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Pulmonary alveolar proteinosis (PAP) is a rare disease characterized by an excessive accumulation of surfactant lipids and proteins in the alveolar space. In mice with a homozygous deletion of granulocyte macrophage-colony stimulating factor (GM-CSF), their phenotype mimics PAP. To evaluate whether the knockout mouse model mimics human disease, we evaluated GM-CSF expression in alveolar macrophages from a patient with PAP. We performed multiple whole lung lavages on a patient with PAP, and cultured BAL cells in the presence or absence of LPS. In contrast to the GM-CSF knockout mouse, human BAL cells from a patient with PAP expressed mRNA for GM-CSF following LPS stimulation. However, similar to the knockout mouse, GM-CSF protein release from BAL cells was undetectable with or without LPS. BAL cells from normal human controls released GM-CSF in abundance after LPS stimulation. In BAL cells from the patient with PAP, neutralization of interleukin-10 (IL-10) by anti-IL-10 antibody, resulted in enhanced GM-CSF production. Thus, alveolar macrophages from a PAP lung have deficient GM-CSF production analogous to the GM-CSF knockout mice; in contrast, human cells from a PAP lung have an intact GM-CSF gene. This case report illustrates an important difference between the knockout mouse model of PAP and the human disease. Tchou-Wong K-M, Harkin TJ, Chi C, Bodkin M, Rom WN. GM-CSF gene expression is normal but protein release is absent in a patient with pulmonary alveolar proteinosis.
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Mice lacking granulocyte/macrophage colony stimulating factor (GM-CSF) generated by homologous recombination develop PAP (1, 2). Surfactant proteins (SP-A, -B, and -C) were
all significantly increased in BAL from these GM-CSF knockout mice compared with wild-type mice, and their lungs contained eosinophilic acellular material in alveolar spaces accompanied by increased tubular myelin. Interestingly, levels
of surfactant mRNAs in mutant mice were indistinguishable
from that in wild-type mice but alveolar macrophages from
GM-CSF-deficient mice contained a marked increase of surfactant protein and lipid. The derangement in PAP was suggested to be related to defective macrophage surfactant catabolism or clearance. In addition, the authors postulated a
regulatory role for GM-CSF in surfactant uptake, perhaps by
regulating collectin receptors. Another murine model of PAP
resulted from homozygous mutation of the GM-CSF 
c receptor gene demonstrated the necessity of GM-CSF signalling in
macrophages to process surfactant (3). Correction of PAP in
this model was accomplished by bone marrow transplantation from wild type mice to c deficient mice demonstrating the
central role alveolar macrophages play in this disorder (4).
Furthermore, Huffman and colleagues recently reported that
pulmonary epithelial expression of GM-CSF using a SP-C-GM-CSF construct in GM-CSF deficient mice corrected the alveolar proteinosis and lymphocytic infiltrates (5). In a further
animal model, PAP occurred in severe combined immunodeficient (SCID) mice that had nonfunctional T and B lymphocytes supporting a role for these cells in surfactant homeostasis (6).
We investigated the function of the GM-CSF gene in four
consecutive whole lung lavages from a PAP patient and demonstrate that the GM-CSF gene in BAL cells could be induced
by LPS in vitro, but that GM-CSF protein in the BAL cell supernatants was nondetectable with or without LPS. We found
that the GM-CSF deficiency following LPS stimulation of
BAL cells could be neutralized by anti-IL-10 antibody but not
anti-TGF- antibody. These data represent a novel comparison of a disease model where GM-CSF deficient mice develop PAP, but in an adult patient with PAP there is inducibility of the gene but absence of protein. An additional case report of PAP in an Australian patient had improvement in symptoms,
alveolar arterial oxygen gradient, and chest radiographs following subcutaneous injections of recombinant GM-CSF (7).
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Patient Summary
Our patient is a 29-yr-old Vietnamese female who had resided in the U.S. for 6 yr. She complained of dyspnea on exertion progressing to less than one block's distance before stopping. She was a lifelong nonsmoker with no occupational inorganic dust exposure or evidence of malignancy. Her chest radiograph revealed bilateral basilar alveolar and interstitial infiltrates. A diagnostic BAL demonstrated that recovered fluid was turbid and cream colored. Electron microscopy identified characteristic tubular myelin within macrophages and lavage fluid.
Whole lung lavage was performed December 1994, with a double lumen endotracheal tube. Procedure 1 was terminated after 13 L of lavage at which point the returned fluid was almost clear. The patient did well until August 1995 when she experienced increasing dyspnea and her chest radiograph again revealed bilateral infiltrates. A second whole lung lavage was performed with 21 L, of normal saline. The BAL cell differential was 58% macrophages, 36% lymphocytes and 6% neutrophils. Flow cytometry revealed 35% CD4+ cells and 56 CD8+ cells for a CD4+/CD8+ ratio of 0.6. The third whole lung lavage performed in October 1995 was on the opposite side and the cell differential was 81% macrophages, 14% lymphocytes and 5% neutrophils. A fourth whole lung lavage was performed October 1996, and the cell differential was 47% macrophages, 29% lymphocytes and 24% neutrophils. Flow cytometry revealed 51% CD4+ cells and 44% CD8+ cells for a CD4+/CD8+ ratio of 1.2.
As a comparison group, four normal volunteers (ages 27-32) who were nonsmokers had a research BAL with a fiberoptic bronchoscope. Under local anesthesia, five, 20 ml aliquots of normal saline were instilled sequentially followed by suction in the right middle lobe, right lower lobe, and lingula. None had occupational exposure to inorganic dust and all were in good health. The New York University Human Subjects Committee approved the protocol. The BAL cell differential means were macrophages 83 ± 2%, lymphocytes 15 ± 2%, and neutrophils 2 ± 2%.
Isolation and Culturing of BAL Cells
The recovered bronchoalveolar lavage fluid was filtered through sterile gauze. A total cell count was done in a hematocytometer, and cell differentials were performed on cytocentrifuge slides stained with Diff-Quick and 500 cells were counted. Cell viability was determined by trypan blue exclusion, and recovered cells were > 95% viable. Cells were washed in PBS 3× and resuspended in RPMI 1640 containing penicillin (100 U/ml) and streptomycin (100 µg/ml) at 1 × 106 cells/ml in polypropylene tubes and cultured in the presence or absence of LPS (2 µg/ml) at 37° C for 24 h.
After culturing, BAL cells were spun down and supernatants collected and stored at 
80° C. The amount of cytokines secreted into
the supernatants were measured using commercial ELISA kits according to the manufacturer's instructions.
Reagents
Commercial kits for quantitative sandwich enzyme-linked, immunosorbent assays (ELISA) for GM-CSF (limit of detection 8 pg/ml) and IL-10 (limit of detection 15 pg/ml) were purchased from Biosource International (Camarillo, CA) and the IL-1-specific ELISA
kit (limit of detection 2 pg/ml) was purchased from Cistron Biotechnology (Pine Brook, NJ). ELISA assays were performed in triplicate
with the mean ± standard deviation presented.
Lipopolysaccharide (LPS) 055:B5 was purchased from Sigma (St.
Louis, MO). Neutralizing antibody directed against IL-10 and control
rat IgG antibody were purchased from Pharmingen (San Diego, CA)
and pan-specific, neutralizing anti-TGF- antibody was purchased from
R & D Systems (Minneapolis, MN).
RNA Analysis
Cytokine gene expression was analyzed by Northern blot analysis.
Total RNA was isolated by guanidinium isothiocyanate lysis and cesium chloride centrifugation as described (8). Equal amounts of RNA
were fractionated by electrophoresis through a 1% agarose-formaldehyde gel, and transferred to Hybond-N nylon filter (Amersham).
cDNA inserts were labeled with [
-32P]dCTP by random priming. cDNAs for GM-CSF and IL-10 were obtained from Genetics Institute
and ATCC, respectively. Filters were hybridized with labeled probes
in Church buffer (7% SDS, 1% bovine serum albumin, 1 mM EDTA,
0.25 M Na2HPO4, pH 7.2) at 68° C overnight. Filters were washed in
2× SSC (1× SSC is 0.15 M NaCl, 0.015 M sodium citrate) 0.5% SDS
at room temperature for 5 min, 2× SSC-0.1% SDS at room temperature for 15 min and then in 0.1× SSC-0.5% SDS at 65° C for 30 min.
Autoradiography was performed at 80° C. To control for RNA loading, expression of the -actin gene was examined.
Statistics
Comparisons of unstimulated BAL cells to LPS-stimulated BAL cells for GM-CSF for the four normal controls used the Wilcoxon rank sum test.
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Release of GM-CSF from BAL Cells from PAP and Normal Controls
GM-CSF was not spontaneously released by BAL cells obtained from any of the four whole lung lavages from our PAP patient (Sensitivity: 8 pg/ml), whereas GM-CSF release the four normal controls was only minimally present in one individual (Table 1). Upon stimulation with LPS, high levels of GM-CSF were secreted by BAL cells from normal controls (271 ± 160 pg/ml, p < 0.05). In contrast, no GM-CSF was secreted by LPS-stimulated BAL cells recovered from any of the four whole lung lavages of the PAP patient (Table 1).
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Induction of GM-CSF mRNA Expression in PAP and Normals
To determine whether deficient GM-CSF production was due to the lack of GM-CSF gene induction, expression of GM-CSF mRNA was examined by Northern blot analysis. As shown in Figure 1A, expression of GM-CSF mRNA was strongly induced by LPS at 4 h but declined by 24 h. The Northern blot was performed on three of the four PAP whole lung lavages with LPS stimulation over unstimulated cells increasing 3.8-fold, 8.8-fold, and 5.6-fold. The kinetics of GM-CSF mRNA accumulation induced by LPS-stimulated BAL cells from the PAP patient were consistent with that of LPS-stimulated peritoneal mouse macrophages, with a maximal induction between 3-5 h (9). Induction of GM-CSF mRNA expression by LPS was also seen in normal BAL cells (Figure 1B).
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Inhibitory Role of IL-10 on GM-CSF Production
To gain insight into the mechanism of deficient GM-CSF production in the PAP patient, the role of inhibitory molecules
was investigated. IL-10, also known as cytokine synthesis inhibitory factor, has been shown to inhibit the production of cytokines such as IL-1, IL-1, IL-6. IL-8. TNF-, GM-CSF and
G-CSF at the transcriptional level (10). The role of transforming growth factor- (TGF-), a potent macrophage deactivator (12), was also investigated.
IL-10 mRNA was strongly induced at both 4 h and 24 h upon stimulation with LPS in BAL cells from the PAP patient (Figure 2A). In contrast, IL-10 mRNA was not inducible in fresh BAL cells from the normal controls studied after LPS stimulation for 24 h (Figure 2B). BAL cells from the PAP patient released IL-10 spontaneously on three out of four whole lung lavages, and IL-10 release could be further stimulated by LPS each time (Table 1). In contrast, IL-10 production by BAL cells from four normal controls was not induced following LPS stimulation (Table 1).
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To determine the role of IL-10 in suppressing GM-CSF
production, total BAL cells from the PAP patient were stimulated with LPS in the presence of neutralizing anti-IL-10 monoclonal antibodies. As demonstrated in Figure 3A, neutralization of IL-10 resulted in the release of GM-CSF stimulated by
LPS (136 pg/ml) in amounts similar to normal controls (130-494 pg/ml) (Table 1). The specificity of IL-10 inhibition of GM-CSF production was further demonstrated by the fact that
neutralizing anti-TGF- antibodies and control IgG antibodies failed to restore GM-CSF production (Figure 3A).
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As a control for LPS inducibility, IL-1 production by total
BAL cells from the PAP patient was analyzed (Figure 3B).
The release of IL-1 by total BAL cells stimulated with LPS
was slightly enhanced by treatment with anti-IL-10 antibody
(73 pg/ml) compared with LPS alone (38 pg/ml). The production of IL-1 was strongly enhanced by anti-TGF- antibody
(123 pg/ml) which had no effect on GM-CSF release.
Milleron and colleagues reported a significant BAL lymphocytosis in 9 patients with PAP (13). The mean percent lymphocytes was 57 with a significant increase in CD4+ cells and CD8+ cells. We also noticed increased lymphocytes in each whole lung lavage specimen from our PAP patient. IL-10 is a chemotactic factor for CD8+ T lymphocytes and enhances the activity of CD8+ cytotoxic lymphocytes (14). In one of the lavage specimens, we were able to separate adherent cells (> 80% alveolar macrophages) from nonadherent cells (> 70% lymphocytes). There was 4-fold more GM-CSF released from LPS-stimulated adherent cells than nonadherent cells, and 3-fold more IL-10 released from LPS-stimulated nonadherent cells than adherent cells. Interesting, the mouse GM-CSF knockout models had increased lymphocyte accumulation in the PAP lung.
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We report here the first human case of PAP evaluated for
GM-CSF gene expression and protein release by BAL cells.
We have shown in a human study that BAL cells isolated from
the lung failed to secrete GM-CSF protein, although the GM-CSF gene was expressed. The mechanism of GM-CSF deficiency was further addressed by identifying an inhibitory role
for IL-10 in suppressing GM-CSF production. The murine
models show that PAP results from disruption of the GM-CSF
gene or the c receptor gene, whereas the mechanism of human adult PAP results from a functional deficiency of GM-CSF production possibly due to increased levels of the inhibitory cytokine IL-10. Increased IL-10 could possibly lead to
secondary forms of PAP as well. Secondary PAP has been reported in accelerated or acute silicosis, Pneumocytis carinii
pneumonia, and secondary to hematologic malignancies (15,
16). Macrophages upregulate GM-CSF mRNA during phagocytosis of sheep red blood cells analogous to macrophage stimulation by LPS (9). GM-CSF deficiency could reduce macrophage phagocytosis and processing of excess surfactant.
Interleukin-l0, originally identified as a cytokine synthesis
inhibitory factor, is produced by CD4+/CD8+ T cells, B cells
and monocytes/macrophages (10, 11). Stimulation of peripheral blood monocytes by LPS results in cytokine production including IL-1, IL-1, IL-6, IL-8, TNF-, G-CSF, GM-CSF
and IL-10. The endogenously produced IL-10 is able to downregulate the production of the former cytokines as well as its
own production. The IL-10-mediated inhibition of cytokine
production is accompanied by reduced accumulation of mRNAs
(17). Wang and colleagues have shown that IL-10 selectively inhibits NF-
B translocation from the cytosol to the nucleus
consequently inhibiting mRNAs for IL-1, IL-6, IL-8, and
TNF- in a dose dependent manner (18). AP-1, NF-IL6, CREB,
SP-1 and other transcription factors were not affected by IL-10.
They demonstrated that IL-10 blocks NF-B activation in response to distinct NF-B inducers such as LPS and TNF-. In
this report, we have shown that GM-CSF mRNA expression
can be induced by LPS, but the release of GM-CSF is inhibited by IL-10. IL-10 is a potent inhibitor of GM-CSF, including GM-CSF production by chronic myelomonocytic leukemia cells (19). It is a direct inhibitor of T-cell activation by inhibiting IL-12 (17). GM-CSF inhibits the immunosuppressive activity of AM that downregulates local T cell responses
(20) and GM-CSF deficiency would allow for increased T cell
suppressor activity. We would suggest that IL-10 from nonadherent cells inhibits GM-CSF secretion by acting on translation or protein processing in alveolar macrophages.
These data derived from a patient with PAP demonstrate a deficiency in GM-CSF analogous to the GM-CSF knockout mouse. However, the mechanisms for deficient GM-CSF differs between the human and the mouse model. Our patient may represent a form of secondary PAP due to an unknown insult; further studies are indicated to determine if our case report is generalizable to secondary PAP from silica exposure, Pneumocystis carinii penumonia. PAP in remission, and congenital PAP. Studies of GM-CSF and inhibitory molecules on other patients with PAP, a rare disorder, are also indicated. Other mechanisms may also be extant, e.g., defects in expression or function of the GM-CSF receptor, and other suppressor molecules such as Th2 cytokines may be revelant. Restoring GM-CSF function in patients with PAP may be therapeutic, e.g., treating with subcutantous injections (7), or aerosolizing recombinant GM-CSF directly to the lung, or administration of anti-IL-10 antibody. Importantly, these studies demonstrate the need for patient-oriented investigations to complement gene knockout models of human disease.
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Footnotes |
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Correspondence and requests for reprints should be addressed to William N. Rom, M.D., M.P.H., NYU Medical Center, Division of Pulmonary & Critical Care Medicine, Department of Medicine, 550 First Avenue, NB 7N24, New York, NY 10016.
(Received in original form December 27, 1996 and in revised form June 5, 1997).
Acknowledgments: The authors wish to thank Joan Reibman, M.D., for critical reading of the manuscript, and Natalie Little for editorial assistance.
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