Site-directed mutagenesis of surfactant protein A reveals dissociation of lipid aggregation and lipid uptake by alveolar type II cells.

Surfactant protein A (SP-A) binds to dipalmitoylphosphatidylcholine (DPPC) and induces phospholipid vesicle aggregation. It also regulates the uptake and secretion of surfactant lipids by alveolar type II cells. We introduced the single mutations Glu195-->Gln (rE195Q), Lys201-->Ala (rK201A) and Lys203-->Ala (rK203A) for rat SP-A, Arg199-->Ala (hR199A) and Lys201-->Ala (hK201A) for human SP-A, and the triple mutations Arg197, Lys201 and Lys203-->Ala (rR197A/K201A/K203A) for rat SP-A, into cDNAs for SP-A, and expressed the recombinant proteins using baculovirus vectors. All recombinant proteins avidly bound to DPPC liposomes. rE195Q, rK201A, rK203A, hR199A and hK201A function with activity comparable to wild type SP-A. Although rR197A/K201A/K203A was a potent inducer of phospholipid vesicle aggregation, it failed to stimulate lipid uptake. rR197A/K201A/K203A was a weak inhibitor for lipid secretion and did not competed with rat [125I]SP-A for receptor occupancy. From these results, we conclude that Lys201 and Lys203 of rat SP-A, and Arg199 and Lys201 of human SP-A are not individually critical for the interaction with lipids and type II cells, and that Glu195 of rat SP-A can be replaced with Gln without loss of SP-A functions. This study also demonstrates that the SP-A-mediated lipid uptake is not directly correlated with phospholipid vesicle aggregation, and that specific interactions of SP-A with type II cells are involved in the lipid uptake process.

Reconstitution of phosphatidylserine import into rat liver mitochondria.

The synthesis translocation and decarboxylation of phosphatidylserine occurs in a cell-free system. The principal membrane components necessary are microsomes (source of phosphatidylserine synthase) and mitochondria (source of phosphatidylserine decarboxylase). The interorganelle translocation of phosphatidylserine can be measured by quantitating the decarboxylation of phosphatidyl[1'-14C]serine initially present in prelabeled microsomal membranes using a 14CO2 trapping assay. The decarboxylation of microsomal phosphatidylserine by intact mitochondria is 1) dependent upon substrate (microsomal membrane) concentration, 2) different from decarboxylation of liposomal phosphatidylserine, 3) resistant to proteases, 4) independent of soluble factors, and 5) unaffected by the addition of partially purified phospholipid exchange proteins but accelerated by purified nonspecific phospholipid exchange protein. The rate-limiting step in the reconstituted translocation-decarboxylation system is not the decarboxylation reaction but the initial translocation event between the microsomal membrane and the outer mitochondrial membrane. These data are interpreted to demonstrate that phosphatidylserine import into the mitochondria can occur via collision complexes formed between the endoplasmic reticulum or vesicles derived therefrom and the outer mitochondrial membrane.

Disruption of phosphatidylserine translocation to the mitochondria in baby hamster kidney cells.

Phosphatidylserine synthase is found predominantly in the microsomal fraction, and phosphatidylserine decarboxylase is found predominantly in the mitochondrial fraction of baby hamster kidney (BHK-21) cells. This segregation of enzymes of phosphatidylserine metabolism allows serine metabolism to phosphatidylserine and phosphatidylethanolamine to be used as an indicator of the intracellular movement of phosphatidylserine. After BHK-21 cells were pulse-labeled with [3H]serine, phosphatidylserine was efficiently labeled, and subsequently 40-50% of this radiolabeled lipid turned over to form phosphatidylethanolamine during a 7.5-h chase. Treatment of cells with NaN3 plus NaF or cycloheximide at the end of the pulse labeling period markedly inhibited the rate and extent of phosphatidylserine turnover during the chase period. The inhibition of phosphatidylserine turnover could not be attributed to inhibition of either phosphatidylserine decarboxylase or phosphatidylserine exchange protein activity. Subcellular fractionation of the BHK-21 cells demonstrated that cells poisoned with NaN3 plus NaF accumulated phosphatidylserine in the microsomal fraction relative to unpoisoned cells. The results indicate that metabolic energy is required for the transport of phosphatidylserine to the mitochondria.

The role of the amino-terminal domain and the collagenous region in the structure and the function of rat surfactant protein D.

Surfactant protein D (SP-D) is a member of the C-type lectin superfamily with four distinct structural domains: an amino terminus involved in forming intermolecular disulfides, a collagen-like domain, a neck region, and a carbohydrate recognition domain. A collagen domain deletion mutant (CDM) of SP-D was created by site-directed mutagenesis. A second variant lacking both the amino-terminal region and the collagen-like domain was generated by collagenase treatment and purification of the collagenase-resistant fragment (CRF). The CDM expressed in CHO-K1 cells formed the covalent trimers, but not the noncovalent dodecamers, typical of native SP-D. The CRF derived from recombinant SP-D formed only monomers. The CDM bound mannose-Sepharose and phosphatidylinositol (PI) as well as SP-D, but the binding to mannosyl bovine serum albumin and glucosylceramide was diminished by approximately 60%. The CRF displayed weak binding to mannose-Sepharose and PI and essentially no binding to mannosyl bovine serum albumin and glucosylceramide. Both SP-D and CDM altered the self-aggregation of PI-containing liposomes. SP-D reduced the density and the light scattering properties of PI aggregates. These results demonstrate that the collagen-like domain is required for dodecamer but not covalent trimer formation of SP-D and plays an important, but not essential, role in the interaction of SP-D with PI and GlcCer. Removal of the amino-terminal domain of SP-D along with the collagen-like domain diminishes PI binding and effectively eliminates GlcCer binding.

Altered carbohydrate recognition specificity engineered into surfactant protein D reveals different binding mechanisms for phosphatidylinositol and glucosylceramide.

Pulmonary surfactant protein D (SP-D) is a member of the collection subgroup of the C-type lectin superfamily that binds glycosylated lipids such as phosphatidylinositol (PI) and glucosylceramide (GlcCer). We have previously reported that the carbohydrate recognition domain of SP-D plays an essential role in lipid binding. However, it is unclear how the carbohydrate binding property of SP-D contributes to the lipid binding. To clarify the relationship between the lectin property and the lipid binding activity of rat SP-D, we expressed wild-type recombinant rat SP-D (rSP-D) and a mutant form of the protein with substitutions Glu-321-->Gln and Asn-323-->Asp (SP-DE321Q,N323D) in CHO-K1 cells. The indicated mutations have previously been shown to change the carbohydrate binding specificity of surfactant protein A and mannose-binding protein from mannose > galactose to the converse. rSP-D expressed in mammalian cells was essentially identical to native rat SP-D in its lipid and carbohydrate binding properties. In contrast, SP-DE321Q,N323D was unable to bind GlcCer, but retained binding activity toward PI liposomes and solid-phase PI. The efficiency of SP-DE321Q,N323D binding to PI liposome was approximately 50% of that of rSP-D in the presence of 5 mM Ca2+, but equivalent at 20 mM Ca2+. Carbohydrates competed for SP-D binding to PI such that maltose > galactose for rSP-D, and the order was reversed for SP-DE321Q,N323D. Furthermore, SP-DE321Q,N323D could bind to digalactosyldiacylglycerol more effectively than rSP-D. These results suggest the following. 1) The carbohydrate binding specificity of SP-DE321Q,N323D was changed from a mannose-glucose type to a galactose type; 2) the GlcCer binding property of SP-D is closely related to its sugar binding activity; and 3) the PI binding activity is not completely dependent on its carbohydrate binding specificity.

Alanine mutagenesis of surfactant protein A reveals that lipid binding and pH-dependent liposome aggregation are mediated by the carbohydrate recognition domain.

The carbohydrate recognition domain (CRD) of surfactant protein A (SP-A) is critical for the modulation of surfactant secretion from isolated type II cells and for the Ca(2+)-dependent aggregation of surfactant liposomes, but the domains of SP-A that mediate lipid binding have not been precisely mapped. To determine the role of the CRD in lipid interactions and other functions, the conserved amino acids of the putative Ca2+ and carbohydrate binding site (Glu195, Glu202, Asn214, Asp215) were substituted with alanine. The wild-type recombinant protein, SP-Ahyp, and mutant SP-As SP-Ahyp,E195A, SP-Ahyp,E202A, SP-Ahyp,N214A, and SP-Ahyp,D215A, were expressed in insect cells using baculovirus vectors and compared functionally. The Ca(2+)-dependent binding and aggregation of liposomes at pH 7.0 by SP-Ahyp,N214A were comparable to SP-Ahyp, but these activities were blocked in SP-Ahyp,E195A, SP-Ahyp,E202A, and SP-Ahyp,D215A. In contrast, the SP-Ahyp,D215A but not the other mutant proteins induced the Ca(2+)-independent aggregation of phospholipid liposomes at pH 4.0. The mutant recombinant proteins did not compete with 125I-labeled rat SP-A for high-affinity receptor occupancy on isolated type II cells and were much less potent than SP-Ahyp as regulators of surfactant secretion and uptake from type II cells. We conclude that (1) lipid binding and pH-dependent liposome aggregation are mediated by the CRD of SP-A, (2) distinct but overlapping domains within the CRD are required for pH- and Ca(2+)-dependent liposome aggregation, and (3) conserved acidic and polar residues of the carbohydrate binding site of SP-A are essential for interactions with type II cells.

The Cys6 intermolecular disulfide bond and the collagen-like region of rat SP-A play critical roles in interactions with alveolar type II cells and surfactant lipids.

Rat pulmonary surfactant protein A is an oligomer of 18 polypeptide chains which are associated by triple helix formation in the collagen-like domain and interchain disulfide bridges at the NH2 terminus. The roles of the intermolecular bond at Cys6 and the collagen-like domain (Gly8-Pro80) in the interactions of SP-A with phospholipids and alveolar type II cells were investigated using mutant forms of the protein. Wild type SP-A (SP-Ahyp), SP-A with the substitution Cys6 --> Ser to prevent disulfide formation (SP-Ahyp, C6S), and SP-A with the collagen-domain deleted (SP-ADeltaG8-P80) were synthesized in insect cells using recombinant baculoviruses. The SP-As were glycosylated and secreted from the invertebrate cells and the binding affinities of the wild type and mutant proteins for the mannose-Sepharose matrix used for purification were nearly identical. The SP-Ahyp and SP-ADeltaG8-P80 were at least nonameric in solution based on gel exclusion chromatography, and demonstrated extensive sulfhydryl-dependent oligomerization under nonreducing conditions. The SP-Ahyp,C6S was also oligomeric in solution and formed disulfide-dependent dimers, indicating the presence of at least one additional interchain disulfide bond. The SPADeltaG8-P80 but not the SP-Ahyp,C6S aggregated lipid vesicles at 20 degrees C and augmented the surface tension lowering effect of extracts of natural surfactant. The SP-ADeltaG8-P80 competed poorly with native SP-A for receptor occupancy on isolated alveolar type II cells and was a potent but nonspecific (concanavalin A-like) inhibitor of surfactant secretion. In contrast, the SP-Ahyp,C6S partially competed for receptor occupancy and weakly inhibited surfactant secretion in a specific manner. Neither the SP-ADeltaG8-P80 nor the SP-Ahyp,C6S supported the association of phospholipid liposomes with type II cells. We conclude that: 1) the Cys6 interchain disulfide bond of SP-A is required for aggregation of liposomes and for potent inhibition of surfactant secretion. 2) The collagen-like region is required for competition with 125I-SP-A for receptor occupancy and specific inhibition of surfactant secretion in the presence of competing sugars. 3) Both the NH2-terminal disulfide and the collagen-like region are required to enhance the association of phospholipid vesicles with type II cells.

Chimeras of surfactant proteins A and D identify the carbohydrate recognition domains as essential for phospholipid interaction.

Pulmonary surfactant proteins A (SP-A) and D (SP-D) possess similar structure as members of the mammalian C-type lectin superfamily. Both proteins are composed of four characteristic domains which are: 1) an NH2-terminal domain involved in interchain disulfide formation (denoted A1 domain for SP-A or D1 for SP-D); 2) a collagenous domain (denoted A2 or D2); 3) a neck domain (denoted A3 or D3); and 4) a carbohydrate recognition domain (denoted A4 or D4). SP-A specifically binds to dipalmitoylphosphatidylcholine, the major lipid component of surfactant, and can regulate the secretion and recycling of this lipid by alveolar type II cells. SP-D binds to phosphatidylinositol (PI) and glucosylceramide (GlcCer), and its role in alveolar lipid metabolism remains to be clarified. To understand the relationship between the structure and the function of both proteins with respect to their interaction with lipids, we expressed recombinant wild type rat SP-D (rSP-D) and chimeric molecules of SP-A and SP-D (A1A2A3D4, A1A2D3D4, and D1D2A3A4) using a baculovirus expression system, and performed lipid binding and aggregation assays. The rSP-D effectively competed with 125I-labeled native rat SP-D in a solid phase binding assay to PI and GlcCer in a manner nearly identical to native SP-D. The rSP-D also bound to PI liposomes with approximately half the affinity of native rat SP-D. Chimera A1A2D3D4 competed with iodinated SP-D in the solid phase binding assay to both PI and GlcCer. This chimera did not bind to dipalmitoylphosphatidylcholine (DPPC) liposomes or induce their aggregation. Chimera A1A2A3D4 did not bind solid phase PI or GlcCer but was equivalent to rSP-D in binding to PI liposomes. This chimera exhibited weak binding to DPPC but failed to aggregate DPPC liposomes. Chimera D1D2A3A4 failed to bind PI and GlcCer and bound weakly to DPPC liposomes but was quite effective at inducing aggregation of DPPC liposomes. These findings demonstrate that the D3 plus D4 domains of SP-D play a role in lipid binding and that the D4 domain is essential for PI binding. Furthermore, the A3 domain of SP-A cannot account for all the lipid binding activity of this protein. In addition, the results implicate the A4 domain of SP-A as an important structural domain in lipid aggregation phenomena.

Surfactant protein A amino acids Glu195 and Arg197 are essential for receptor binding, phospholipid aggregation, regulation of secretion, and the facilitated uptake of phospholipid by type II cells.

Pulmonary surfactant protein A (SP-A) is a mammalian lectin that regulates the uptake and secretion of surfactant by alveolar type II cells and is an important component of surfactant complexes. The domains of SP-A which mediate these functions have not been fully mapped. The binding of SP-A to its high affinity receptor on alveolar type II cells is thought to be dependent on a carbohydrate recognition domain (CRD), while the interaction with lipids has been attributed to the hydrophobic neck region of the molecule. To explore the role of the CRD in the interactions of SP-A with type II cells and lipids, we introduced mutations into the cDNA to encode for the substitutions Glu195-->Gln and Arg197-->Asp (SP-Ahyp,Gln195,Asp197) and expressed the mutant protein in insect (Sf9) cells using recombinant baculoviruses. Similar mutations introduced into mannose-binding protein A have been shown to switch the carbohydrate binding specificity from mannose > galactose to the converse. Wild type SP-A produced in Sf9 cells does not contain hydroxyproline (SP-Ahyp), but like rat SP-A it binds to carbohydrate affinity columns, lipids, and the SP-A receptor and is a potent inhibitor of the secretion of surfactant from type II cells (IC50 = 0.5-1.0 micrograms/ml). The SP-Ahyp,Gln195,Asp197 also bound to affinity matrices of galactose-Sepharose and mannose-Sepharose but the indicated mutations rendered the binding at least 100 times more susceptible than SP-Ahyp to competition by free galactose. The SP-Ahyp,Gln195,Asp197 did not compete with rat SP-A for occupancy of its high affinity receptor on type II cells and the mutant protein was 25-50-fold less potent as an inhibitor of the secretion of surfactant from type II cells (IC50 = 26.0 micrograms/ml). Unlike SP-Ahyp, the inhibition of secretion of surfactant by SP-Ahyp,Gln195,Asp197 was reversed by 0.25 M alpha-methylmannoside or galactose. In addition, the SP-Ahyp,Gln195,Asp197 bound avidly to phospholipid but did not aggregate vesicles or augment the uptake of phospholipid into type II cells. We conclude that the binding of SP-A to its receptor and the inhibition of surfactant secretion are critically dependent on the carbohydrate binding specificity of the CRD. Furthermore, phospholipid aggregation and augmentation of phospholipid uptake into type II cells are mediated by the COOH-terminal region of SP-A by a mechanism that is distinct from phospholipid binding.