiltrating mononuclear cells may also lead to abnormalities in surfactant function
(34, 45). When surfactant production is reduced or surfactant is damaged, alveoli collapse, causing hypoxia and the conditions that favor edema formation, resulting in a potentially fatal outcome in patients suffering from PCP or other severe lung diseases. Therefore, synthesis of FBG upon induction by proinflammatory mediators in the pulmonary epithelium is a significant new finding that
may have dramatic implications for improving the management of patients
with lung diseases or infections.
| |
ACKNOWLEDGMENTS |
We thank Barbara J. Earnest, Karl Van Der Meid, and Jean Brennan
for their expert technical assistance with the animal models of PCP;
Sarah O. Lawrence for assistance with immunoelectron microscopy; and
Gayle Guadiz and C. G. Haidaris for their critical reading of the
manuscript.
This work was supported by PHS grants HL50615, AI23302, AI07362,
HL30616, AI28354, and HL59833 from the National Institutes of Health,
Bethesda, Md., and a grant from the Strong Children's Research Center of the University of Rochester.
| |
FOOTNOTES |
*
Corresponding author. Mailing address: Vascular
Medicine Unit, P.O. Box 610, University of Rochester, 601 Elmwood
Ave., Rochester, NY 14642. Phone: (716) 275-8267. Fax: (716)
473-4314. E-mail: pj_simpsonhaidaris{at}urmc.rochester.edu.
Editor:
J. M. Mansfield
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Abstract
Introduction
