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Query: UMLS:C0344329 (
collapse
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28,634
document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)
Pulmonary surfactant, a protein-phospholipid mixture, maintains surface tension at the lung epithelium/air interface preventing alveolar
collapse
during respiration. For mammals appropriate developmental production of surfactant is necessary for adaptation to the air breathing environment. Deficiency of pulmonary surfactant results in respiratory distress syndrome (RDS), a leading cause of death in premature infants. Recently, three lung-specific pulmonary surfactant proteins designated SP-A,
SP-B
, and SP-C have been described. Cloned sequences for the genes that encode each of these proteins have been partially characterized in humans and other species. Analysis of interspecific backcross mice has allowed us to map the chromosomal locations of these three genes in the mouse. The gene encoding SP-A (Sftp-1) and the gene encoding SP-C (Sftp-2) both map to mouse chromosome 14, although at separate locations, while the gene encoding
SP-B
(Sftp-3) maps to chromosome 6. The mouse map locations determined in this study for the Sftp genes are consistent with the locations of these genes on the human genetic map and the syntenic relationships between the human and the mouse genomes.
...
PMID:Chromosomal localization of three pulmonary surfactant protein genes in the mouse. 134 79
Pulmonary surfactant proteins,
SP-B
and SP-C, if present in preformed monolayers can induce lipid insertion from lipid vesicles into the monolayer after the addition of (divalent) cations [Oosterlaken-Dijksterhuis, M. A., Haagsman, H. P., van Golde, L. M. G., & Demel, R. A. (1991) Biochemistry 30, 8276-8287]. This model system was used to study the mechanisms by which
SP-B
and SP-C induce monolayer formation from vesicles. Lipid insertion proceeds irrespectively of the molecular class, and PG is not required for this process. In addition to lipids that are immediately inserted from vesicles into the monolayer, large amounts of vesicles are bound to the monolayer and their lipids eventually inserted when the surface area is expanded.
SP-B
and SP-C are directly responsible for the binding of vesicles to the monolayer. By weight, the vesicle binding capacity of
SP-B
is approximately 4 times that of SP-C. For vesicle binding and insertion, the formation of close contacts between monolayer and vesicles is essential.
SP-B
and SP-C show very similar surface properties. Both proteins form extremely stable monolayers (
collapse
pressures 36-37 mN/m) of alpha-helical structures oriented parallel to the interface. In monolayers consisting of DPPC and
SP-B
or SP-C, an increase in mean molecular area is observed, which is mainly attributed to the phospholipid. This will greatly enhance the insertion of new lipid material into the monolayer. The results of this study suggest that the surface properties and the hydrophobic nature of
SP-B
and SP-C are important for the protein-mediated monolayer formation.
...
PMID:Characterization of lipid insertion into monomolecular layers mediated by lung surfactant proteins SP-B and SP-C. 193 22
SP-B
is a protein in pulmonary surfactant that is, in greatest part, responsible for resistance to surface tension and prevention of
collapse
of pulmonary alveoli. Peptides of 21 residues, synthesized following the sequence of
SP-B
or resembling the hydrophobic and hydrophilic domains of
SP-B
(such as RLLLLRLLLLRLLLLRLLLLR, R, Arg, and L, Leu), enhanced the abilities of phospholipids to reduce surface tension both in vitro and in vivo. Intermittent positively charged residues were essential for this activity. The
SP-B
-like peptides were found by tryptophan fluorescence to partition within the phospholipid layer in contact with both polar head groups and acyl side chains. These data, together with findings that the
SP-B
-related peptides increase inter- and intramolecular order of the phospholipid layer, suggest that
SP-B
resists surface tension by increasing lateral stability of the phospholipid layer.
...
PMID:Pulmonary surfactant protein B (SP-B): structure-function relationships. 194 32
Pulmonary surfactant prevents
collapse
of lung alveoli by lowering surface tension at the air/liquid interface. The hydrophobic surfactant associated proteins
SP-B
and SP-C have been shown to be important in surfactant function and metabolism. A cDNA clone for rat
SP-B
was isolated and sequenced. Northern analysis showed mRNA for
SP-B
was present in whole lung and was greatly enriched in alveolar type II cells, but was not present in brain, kidney, spleen or liver. A full length transcript of the rat
SP-B
cDNA clone consists of 1536 bases and encodes an open reading frame of 376 amino acids. The predicted molecular mass of the primary translation product is 42 kDa and the predicted molecular mass of the mature protein is 8 kDa. Extensive homology exists between the rat sequence for
SP-B
and those reported for human and canine
SP-B
. The position of 25 cysteine residues has been extremely well preserved across all three species. An N-linked glycosylation site in the COOH region has been conserved across all three species. A search of the NIH database revealed homology between rat
SP-B
and the active site for the mouse contrapsin serum proteinase inhibitor.
...
PMID:cDNA and deduced amino acid sequence for the rat hydrophobic pulmonary surfactant-associated protein, SP-B. 292 Jan 85
The pulmonary surfactant lines as a complex monolayer of lipids and proteins the alveolar epithelial surface. The monolayer dynamically adapts the surface tension of this interface to the varying surface areas during inhalation and exhalation. Its presence in the alveoli is thus a prerequisite for a proper lung function. The lipid moiety represents about 90% of the surfactant and contains mainly dipalmitoylphosphatidylcholine (DPPC) and phosphatidylglycerol (PG). The surfactant proteins involved in the surface tension adaption are called SP-A,
SP-B
and SP-C. The aim of the present investigation is to analyse the properties of monolayer films made from pure SP-C and from mixtures of DPPC, DPPG and SP-C in order to mimic the surfactant monolayer with minimal compositional requirement. Pressure-area diagrams were taken. Ellipsometric measurements at the air-water interface of a Langmuir film balance allowed measurement of the changes in monolayer thickness upon compression. Isotherms of pure SP-C monolayers exhibit a plateau between 22 and 25 mN/m. A further plateau is reached at higher compression. Structures of the monolayer formed during compression are reversible during expansion. Together with ellipsometric data which show a stepwise increase in film thickness (coverage) during compression, we conclude that pure SP-C films rearrange reversibly into multilayers of homogenous thickness. Lipid monolayers
collapse
locally and irreversibly if films are compressed to approximately 0.4 nm2/molecule. In contrast, mixed DPPG/SP-C monolayers with less than 5 mol% protein
collapse
in a controlled and reversible way. The pressure-area diagrams exhibit a plateau at 20 mN/m, indicating partial demixing of SP-C and DPPG.(ABSTRACT TRUNCATED AT 250 WORDS)
...
PMID:Pulmonary surfactant protein C containing lipid films at the air-water interface as a model for the surface of lung alveoli. 776 91
The most well characterized function of pulmonary surfactant is its ability to reduce surface tension at the alveolar air-liquid interface, thereby preventing lung
collapse
. However, several lines of evidence suggest that surfactant may also have 'non-surfactant' functions: specific components of surfactant (proteins and phospholipids) may interact with different alveolar cells, inhaled particles and micro-organisms modulating pulmonary host defence systems. SP-A, the most abundant surfactant protein, binds to alveolar macrophages via a specific surface receptor with high affinity [128]. Such binding effects the release of reactive oxygen species from resident alveolar macrophages if SP-A is properly presented to the target cell. SP-A also stimulates chemotaxis of alveolar macrophages [142], and serves as an opsonin in the phagocytosis of herpes simplex virus [161] Candida tropicalis [138] and various bacteria [137]. In addition, SP-A enhances the uptake of particles by monocytes and culture-derived macrophages [140] and improves bacterial killing. SP-D, another hydrophobic surfactant-associated protein, might interact with alveolar macrophages as well, stimulating the release of oxygen radicals [148], while for the hydrophilic surfactant proteins
SP-B
and SP-C no macrophage interactions have been described so far. SP-A and SP-D are members of the so-called 'collectins', pattern recognition molecules involved in first line defence. While some surfactant proteins appear to stimulate certain macrophage defence functions, surfactant phospholipids seem to inhibit those of lymphocytes. Suppressed lymphocyte functions include lymphoproliferation in response to mitogens and alloantigens, B cell immunoglobulin production and natural killer cell cytotoxicity. Concerning surfactant's phospholipid composition phosphatidylglycerol is more suppressive than phosphatidylcholine on a molar basis [38]. Bovine surfactant has an immunosuppressive effect on the development of hypersensitivity pneumonitis in a guinea pig model [150]. Despite these interesting observations, several important questions concerning the interactions of surfactant components with pulmonary host defence systems remain unanswered. Sufficient host defence in the lungs works through various humoral-cellular systems in conjunction with the specific anatomy of the airways and the gas exchange surface--how does the surfactant system fit into this network? Surfactant and alveolar cells are both altered during lung injury--is there a relationship between alveolar cells from RDS patients and the endogenous surfactant isolated from such patients? How does exogenous surfactant as used for substitution therapy modulate the defence system of the host? Some of those artificial surfactants have been shown to inhibit the endotoxin-alveolar macrophages, PMNs and monocytes including IL-1, IL-6 and TNF [139,152].(ABSTRACT TRUNCATED AT 400 WORDS)
...
PMID:Host defence capacities of pulmonary surfactant: evidence for 'non-surfactant' functions of the surfactant system. 782 30
Dynamic cyclic surface pressure (pi)-area measurements were performed on surfactant proteins
SP-B
and SP-C in pure and binary spread films with dipalmitoylphosphatidylcholine (DPPC). When the films of pure
SP-B
and SP-C were compressed beyond their
collapse
points (about 40 mN m-1), no appreciable irreversible loss of material occurred and the successive compression isotherms were reproducible. A similar reversible
collapse
for the proteins was observed when their binary films with DPPC were compressed up to high surface pressures (pi approximately 65 mN m-1), which did not surpass the
collapse
for DPPC (about 72 mN m-1). In this case,
SP-B
, squeezed out at 50 mN m-1 during compression of the
SP-B
/DPPC monolayers that contained > or = 10 weight % protein, reinserted in the films during their subsequent expansion. Likewise, SP-C-DPPC complexes were reversibly excluded at pi approximately 55 mN m-1 from the SP-C/DPPC films that contained > or = 5 weight % protein. Dynamic compression of the mixed protein-lipid films beyond the
collapse
pressure of DPPC showed that
SP-B
and SP-C improved the respreading of DPPC in a concentration dependent manner.
SP-B
was more effective in promoting the respreading of DPPC than was SP-C, as indicated by the
collapse
plateau length ratio criterion. The results from this study suggest a possible interfacial role for
SP-B
and SP-C in lipid replenishment at the alveolar-air interface, through enhancement of the respreading of DPPC
collapse
phases (
SP-B
and SP-C) or through reversible removal of phospholipid (SP-C) during dynamic cyclic compression-expansion of the alveolar surface.
...
PMID:Dynamic surface properties of pulmonary surfactant proteins SP-B and SP-C and their mixtures with dipalmitoylphosphatidylcholine. 799 94
Spread binary monolayers of surfactant-associated proteins
SP-B
and SP-C were formed at the air-water interface. Surface pressure measurements showed no interactions between the hydrophobic proteins. The effects of a mixture of
SP-B
plus SP-C (2:1, w/w) on the properties of monolayers of dipalmitoylphosphatidylcholine (DPPC), dipalmitoylphosphatidylglycerol (DPPG), and DPPC:DPPG (7:3, mol:mol) were studied. During compression of ternary and quaternary films, containing less than 0.4 mol% or 5 weight% total protein, the proteins were not squeezed out and appeared to remain associated with the film until
collapse
at surface pressures of about 65-70 mN.m-1. At initial concentrations of total protein of about 0.9 mol% or 10 weight%, exclusion of protein-lipid complexes was observed at 40-50 mN.m-1. Larger amounts of phospholipid were removed by proteins from (
SP-B
:SP-C)/DPPG films than from (
SP-B
:SP-C)/DPPC ones. Separate squeeze-out of
SP-B
(or
SP-B
plus DPPC) at about 40 mN.m-1, followed by exclusion of SP-C (or SP-C plus DPPC) at about 50 mN.m-1, was observed in (
SP-B
:SP-C)/DPPC films. This led to a conclusion that there was independent behavior of
SP-B
and SP-C in (
SP-B
:SP-C)/DPPC monolayers. The quaternary (
SP-B
:SP-C)/(DPPC:DPPG) films showed qualitatively similar process of squeeze-out of the proteins. In the ternary mixtures of
SP-B
plus SP-C with DPPG separate exclusion of
SP-B
was not detected; rather, the data was consistent with exclusion of a (
SP-B
:SP-C)/DPPG complex at about 50 mN.m-1. The results imply possible interactions between
SP-B
and SP-C and the acidic phospholipid.
...
PMID:Pulmonary surfactant proteins SP-B and SP-C in spread monolayers at the air-water interface: III. Proteins SP-B plus SP-C with phospholipids in spread monolayers. 803 87
Lung surfactant-associated protein interaction with lipid matrices and the effects on lipid thermotropic phase behavior are areas of active research. Many studies limit the lipids to a single or two-component system. The current investigation utilizes a three-lipid component matrix (DPPC:POPG:palmitic acid) to investigate the impact of a synthetic surfactant protein B fragment (
SP-B
53-78 DiACM) on the dynamic surface activity of the lipid admixture as measured by a Wilhelmy surface balance. Also, the modulation of the individual lipid acyl chain order by the peptide within the lipid matrix is studied through the use of thermal perturbation FTIR spectroscopy. The data clearly demonstrate a concentration-dependent effect of the peptide on the surface activity with an improvement in the dynamic surface tension diagram characteristics (decreased surface tension and increased
collapse
plateau) especially at low, 0.36 M%, peptide concentrations. These effects are diminished upon further addition of the peptide. FTIR spectral data demonstrate that the peptide addition results in a significant increase in the acyl chain order of the DPPC and POPG components as measured by the position of the methylene stretching vibrational bands. DPPC is most sensitive to the peptide presence, while the palmitic acid is least affected. The transition temperatures of the individual lipids are also increased with the addition of the peptide. The presence of POPG in the matrix achieves the surface activity similarly seen with natural lung surfactant relative to a DPPC/palmitic acid lipid matrix alone. Its presence increases the sensitivity of the DPPC acyl chains to the presence of the peptide. These effects on the chain order are most probably related to the increased acyl chain fluidity which POPG imparts to the lipid matrix because of the presence of the cis double bond. The phosphatidylglycerol headgroup also adds a negative charge to the lipid matrix which enhances the peptide-lipid interaction. Although the palmitic acid is minimally affected by the peptide, its presence, as suggested by surface balance measurements, results in the establishment of a stable lipid film with DPPC, capable of achieving low surface tension values.
...
PMID:Pulmonary lung surfactant synthetic peptide concentration-dependent modulation of DPPC and POPG acyl chain order in a DPPC:POPG:palmitic acid lipid mixture. 803 57
SP-B
is the protein in pulmonary surfactant with the greatest capacity to augment the phospholipids, ability to resist surface tension, and capability to prevent
collapse
of pulmonary alveoli. Synthetic peptides derived from the structure of
SP-B
and simplified analogues of these
SP-B
-derived peptides were found by tryptophan fluorescence to partition within the phospholipid layer in contact with both polar head groups and acyl side chains of the phospholipids. The intermittent hydrophilic basic residues were found to be essential for full activity, probably because of electrostatic interactions formed with phosphates of the polar head groups. The hydrophobic stretches of residues in
SP-B
and the related peptides supplement the activity through interaction with the phospholipid acyl side chains. By increasing intermolecular and intramolecular order of the phospholipid layer and thereby stability of the layer, the
SP-B
analogues provide strong surfactant activity. Simplified peptide analogues of
SP-B
, dispersed in DPPC and POPG, provide strong surfactant activity in vitro and in the lungs of premature infant rabbits, rhesus monkeys, and humans.
...
PMID:Protein-phospholipid interactions in pulmonary surfactant. The Parker B. Francis Lectureship. 813 14
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