Samuel Hawgood

Structure and properties of surfactant protein B

Surfactant protein B is a small homodimeric protein that is found tightly associated with surfactant lipids in the alveolar space. In this review, we discuss the actions of SP-B on phospholipid membranes using information predominantly obtained from model membrane systems. We try to correlate these model actions with current concepts of SP-B structure and proposed biological functions. These functions may include critical roles in the intracellular assembly of surfactant through a role in lamellar body organogenesis, the structural rearrangement of secreted surfactant lipids into tubular myelin, and the subsequent rapid insertion of secreted surfactant phospholipids into the surface film itself. The relevance of SP-B to human biology is emphasized by the fatal respiratory distress that is associated with a genetic deficiency of SP-B and the important role of SP-B in certain exogenous surfactant formulations in wide clinical use.

Regulation of messenger RNAs for the hydrophobic surfactant proteins in human lung.

The pulmonary surfactant proteins SP-B (8,000 D) and SP-C (4,000 D) accelerate surface film formation by surfactant phospholipids. We used cDNA probes to examine regulation of these proteins in human fetal lung. The mRNAs were detectable at 13 wk gestation and increased to approximately 50% (SP-B) and approximately 15% (SP-C) of adult levels at 24 wk. The mRNAs were detected only in lung of 11 dog tissues examined. When human fetal lung was cultured as explants without hormones, SP-B mRNA increased and SP-C mRNA decreased. Exposure for 48 h to glucocorticoids, but not other steroids, increased both SP-B mRNA (approximately 4-fold) and SP-C mRNA (approximately 30-fold) vs. controls. Half-maximal stimulation occurred with 1 nM dexamethasone and 300 nM cortisol for SP-B mRNA and at three- to fivefold higher concentrations for SP-C mRNA. Both stimulation and its reversal on removal of hormone were more rapid for SP-B than for SP-C. Terbutaline and forskolin increased SP-B mRNA but not SP-C mRNA. Levels of both mRNAs were much higher in type II cells than fibroblasts prepared from explants. Thus, the genes for SP-B and SP-C are expressed in vivo before synthesis of both SP-A (28,000-36,000 D) and surfactant lipids. Glucocorticoid induction of SP-B and SP-C mRNAs in type II cells appears to be receptor mediated but may involve different mechanisms.

Surfactant Protein D Reduces Alveolar Macrophage Apoptosis In Vivo

Surfactant protein D (SP-D) is a molecule of the innate immune system that recognizes the patterns of surface carbohydrate on pathogens and targets them for phagocytosis and killing. SP-D-deficient mice show an increased number of macrophages in the alveolar space, excess surfactant phospholipid, overproduction of reactive oxygen species, and the development of emphysema. We report here that SP-D-deficient mice have a 5- to 10-fold increase in the number of apoptotic and necrotic alveolar macrophages, as defined by annexin V and propidium iodine staining, respectively. Intrapulmonary administration of a truncated 60-kDa fragment of human recombinant SP-D reduces the number of apoptotic and necrotic alveolar macrophages and partially corrects the lipid accumulation in SP-D-deficient mice. The same SP-D fragment binds preferentially to apoptotic and necrotic alveolar macrophages in vitro, suggesting that SP-D contributes to immune homeostasis in the lung by recognizing and promoting removal of necrotic and apoptotic cells.

N-Linked Glycosylation Attenuates H3N2 Influenza Viruses

ABSTRACT Over the last four decades, H3N2 subtype influenza A viruses have gradually acquired additional potential sites for glycosylation within the globular head of the hemagglutinin (HA) protein. Here, we have examined the biological effect of additional glycosylation on the virulence of H3N2 influenza viruses. We created otherwise isogenic reassortant viruses by site-directed mutagenesis that contain additional potential sites for glycosylation and examined the effect on virulence in naïve BALB/c, C57BL/6, and surfactant protein D (SP-D)-deficient mice. The introduction of additional sites was consistent with the sequence of acquisition in the globular head over the past 40 years, beginning with two sites in 1968 to the seven sites found in contemporary influenza viruses circulating in 2000. Decreased morbidity and mortality, as well as lower viral lung titers, were seen in mice as the level of potential glycosylation of the viruses increased. This correlated with decreased evidence of virus-mediated lung damage and increased in vitro inhibition of hemagglutination by SP-D. SP-D-deficient animals displayed an inverse pattern of disease, such that more highly glycosylated viruses elicited disease equivalent to or exceeding that of the wild type. We conclude from these data that increased glycosylation of influenza viruses results in decreased virulence, which is at least partly mediated by SP-D-induced clearance from the lung. The continued exploration of interactions between highly glycosylated viruses and surfactant proteins may lead to an improved understanding of the biology within the lung and strategies for viral control.

Localization and Developmental Expression of Surfactant Proteins D and A in the Respiratory Tract of the Mouse

Surfactant protein D (SP-D) is synthesized and secreted by pulmonary epithelial cells. Like surfactant protein A (SP-A), SP-D is a collagen-like glycoprotein belonging to the “collectin” class of C-type lectins that may play an important role in pulmonary host defense. To begin studies on SP-D gene regulation and function using the mouse as an animal model, we identified the cellular sites of SP-D gene expression in adult mouse lung and trachea and characterized the developmental expression of SP-D mRNA in murine fetal and newborn lungs. We compared these findings with similar studies for murine SP-A, which has an established role in surfactant function and metabolism and a probable role in pulmonary host defense. SP-D mRNA and protein were readily detected by in situ hybridization and immunocytochemistry in alveolar type II and nonciliated bronchiolar epithelial cells of the lung, as well as in cells of the tracheal epithelium and tracheal submucosal glands of the adult mouse. Although SP-A mRNA and protein were also localized to alveolar and nonciliated bronchiolar epithelial cells of the murine lung, there was no detectable labeling for either SP-A mRNA or protein in the murine trachea. Expression of murine SP-D mRNA was first detected by Northern blot analysis on d 16 of gestation in timed-pregnant mice, with an average gestational period of 17 d, and this increased dramatically before birth and during the immediate postnatal period. The developmental expression of murine SP-A mRNA paralleled that of SP-D except that there was a small decrease in mRNA content on postnatal d 5. These studies provide the first description of the cellular distribution and developmental expression of SP-D in mouse lung, which will be important for interpreting future studies of SP-D gene expression in transgenic animal models. In addition, these studies provide the first documentation that, unlike SP-A, SP-D is synthesized not only in the lung but also in submucosal glands of the trachea.

Tissue distribution of surfactant proteins A and D in the mouse.

Surfactant proteins A and D, collagen-like lectins (collectins), were first isolated from the lung. In the lung, SP-A and SP-D have roles in surfactant homeostasis and innate immunity. In this study we show that SP-A and SP-D mRNA can be detected in a significant number of non-pulmonary tissues but the proteins have a more limited distribution. SP-D protein was detected in lung, uterus, ovary, and lacrimal gland, whereas SP-A protein was detected only in the lung. The results suggest that SP-D participates in mucosal immunity throughout the body.

Surfactant apoprotein A modifies the inhibitory effect of plasma proteins on surfactant activity in vivo.

ABSTRACT: Surfactant apoprotein A (SP-A) reduces the inhibitory effects of plasma proteins on the surface tension lowering properties of pulmonary surfactant in vitro. To test the effects of SP-A in vivo we administered a complete natural dog lung surfactant (DLS) containing apoproteins SP-A, SP-B, and SP-C, a butanol extract of DLS (DLSE) containing only apoproteins SP-B and SP-C, and DLSE supplemented with SP-A intratracheally to prematurely delivered rabbit pups in the presence of increasing amounts of human plasma. In the absence of plasma DLS and DLSE (100 mg/kg phospholipid) had comparable effects on lung mechanics (compliance during ventilation with a tidal volume of 6–7 mL/kg and quasi-static pressure-volume behavior) in this surfactant deficiency model. Plasma proteins in increasing amounts to a maximum protein concentration of 62.5 mg/mL had no effect on the response of the pups to DLS. In contrast, plasma added to DLSE in concentrations above 20 mg/mL significantly increased the peak inspiratory pressure (PIP) required to ventilate the pups with a tidal volume of 6–7 mL/kg, reduced the calculated total lung compliance, and decreased the deflation lung volumes. The inhibitory effects of plasma on DLSE were significantly less when SP-A was added to DLSE (5:1, phospholipid:SP-A, wt:wt). The addition of SP-A to DLSE in plasma restored the activity of the extract to levels comparable to complete DLS. These results suggest that plasma can interfere with surfactant function and that SP-A has a significant protective effect for surfactant against the inhibitory effects of plasma in vivo.

Pulmonary Collectins Modulate Strain-Specific Influenza A Virus Infection and Host Responses

ABSTRACT Collectins are secreted collagen-like lectins that bind, agglutinate, and neutralize influenza A virus (IAV) in vitro. Surfactant proteins A and D (SP-A and SP-D) are collectins expressed in the airway and alveolar epithelium and could have a role in the regulation of IAV infection in vivo. Previous studies have shown that binding of SP-D to IAV is dependent on the glycosylation of specific sites on the HA1 domain of hemagglutinin on the surface of IAV, while the binding of SP-A to the HA1 domain is dependent on the glycosylation of the carbohydrate recognition domain of SP-A. Here, using SP-A and SP-D gene-targeted mice on a common C57BL6 background, we report that viral replication and the host response as measured by weight loss, neutrophil influx into the lung, and local cytokine release are regulated by SP-D but not SP-A when the IAV is glycosylated at a specific site (N165) on the HA1 domain. SP-D does not protect against IAV infection with a strain lacking glycosylation at N165. With the exception of a small difference on day 2 after infection with X-79, we did not find any significant difference in viral load in SP-A−/− mice with either IAV strain, although small differences in the cytokine responses to IAV were detected in SP-A−/− mice. Mice deficient in both SP-A and SP-D responded to IAV similarly to mice deficient in SP-D alone. Since most strains of IAV currently circulating are glycosylated at N165, SP-D may play a role in protection from IAV infection.

Deletion of the Transmembrane Transporter ABCG1 Results in Progressive Pulmonary Lipidosis

We show that mice lacking the ATP-binding cassette transmembrane transporter ABCG1 show progressive and age-dependent severe pulmonary lipidosis that recapitulates the phenotypes of different respiratory syndromes in both humans and mice. The lungs of chow-fed Abcg1-/- mice, >6-months old, exhibit extensive subpleural cellular accumulation, macrophage, and pneumocyte type 2 hypertrophy, massive lipid deposition in both macrophages and pneumocytes and increased levels of surfactant. No such abnormalities are observed at 3 months of age. However, gene expression profiling reveals significant changes in the levels of mRNAs encoding key genes involved in lipid metabolism in both 3- and 8-month-old Abcg1-/- mice. These data suggest that the lungs of young Abcg1-/- mice maintain normal lipid levels by repressing lipid biosynthetic pathways and that such compensation is inadequate as the mice mature. Studies with A-549 cells, a model for pneumocytes type 2, demonstrate that overexpression of ABCG1 specifically stimulates the efflux of cellular cholesterol by a process that is dependent upon phospholipid secretion. In addition, we demonstrate that Abcg1-/-, but not wild-type macrophages, accumulate cholesterol ester droplets when incubated with surfactant. Together, these data provide a mechanism to explain the lipid accumulation in the lungs of Abcg1-/-mice. In summary, our results demonstrate that ABCG1 plays essential roles in pulmonary lipid homeostasis.

Proteolytic inactivation of dog lung surfactant-associated proteins by neutrophil elastase

The adsorption of pulmonary surfactant to an air/fluid interface is influenced by calcium-dependent interactions between its lipid and protein components. The latter include a glycoprotein of 28-36 kDa (SP-A) and two smaller hydrophobic proteins of 5-8 kDa (SP-B, SP-C). Neutrophil elastase and other proteolytic enzymes found in the alveolar washings in a variety of acute lung injuries may cleave the protein components of lung surfactant. To examine the hypothesis that free airspace elastolytic activity may thereby impair surfactant function, we analyzed the effect of neutrophil elastase on surfactant activity in vitro. The adsorption characteristics of dog surfactant and of complexes reassembled from purified surfactant components were examined after incubations with active or heat-inactivated neutrophil elastase. Surfactant preincubated with the active enzyme showed a marked concentration-dependent slowing of adsorption associated with proteolytic cleavage of SP-A. To determine whether elastase also decreases surface activity by affecting the hydrophobic proteins SP-B and SP-C, we studied the effect of incubating elastase with liposomes prepared from surfactant lipid fractions which contain SP-B and SP-C. The addition of intact SP-A to these liposomes incubated with inactive enzyme immediately enhanced adsorption speed. This enhancement was greatly attenuated in liposomes treated with active elastase, suggesting that one or both of the hydrophobic surfactant proteins had been affected by elastase. We conclude that proteolytic cleavage of surfactant proteins reduces adsorption speed in vitro and may disturb surfactant function in vivo.