Summary Biofilms - communities of bacteria encased in a polymer-rich matrix- confer bacteria with the ability to persist in pathologic host contexts, such as the cystic fibrosis (CF) airways. How bacteria assemble polymers into biofilms is largely unknown. We find that the extracellular matrix produced by Pseudomonas aeruginosa self-assembles into a liquid crystal through entropic interactions between polymers and filamentous Pf bacteriophages, which are long, negatively charged filaments. This liquid crystalline structure enhances biofilm function by increasing adhesion and tolerance to desiccation and antibiotics. Pf bacteriophages are prevalent amongst P. aeruginosa clinical isolates and were detected in CF sputum. The addition of Pf bacteriophage to sputum polymers or serum was sufficient to drive their rapid assembly into viscous liquid crystals. Fd, a related bacteriophage of Escherichia coli, has similar biofilm-building capabilities. Targeting filamentous bacteriophage or the liquid crystalline organization of the biofilm matrix may represent antibacterial strategies.
The mechanisms that promote an inflammatory environment and accelerated atherosclerosis in diabetes are poorly understood. We show that macrophages isolated from two different mouse models of type 1 diabetes exhibit an inflammatory phenotype. This inflammatory phenotype associates with increased expression of long-chain acyl-CoA synthetase 1 (ACSL1), an enzyme that catalyzes the thioesterification of fatty acids. Monocytes from humans and mice with type 1 diabetes also exhibit increased ACSL1. Furthermore, myeloid-selective deletion of ACSL1 protects monocytes and macrophages from the inflammatory effects of diabetes. Strikingly, myeloid-selective deletion of ACSL1 also prevents accelerated atherosclerosis in diabetic mice without affecting lesions in nondiabetic mice. Our observations indicate that ACSL1 plays a critical role by promoting the inflammatory phenotype of macrophages associated with type 1 diabetes; they also raise the possibilities that diabetic atherosclerosis has an etiology that is, at least in part, distinct from the etiology of nondiabetic vascular disease and that this difference is because of increased monocyte and macrophage ACSL1 expression.
Pseudomonas aeruginosa is an important opportunistic human pathogen that lives in biofilm-like cell aggregates at sites of chronic infection, such as those that occur in the lungs of patients with cystic fibrosis and nonhealing ulcers. During growth in a biofilm, P. aeruginosa dramatically increases the production of filamentous Pf bacteriophage (Pf phage). Previous work indicated that when in vivo Pf phage production was inhibited, P. aeruginosa was less virulent. However, it is not clear how the production of abundant quantities of Pf phage similar to those produced by biofilms under in vitro conditions affects pathogenesis. Here, using a murine pneumonia model, we show that the production of biofilm-relevant amounts of Pf phage prevents the dissemination of P. aeruginosa from the lung. Furthermore, filamentous phage promoted bacterial adhesion to mucin and inhibited bacterial invasion of airway epithelial cultures, suggesting that Pf phage traps P. aeruginosa within the lung. The in vivo production of Pf phage was also associated with reduced lung injury, reduced neutrophil recruitment, and lower cytokine levels. Additionally, when producing Pf phage, P. aeruginosa was less prone to phagocytosis by macrophages than bacteria not producing Pf phage. Collectively, these data suggest that filamentous Pf phage alters the progression of the inflammatory response and promotes phenotypes typically associated with chronic infection.
Versican is an extracellular matrix proteoglycan produced by many cells. Although versican is generally known as a large chondroitin sulfate proteoglycan (CSPG), the smallest splice variant, V3, consists only of the amino- and carboxy-terminal globular domains and is therefore predicted to be a small glycoprotein, lacking CS chains. The large size, negative charge, and ability of versican variants to form pericellular coats with hyaluronan are responsible for many of its effects. V3, lacking the large size and high charge density, but retaining the hyaluronan-binding domain of the larger isoforms, may have different effects on cell phenotype. To determine whether V3 alters cell phenotype, Fisher rat arterial smooth muscle cells (ASMCs), which express the larger CSPG versican splice forms (V0 and V1) were retrovirally transduced with the rat V3 cDNA. Northern analysis for versican RNAs confirmed that cells transduced with V3 retrovirus, but not cells tranduced with the empty vector, expressed RNA of the size expected for V3/neo(r) bicistronic RNA. V3 overexpressing cells were more spread on tissue culture plastic, had a smaller length-to-breadth ratio and were more resistant to release from the culture dish by trypsin. Interference reflection microscopy of sparsely plated cells showed larger areas of close contact between the V3 expressing cells and the coverslip, in comparison to control cells. Focal contacts in the periphery of V3 expressing cells were larger. Growth and migration studies revealed that V3 transduced cells grow slower and migrate a shorter distance in a scratch wound assay. The increased adhesion and the inhibition of migration and proliferation resulting from V3 overexpression are the opposites of the known and predicted effects of the other variants of versican. V3 may exert these effects through changes in pericellular coat formation, either by competing with larger isoforms for hyaluronan-binding, or by altering other components of the pericellular matrix.
Abstract-Versican is an extracellular matrix (ECM) proteoglycan that is synthesized as multiple splice variants. In a recent study, we demonstrated that retroviral-mediated overexpression of the variant V3, which lacks chondroitin sulfate (CS) chains, altered arterial smooth muscle cell (ASMC) phenotype in short-term cell culture. We now report that V3-overexpressing ASMCs exhibit significantly increased expression of tropoelastin and increased formation of elastic fibers in long-term cell cultures. In addition, V3-overexpressing ASMCs seeded into ballooned rat carotid arteries continued to overexpress V3 and, at 4 weeks after seeding, produced a highly structured neointima significantly enriched in elastic fiber lamellae. In contrast to the hydrated, myxoid neointima produced by rounded or stellate vector-alonetransduced cells, V3-expressing cells produced a compact and highly ordered neointima, which contained elongated ASMCs that were arranged in parallel arrays and separated by densely packed collagen bundles and elastic fibers. These results indicate that a variant of versican is involved in elastic fiber assembly and may represent a novel therapeutic approach to facilitate the formation of elastic fibers. T he extracellular matrix (ECM) proteoglycan versican, the major chondroitin sulfate proteoglycan of vessel wall, 1 is distinguished by a central extended region with attached glycosaminoglycan (GAG) chains by an amino-terminal globular domain (G1) that binds hyaluronan (HA) and by a carboxy-terminal selectin-like domain (G3) that binds to other matrix components including tenascin-R and fibulin-1. [2][3][4][5][6] The mRNA that codes the GAG attachment region, which in the full-length form has 2 domains, can undergo differential splicing to produce 4 variants: V0, with 2 (␣ and ) GAG binding regions; V1 (with the  GAG exon); V2 (with the ␣ GAG exon); and V3 with neither GAG exon and formed from the G1 and G3 domains only. 7-9 V3 is thus predicted to be a glycoprotein and not a proteoglycan. V3 mRNA has been demonstrated in aortic tissue as well as cultures of ASMCs by Northern blot 10 and has been detected, by polymerase chain reaction (PCR), from cDNA libraries for various tissues including brain, stomach, and liver. 9 Recently, we reported that retroviral insertion and overexpression of the gene for V3 into cultured Fischer rat ASMCs induces a number of phenotypic changes. 11 Compared with vector-alone-transduced cells, V3 ASMCs are more flattened and spread, show a large increase in area of close contacts and in the size of peripheral focal contacts, increased resistance to trypsin detachment, reduced pericellular coats, and decreased rates of growth and migration. The mechanism by which V3 effects these changes is not clear, although the morphological features, the reduced growth and migration, and the reduced cell coat, raise the possibility that V3 may affect the accumulation of components of the extracellular matrix. For example, Evanko et al 12 showed recently that the V1 isoform of versican in ...
We describe a role for ECM as a biosensor for inflammatory microenvironments that plays a critical role in peripheral immune tolerance. We show that hyaluronan (HA) promotes induction of Foxp3-IL-10-producing regulatory T cells (TR1) from conventional T-cell precursors in both murine and human systems. This is, to our knowledge, the first description of an ECM component inducing regulatory T cells. Intact HA, characteristic of healing tissues, promotes induction of TR1 capable of abrogating disease in an IL-10-dependent mouse colitis model whereas fragmentary HA, typical of inflamed tissues, does not, indicating a decisive role for tissue integrity in this system. The TR1 precursor cells in this system are, suggesting that effector memory cells assume a regulatory phenotype when they encounter their cognate antigen in the context of intact HA. Matrix integrity cues might thereby play a central role in maintaining peripheral tolerance. This TR1 induction is mediated by CD44 cross-linking and signaling through p38 and ERK1/2. This induction is suppressed, also in a CD44-dependent manner, by osteopontin, a component of chronically inflamed ECM, indicating that CD44 signaling serves as a nexus for fate decisions regarding TR1 induction. Finally, we demonstrate that TR1 induction signals can be recapitulated using synthetic matrices. These results reveal important roles for the matrix microenvironment in immune regulation and suggest unique strategies for immunomodulation.
Viral infections are known to exacerbate asthma and other lung diseases in which chronic inflammatory processes are implicated, but the mechanism is not well understood. The viral mimetic, polyinosine-polycytidylic acid, causes accumulation of a versicanand hyaluronan-enriched extracellular matrix (ECM) by human lung fibroblasts with increased capacity for monocyte adhesion. The fivefold increase in versican retention in this ECM is due to altered compartmentalization, with decreased degradation of cell layerassociated versican, rather than an increase in total accumulation in the culture. This is consistent with decreased mRNA levels for all of the versican splice variants. Reduced versican degradation is further supported by low levels of the epitope, DPEAAE, a product of versican digestion by a disintegrin-like and metallopeptidase with thrombospondin type 1 motif enzymes, in the ECM. The distribution of hyaluronan is similarly altered with a 3.5-fold increase in the cell layer. Pulse-chase studies of radiolabeled hyaluronan show a 50% reduction in the rate of loss from the cell layer over 24 hours. Formation of monocyte-retaining, hyaluronidase-sensitive ECMs can be blocked by the presence of anti-versican antibodies. In comparison, human lung fibroblasts treated with the cytokines, IL1b plus TNF-a, synthesize increased amounts of hyaluronan, but do not retain it or versican in the ECM, which, in turn, does not retain monocytes. These results highlight an important role for versican in the hyaluronan-dependent binding of monocytes to the ECM of lung fibroblasts stimulated with polyinosine-polycytidylic acid.
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