CCL5 secreted by senescent aged fibroblasts induces proliferation of prostate epithelial cells and expression of genes that modulate angiogenesis.

There is increased interest in the effects of secretory products from aged cells on promoting both benign and malignant cell growth. We identified a human fibroblast line, AG04382, from an aged donor that naturally demonstrated senescence-associated features and whose conditioned media significantly induced proliferation of benign prostatic hyperplasia (BPH1) cells. Candidate cytokines mediating this effect were identified with protein arrays and validated by ELISA. We found that the AG04382 fibroblast line secreted high levels of CXCL5, CCL5, and CCL2, but relative to the other lines, its conditioned media was unique in its increased expression of CCL5. Blocking studies using specific antibodies against CXCL5, CCL5, and CCL2 in the conditioned media of AG04382 showed that only CCL5 contributed significantly to BPH1 proliferation. Stimulation of BPH1 cells with rhuCCL5 resulted in increased proliferation and migration, as well as significant changes in the expression of genes that influence angiogenesis. These data suggest that CCL5 is a candidate chemokine secreted by aged cells that promotes prostate growth and regulates angiogenesis.

Alternate amino terminal processing of surfactant protein A results in cysteinyl isoforms required for multimer formation.

The biological functions of rat surfactant protein A (SP-A), an oligomer composed of 18 polypeptide subunits derived from a single gene, are dependent on intact disulfide bonds. Reducible and collagenase-reversible covalent linkages of as many as six or more subunits in the molecule indicate the presence of at least two NH2-terminal interchain disulfide bonds. However, the reported primary structure of rat SP-A predicts that only Cys6 in this region is available for interchain disulfide formation. Direct evidence for a second disulfide bridge was obtained by analyses of a set of three mutant SP-As with telescoping deletions from the reported NH2-terminus. Two of the truncated recombinant proteins formed reducible dimers despite deletion of the domain containing Cys6. Edman degradation revealed that each mutant protein was a mixture of two isoforms with and without an isoleucine-lysine-cysteine (IKC) extension at the NH2-terminus, which was derived from the COOH-terminal end of the reported signal peptide. Large variations in the abundance of the IKC isoforms between truncated SP-As suggested that the amino acid sequences located downstream from the signal peptide modulated alternate-site cleavage by signal peptidase. Elution of the newly identified cysteine in the position of DiPTH-Cys indicated participation in disulfide linkage, which was interchain based on the direct correlation between prevalence of the IKC variant and the extent of dimerization for each truncated protein. Sequencing of both native rat SP-A and human SP-A also revealed isoforms with disulfide-forming NH2-terminal extensions. The extended rat SP-A isoforms were enriched in the more fully glycosylated and multimeric SP-A species separated on SDS-PAGE gels. Thus, a novel post translational modification results in naturally occurring cysteinyl isoforms of rat SP-A, which are essential for multimer formation.

Deletion mapping of N-terminal domains of surfactant protein A. The N-terminal segment is required for phospholipid aggregation and specific inhibition of surfactant secretion.

The objective of the current study was to examine the functional importance of the N-terminal domains of surfactant protein A (SP-A) including the N-terminal segment from Asn1 to Ala7 (denoted domain 1), the N-terminal portion of the collagen domain from Gly8 to Gly44 (domain 2), and the C-terminal portion of the collagen-like domain from Gly45 to Pro80 (domain 3). Wild type recombinant SP-A (SP-Ahyp; where hyp indicates hydroxyproline-deficient) and truncated mutant (TM) SP-As containing deletions of domain(s) 1 (TM1), 2 (TM2), 1 and 2 (TM1-2), and 1, 2, and 3 (TM1-2-3) were synthesized in insect cells and purified by mannose-Sepharose affinity chromatography. N-terminal disulfide-dependent dimerization was preserved at near wild type levels in the TM1-2 (at Cys-1) and TM2 proteins (at Cys-1 and Cys6), and to a lesser extent in TM1 (at Cys-1), but not in TM1-2-3. Cross-linking analyses demonstrated that the neck + CRD was sufficient for assembly of monomers into noncovalent trimers and that the N-terminal segment was required for the association of trimers to form higher oligomers. All TM proteins except TM1-2-3 bound to phospholipid, but only the N-terminal segment containing TM proteins aggregated phospholipid vesicles. The TM1, TM1-2, and TM2 but not the TM1-2-3 inhibited the secretion of surfactant from type II cells as effectively as SP-Ahyp, but the inhibitory activity of each mutant was blocked by excess alpha-methylmannoside and therefore nonspecific. TM1 and TM1-2-3 did not enhance the uptake of phospholipids by isolated type II cells, but the TM1-2 and TM2 had activities that were 72 and 83% of SP-Ahyp, respectively. We conclude the following for SP-A: 1) trimerization does not require the collagen-like region or interchain disulfide linkage; 2) the N-terminal portion of the collagen-like domain is required for specific inhibition of surfactant secretion but not for binding to liposomes or for enhanced uptake of phospholipids into type II cells; 3) N-terminal interchain disulfide linkage can functionally replace the N-terminal segment for lipid binding, receptor binding, and enhancement of lipid uptake; 4) the N-terminal segment is required for the association of trimeric subunits into higher oligomers, for phospholipid aggregation, and for specific inhibition of surfactant secretion and cannot be functionally replaced by disulfide linkage alone for these activities.

Two rat surfactant protein A isoforms arise by a novel mechanism that includes alternative translation initiation.

A single gene for rat surfactant protein A (SP-A) encodes two isoforms that are distinguished by an isoleucine-lysine-cysteine (IKC) N-terminal extension (SP-A and IKC-SP-A). Available evidence suggests that the variants are generated by alternative signal peptidase cleavage of the nascent polypeptide at a primary site (Cys(-)(1)-Asn(1)) and a secondary site (Gly(-)(4)-Ile(-)(3)). In this study, we used site-directed mutagenesis and heterologous expression in vitro and in insect cells to the examine mechanisms that may lead to alternative signal peptidase cleavage including alternative translation initiation at two in-frame AUGs (Met(-)(30) and Met(-)(20)), a suboptimal context for hydrolysis at the primary cleavage site, or cotranslational protein modifications that expose an otherwise cryptic secondary cleavage site. In vitro translation of a rat cDNA for SP-A resulted in both 28 and 29 kDa primary translation products on SDS-PAGE analysis, while translation of cDNAs encoding Met-30Ala and Met-20Ala mutations resulted in only the single 28 and 29 kDa molecular mass species, respectively. These data are consistent with translation initiation at both Met(-)(30) and Met(-)(20) during in vitro synthesis of SP-A. The Met-30Ala mutation reduced expression of the longer isoform in insect cells, indicating that the Met(-)(30) site also contributes to eucaryotic protein expression. Forcing translation initiation at Met(-)(30) by optimizing the Kozak consensus sequence surrounding that codon or by mutating the Met(-)(20) codon resulted in preferential expression of the longer SP-A isoform but reduced overall expression of the protein almost 10-fold. Both isoforms were generated to some degree whether translation was initiated at the codon for Met(-)(30) or Met(-)(20), indicating that the site of translation initiation is not the sole determinant of isoform generation and suggesting that either the context of the primary cleavage site is suboptimal or that cotranslational modifications affect cleavage. Preventing N-terminal glycosylation at Asn(1) did not affect the site of signal peptidase cleavage. Disruption of interchain disulfide formation at Cys(-)(1) by substitution with serine markedly enhanced cleavage at the Gly(-)(4)-Ile(-)(3) bond, but substitution with alanine enhanced cleavage at the Cys(-)(1)-Asn(1) bond. We conclude that rat SP-A isoforms arise by a novel mechanism that includes both alternative translation initiation at two in-frame AUGs and a suboptimal context for signal peptidase hydrolysis at the primary cleavage site.

The longer isoform and Cys-1 disulfide bridge of rat surfactant protein A are not essential for phospholipid and type II cell interactions.

Rat SP-A is a heterooligomer of two closely related isoforms, that requires interchain disulfide linkage for several functions including SP-A-mediated phospholipid vesicle aggregation and modulation of surfactant secretion and uptake by isolated alveolar type II cells. While the Cys6 disulfide bond of rat SP-A is known to be critical for function, the importance of the second interchain disulfide linkage within the N-terminal Isoleucine-3-Lysine-Cysteine-1 (IKC) sequence of the alternatively processed isoform is not clear. To examine the role of the Cys-1-dependent multimerization in SP-A function, we disrupted the Cys-1 disulfide bond by deletion of the IKC sequence (SP-Ahyp, DeltaIKC) or the substitution Cys-1 to Ser (SP-Ahyp,C-1S) in mutant recombinant proteins produced in insect cells. N-terminal sequence analyses revealed that the mutations influenced signal peptidase cleavage specificity, resulting in an increase in the abundance of the longer isoform of SP-Ahyp,C-1S and in N-terminal truncation of a fraction of the SP-Ahyp,DeltaIKC polypeptides at Gly8. On nonreducing SDS-PAGE analysis, both mutant proteins migrated as monomers and dimers but not the higher multimers that are characteristic of the wild-type recombinant protein (SP-Ahyp). Cross-linking analyses demonstrated that the association between trimeric SP-A subunits remained intact despite disruption of the Cys-1 bond. The SP-Ahyp,C-1S eluted in the same volume as SP-Ahyp from the gel sizing column with an apparent mass of 440 kDa, indicative of association of at least 9-10 monomers. The phospholipid binding and aggregation activities of the SP-Ahyp,C-1S were approximately 75% and 55% of the SP-Ahyp, respectively, but the SP-Ahyp,DeltaIKC was functionally comparable to SP-Ahyp. Similarly, both mutant proteins regulated the secretion and uptake of surfactant from isolated type II cells, but the SP-Ahyp,DeltaIKC was somewhat more potent than the SP-Ahyp,C-1S. Competitive binding to the SP-A receptor on type II cells was reduced by both Cys-1 mutations. We conclude that neither Cys-1-dependent multimerization nor the longer SP-A isoform is absolutely required for oligomeric association of trimeric SP-A subunits, SP-A/phospholipid interactions, or the regulation of surfactant secretion or uptake from type II cells by rat SP-A.

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.

Pulmonary surfactant proteins A and D are potent endogenous inhibitors of lipid peroxidation and oxidative cellular injury.

The lung is composed of a series of branching conducting airways that terminate in grape-like clusters of delicate gas-exchanging airspaces called pulmonary alveoli. Maintenance of alveolar patency at end expiration requires pulmonary surfactant, a mixture of phospholipids and proteins that coats the epithelial surface and reduces surface tension. The surfactant lining is exposed to the highest ambient oxygen tension of any internal interface and encounters a variety of oxidizing toxicants including ozone and trace metals contained within the 10 kl of air that is respired daily. The pathophysiological consequences of surfactant oxidation in humans and experimental animals include airspace collapse, reduced lung compliance, and impaired gas exchange. We now report that the hydrophilic surfactant proteins A (SP-A) and D (SP-D) directly protect surfactant phospholipids and macrophages from oxidative damage. Both proteins block accumulation of thiobarbituric acid-reactive substances and conjugated dienes during copper-induced oxidation of surfactant lipids or low density lipoprotein particles by a mechanism that does not involve metal chelation or oxidative modification of the proteins. Low density lipoprotein oxidation is instantaneously arrested upon SP-A or SP-D addition, suggesting direct interference with free radical formation or propagation. The antioxidant activity of SP-A maps to the carboxyl-terminal domain of the protein, which, like SP-D, contains a C-type lectin carbohydrate recognition domain. These results indicate that SP-A and SP-D, which are ubiquitous among air breathing organisms, could contribute to the protection of the lung from oxidative stresses due to atmospheric or supplemental oxygen, air pollutants, and lung inflammation.