Purification of canine surfactant-associated glycoproteins A. Identification of a collagenase-resistant domain

A procedure for purification of surfactant-associated glycoproteins A from canine surfactant was established utilizing preparative isoelectric focusing as a major purification step in absence of detergents. The proteins migrated as charge trains, isoelectric points 4.2-5.0. Unglycosylated forms of surfactant-associated protein A1 (26 kDa) and glycoproteins A2 and A3 (32-36 kDa) were identified by silver-staining and immunoblot analysis. These forms were demonstrated to be identical polypeptides by fingerprint analysis of 125I-labeled peptides generated by tryptic-chymotryptic digests of the iodinated proteins. Size and charge heterogeneity were related to varying amounts of N-linked complex carbohydrates, including sialic acid, which were sensitive to endoglycosidase F and neuraminidase but resistant to endoglycosidase H. A collagenase-sensitive region was demonstrated which was required for sulfhydryl-dependent oligomerization of the molecule. Collagenase treatment resulted in removal of approx. 10 kDa from the glycoprotein molecule. Collagenase-resistant fragments of 21-23 kDa migrated with carbohydrate-dependent size and charge heterogeneity and were reduced to 16 kDa by endoglycosidase F. Amino acid composition of the surfactant glycoproteins demonstrated high glycine content which was diminished after digestion with collagenase. Several glycine-rich tryptic peptides were isolated by reverse-phase chromatography. Partial sequence information shows Gly-X-Y repeat sequences containing hydroxyproline residues. The major canine surfactant-associated proteins, glycoproteins A contain complex-type N-linked carbohydrate. In addition, a separate collagen-like peptide domain is present and is required for sulfhydryl-dependent oligomerization.     

Glycosylation and secretion of surfactant-associated glycoprotein A

Synthesis of glycoprotein A, the major surfactant-associated protein, was demonstrated in Type II epithelial cells isolated from rat lung. Predominant, secreted forms migrated as glycoproteins with asparagine-linked, complex-type oligosaccharides (32,000-36,000 daltons, pI 4.2-4.8). Primary in vitro translation products of the glycoprotein migrated as five distinct proteins of approximately 26,000 daltons which were processed by pancreatic microsomal membranes in vitro to 30,000-34,000-dalton, endoglycosidase F-sensitive forms. These in vitro processed forms of glycoprotein A co-migrated with intracellular forms immunoprecipitated from [35S]methionine-labeled, Type II cells. Pulse-chase experiments with [35S]methionine-labeled cells demonstrated rapid synthesis of endoglycosidase H-sensitive precursors of 34,000 daltons, pI 4.7-4.8, which were neither secreted from Type II cells nor detected in surfactant from alveolar lavage. These high-mannose forms were slowly processed to more acidic, endoglycosidase H-resistant, neuraminidase-sensitive forms. At between 10 and 180 min, fully sialylated or other endoglycosidase H-resistant forms were a minor fraction of intracellular glycoprotein A. After 16 h, intracellular glycoproteins A were primarily present as endoglycosidase H-resistant forms. Secretion of mature, sialylated, glycoprotein A was first detected 1 h after labeling, and was also readily detected after 16-24 h chase period. Tunicamycin, which blocks N-linked protein glycosylation, resulted in synthesis of three major 26,000-dalton proteins which co-migrated with the nonglycosylated, surfactant-associated proteins A1 present in surfactant from alveolar lavage and with the major in vitro translation products of rat lung poly(A+) mRNA. Tunicamycin inhibited secretion of glycoprotein A. Swainsonine, which inhibits Golgi alpha-mannosidase II, completely inhibited synthesis of the fully sialylated molecule. Swainsonine produced forms of glycoprotein A which were both neuraminidase- and endoglycosidase H-sensitive and were readily secreted. Monensin, an ionophore that alters protein transport, markedly inhibited intracellular sialylation and secretion. These studies demonstrate that pulmonary Type II cells rapidly synthesize and process surfactant-associated glycoprotein A precursors to endoglycosidase H-sensitive forms, which are slowly sialylated prior to secretion.     

In vitro acetylation of rat pulmonary surfactant-associated glycoprotein(s) A primary translation products

The primary translation products of pulmonary surfactant-associated glycoprotein(s) A, the major apolipoprotein in mammalian surfactants, exhibit extensive charge heterogeneity. After in vitro translation of poly(A)⁺ mRNa from rat lung, the primary translation products of glycoprotein(s) A were identified as a charge train of five proteins of 26 kDa (pI 4.6–5.0), the predominant forms being the more acidic members (pI < 4.8). Inhibition of acetylation during in vitro translationof rat lung poly(A)⁻ mRNA resulted in a predominance of the more basic isoforms (pI ≥ 4.8). Intracellular forms of glycoprotein(s) A were immunoprecipitated from rat Type II epithelial cells after treatment with tunicamycin or after deglycosylation with endoglycosidase H. Five intracellular precursors consisting primarily of acidic members of the charge train were identified, this being consistent with the intracellular acetylation of the protein. In contrast, canine glycoprotein(s) A translation products consisted of only three proteins of 26 kDa (pI 4.8–5.0), in which most of the radiolabel was concentrated in the more basic components. Acetylation may account for some, but not all, of the charge heterogeneity in the primary translation products and processed forms of surfactant-associated glycoprotein(s) A in the rat.     

Homology of the precursor of pulmonary surfactant-associated protein SP-B with prosaposin and sulfated glycoprotein 1.

The precursor of pulmonary surfactant-associated protein, SP-B, is composed of an NH2-terminal domain of 30 residues (a-type domain) and three tandem repeats of about 90 residues (b-type domain); biophysically active mature SP-B corresponds to the second b-type repeat. Consensus sequences constructed for the b-type repeats were used to search the data base for homologous sequences, and the search has revealed that prosaposin and sulfated glycoprotein 1 show a remarkable homology with these repeats. The domain organizations of the latter proteins, however, differ from that of SP-B precursor inasmuch as they contain four tandem copies of the b-type domain and a-type domains are present both in the NH2-terminal and COOH-terminal parts of the proteins. The implications of the homology of saposins and SP-B for their structure and function are discussed.     

In vitro sulfation of pulmonary surfactant-associated protein-35

Surfactant-associated protein-35 consists of a group of phospholipid-associated proteins of 26-36 kDa isolated from pulmonary alveolar surfactant. In the rat, surfactant-associated protein-35 is synthesized from 26-kDa primary translation products which are cotranslationally acetylated and glycosylated to heterogeneous 30 and 34 kDa forms. High-mannose oligosaccharide-containing precursors of surfactant-associated protein-35 are processed in the rough endoplasmic reticulum and Golgi to complex-type oligosaccharides, resulting in a mature glycoprotein which exhibits extensive charge heterogeneity in two-dimensional isoelectric focusing SDS-polyacrylamide gel electrophoresis. Much of this charge heterogeneity is related to terminal sialylation of the two asparagine-linked oligosaccharides. In the present study, we report that surfactant-associated protein-35 is also sulfated. Sulfation of the 30 and 34 kDa forms of surfactant-associated protein-35 was clearly detected in primary cultures of rat Type II epithelial cells. These sulfated isoforms were sensitive to endoglycosidase F digestion, but resistant to neuraminidase, suggesting that sulfation occurred at oligosaccharide residues other than sialic acid. The lack of sulfation of the 26 kDa forms of surfactant-associated protein-35 and the resistance of the sulfated isoforms to endoglycosidase H digestion are consistent with Golgi-associated sulfation of the complex type oligosaccharides of surfactant-associated protein-35. Thus, sulfation is another component of the complex post-translational processing of surfactant-associated protein-35, which includes acetylation, hydroxylation, glycosylation, sialylation, sulfhydryl-dependent oligomerization and sulfation.     

肺表面活性物质相关蛋白A与肺部免疫防御研究进展

肺表面活性物质相关蛋白A（SP—A）是一种高度保守的亲水性糖蛋白,属于C-型凝素家族成员,相对分子质量为29～36kDa。SP—A是肺部重要的天然免疫防御分子,在肺的局部防御和天然免疫反应中起着十分重要的作用。它不仅可调节局部免疫和炎症反应、调理吞噬作用,还可凝集病原微生物、影响趋化作用及促进杀菌作用等。     

Structure of canine tracheobronchial mucin glycoprotein

Canine tracheal mucin glycoprotein was isolated from beagle dogs fitted with tracheal pouches. Following exclusion chromatography on Sepharose CL-4B, noncovalently associated proteins were further resolved by dissociative density gradient centrifugation in CsBr-guanidinium chloride, and the mucin was then extracted with chloroform-methanol. The delipidated high-density product obtained had a nominal molecular weight of about 10(6) and an overall composition characteristic for a mucin glycoprotein, viz., a high content of serine and threonine, about 80% carbohydrate by weight, the absence of mannose or uronic acid, measurable ester sulfate, and a Pronase-resistant domain of molecular weight (1.75-3.0) X 10(5) which contains essentially all of the saccharide residues. Noncovalently bound lipid amounted to 6-10% by weight and was primarily cholesterol and cholesteryl esters. Cleavage of disulfide bonds by performic acid oxidation resulted in the release of a protein (Mr 65,000) not otherwise resolved by sodium dodecyl sulfate gel electrophoresis or the purification scheme.     

A canine model of neurogenic pulmonary edema

The purpose of this study was to evaluate the usefulness of the intracisternal administration of veratrine as a model of neurogenic pulmonary edema (NPE) in the alpha-chloralose-anesthetized dog. Veratrine (40-60 micrograms/kg) was injected into the cisterna magna of 17 animals, and systemic arterial, pulmonary arterial, and left ventricular end-diastolic (LVEDP) pressures were followed for 1 h. Eleven animals developed alveolar edema. In these animals, systemic arterial pressure increased to 273 +/- 9 (SE) Torr, pulmonary arterial pressure to 74.5 +/- 4.9 Torr, and LVEDP to 42.8 +/- 4.5 Torr, and large amounts of pink frothy fluid, with protein concentrations ranging from 48 to 93% of plasma, appeared in the airways. Postmortem extravascular lung water content (Qwl/dQl) averaged 7.30 +/- 0.46 g H2O/g dry lung wt. Six animals escaped developing this massive degree of edema after veratrine (Qwl/dQl = 4.45 +/- 0.24). These animals exhibited similar elevated systemic arterial pressures (268 +/- 15 Torr), but did not develop the degree of pulmonary hypertension (pulmonary arterial pressure = 52.5 +/- 6.7 Torr, LVEDP = 24.8 +/- 4.0 Torr) observed in the other group. These results suggest that both hemodynamic and permeability mechanisms may play a role in the development of this form of edema and that veratrine administration may provide a useful model of NPE.     

Synthesis of surfactant-associated glycoprotein A by rat type II epithelial cells. Primary translation products and post-translational modification

Surfactant-associated glycoproteins A, 38 (A3), 32 (A2) and 26 (A1) kDa, pI (4.2-4.8), were identified as related proteins present in surfactant isolated from rat lung lavage fluid. Differences in size and charge among surfactant-associated glycoproteins A were related to differences in glycosylation as determined by reduction of the larger forms (38 and 32 kDa) to 26 kDa by endoglycosidase F and by increased isoelectric points of the glycosylated forms after treatment with neuraminidase. Synthesis and secretion of surfactant-associated glycoproteins A and precursors were demonstrated in purified rat Type II epithelial cells by immunoprecipitation of [35S]methionine-labelled proteins with anti-surfactant-associated glycoprotein A antisera. In pulse-chase experiments, labelled proteins 26-34 kDa, appeared within 10 min and smaller forms co-migrated with surfactant-associated glycoprotein A from alveolar lavage. The relative abundance of the larger molecular mass forms (30-34 kDa, pI 4.8) increased at later times up to 3 h. More acidic mature forms, which co-migrated with surfactant-associated glycoproteins A2 and A3 in surfactant (38 and 32 kDa), were readily detectable in the media, but were not abundant forms in lysates of labelled Type II cells after 1-3 h of incubation. Primary translation products of surfactant-associated glycoprotein A were immunoprecipitated with monospecific anti-surfactant-associated glycoprotein A antiserum after in vitro translation of poly(A)+ mRNA isolated from adult rat lung. The immunoprecipitated translation product migrated at 26 kDa, pI 4.8, and migrated slightly faster than surfactant-associated glycoprotein A1 from surfactant. Treatment of surfactant-associated glycoprotein A with bacterial collagenase resulted in proteolytic fragments 23-20 kDa, pI 4.2-4.8, which no longer underwent sulfhydryl-dependent cross-linking, suggesting that the collagen-like domain was required for the sulfhydryl-dependent oligomerization. Surfactant-associated glycoproteins A are synthesized by rat Type II epithelial cells as pre-proteins, 26-34 kDa. Larger forms result primarily from N-linked glycosylation of the 26 kDa primary translation product. Mature, more acidic forms result from further addition of sialic acid.     

Rotaviruses code for two types of glycoprotein precursors

Rotaviruses are nonenveloped viruses that code for two glycoproteins: a structural glycoprotein (VP7) and a nonstructural glycoprotein (NS29). The precursor to VP7 (37K) was shown to contain a 1.5K cleavable signal sequence. The 37K precursor was authentically processed (signal sequence cleaved and the polypeptide "core" glycosylated) when synthesized in a cell-free system supplemented with dog pancreatic microsomes. Similar experiments were performed with the nonstructural glycoprotein precursor (20K); however, the 20K precursor contained an integral (noncleavable) signal sequence. Both precursors were inserted into membranes cotranslationally and both glycosylated products underwent posttranslational oligosaccharide processing. The results suggest a morphogenetic scheme for the simian rotavirus SA11.     

Interaction of pulmonary surfactant-associated protein (SP-A) with surfactant lipids.

A pulmonary surfactant-associated protein complex with components of 36, 32 and 28 kDa was isolated from human lung homogenates and reassembled with surfactant lipids prepared as small unilamellar liposomes. The role of divalent cations in the assembly of this recombinant lipoprotein complex was studied by monitoring the changes in turbidity, intrinsic tryptophanyl fluorescence and surface activity. The protein-facilitated lipid aggregation was promoted on addition of 5 to 20 mM Ca2+. Intrinsic fluorescence measurements on SP-A (28-36 kDa) indicated that the tryptophan side chains were in a relatively hydrophobic environment, that the wavelength of maximum fluorescence emission and also the relative fluorescence, were changed upon the binding of lipid. Tryptophanyl fluorescence of the lipoprotein assembly was quenched as indicated by a reduction in the effective Stern-Volmer constant. These results suggest that Ca2+ lipid-protein interactions are involved in the structure and function of extracellular lung surfactant assembly.     

The 35 kd pulmonary surfactant-associated protein is encoded on chromosome 10

Summary The genomic components identified by each of two closely related cDNA clones for the major 35 kilodalton non-serum surfactant-associated proteins (PSP-A) were shown to derive from human chromosome 10 by Southern blot analysis of DNAs from human-rodent somatic cell hybrids. By in situ hybridization to human metaphase chromosomes, the cDNA probes were localized to the region 10q21-q24.     

Maturation of HIV envelope glycoprotein precursors by cellular endoproteases

The entry of enveloped viruses into its host cells is a crucial step for the propagation of viral infection. The envelope glycoprotein complex controls viral tropism and promotes the membrane fusion process. The surface glycoproteins of enveloped viruses are synthesized as inactive precursors and sorted through the constitutive secretory pathway of the infected cells. To be infectious, most of the viruses require viral envelope glycoprotein maturation by host cell endoproteases. In spite of the strong variability of primary sequences observed within different viral envelope glycoproteins, the endoproteolytical cleavage occurs mainly in a highly conserved domain at the carboxy terminus of the basic consensus sequence (Arg-X-Lys/Arg-Arg downward arrow). The same consensus sequence is recognized by the kexin/subtilisin-like serine proteinases (so called convertases) in many cellular substrates such as prohormones, proprotein of receptors, plasma proteins, growth factors and bacterial toxins. Therefore, several groups of investigators have evaluated the implication of convertases in viral envelope glycoprotein cleavage. Using the vaccinia virus overexpression system, furin was first shown to mediate the proteolytic maturation of both human immunodeficiency virus (HIV-1) and influenza virus envelope glycoproteins. In vitro studies demonstrated that purified convertases directly and specifically cleave viral envelope glycoproteins. Although these studies suggested the participation of several enzymes belonging to the convertases family, recent data suggest that other protease families may also participate in the HIV envelope glycoprotein processing. Their role in the physiological maturation process is still hypothetical and the molecular mechanism of the cleavage is not well documented. Crystallization of the hemagglutinin precursor (HA0) of influenza virus allowed further understanding of the molecular interaction between viral precursors and the cellular endoproteases. Furthermore, relationships between differential pathogenicity of influenza strains and their susceptibility to cleavage are molecularly funded. Here we review the most recent data and recent insights demonstrating the crucial role played by this activation step in virus infectivity. We discuss the cellular endoproteases that are implicated in HIV gp160 endoproteolytical maturation into gp120 and gp41.     

Identification and characterization of the pulmonary alveolar type II cell Maclura pomifera agglutinin-binding membrane glycoprotein

The lectin Maclura pomifera agglutinin (MPA) binds to the apical surface of pulmonary alveolar type II but not type I cells. We show that MPA binds to a single membrane glycoprotein in type II cells with a molecular mass of 230 kDa in the rabbit and 200 kDa in the rat. The glycoprotein has an abundance of terminal N-acetylgalactosamine residues. It is a hydrophilic integral membrane protein suggesting that it has an extensive extramembrane domain or is an ion channel. The glycoprotein is similar in rat and rabbit, with the exception that the rat glycoprotein is partially sialylated and is trypsin sensitive. The MPA-binding glycoprotein represents a new integral membrane marker of the apical domain of the pulmonary alveolar type II cell.     

Identification of adult midgut precursors in Drosophila

The adult Drosophila midgut is thought to arise from an endodermal rudiment specified during embryogenesis. Previous studies have reported the presence of individual cells termed adult midgut precursors (AMPs) as well as “midgut islands” or “islets” in embryonic and larval midgut tissue. Yet the precise relationship between progenitor cell populations and the cells of the adult midgut has not been characterized. Using a combination of molecular markers and directed cell lineage tracing, we provide evidence that the adult midgut arises from a molecularly distinct population of single cells present by the embryonic/larval transition. AMPs reside in a distinct basal position in the larval midgut where they remain through all subsequent larval and pupal stages and into adulthood. At least five phases of AMP activity are associated with the stepwise process of midgut formation. Our data shows that during larval stages AMPs give rise to the presumptive adult epithelium; during pupal stages AMPs contribute to the final size, cell number and form. Finally, a genetic screen has led to the identification of the Ecdysone receptor as a regulator of AMP expansion.