SHIP represses mast cell activation and reveals that IgE alone triggers signaling pathways which enhance normal mast cell survival

The hemopoietic specific, Src homology 2-containing inositol 5' phosphatase (SHIP) hydrolyzes the phosphatidylinositol (PI)-3-kinase generated second messenger, PI-3,4,5-trisphosphate (PIP(3)), to PI-3,4-bisphosphate (PI-3,4-P(2)) in normal bone marrow derived mast cells (BMMCs). As a consequence, SHIP negatively regulates IgE+antigen (Ag)-induced degranulation as well as leukotriene and inflammatory cytokine production. Interestingly, in the absence of SHIP, BMMCs degranulate extensively with IgE alone, i.e. without Ag, suggesting that IgE alone is capable of stimulating signaling in normal BMMCs and that SHIP prevents this signaling from progressing to degranulation. To test this, we compared signaling events triggered by monomeric IgE versus IgE+Ag in normal BMMCs and found that multiple pathways are triggered by monomeric IgE alone and, while they are in general weaker than those stimulated by IgE+Ag, they are more prolonged. Moreover, while SHIP prevents this IgE-induced signalling from progressing to degranulation or leukotriene production it allows sufficient production of autocrine acting cytokines, in part by activation of NFkappaB, to enhance BMMC survival. Interestingly, the activation of NFkappaB and the level of cytokines produced are far higher with IgE than with IgE+Ag. Moreover, IgE alone maintains Bcl-X(L) levels and enhances the adhesion of BMMCs to fibronectin and this likely enhances their survival still further.     

Complex Serology and Immune Response of Mice to Variant High-Molecular-Weight O Polysaccharides Isolated from Pseudomonas aeruginosa Serogroup O2 Strains

The O antigen of the Pseudomonas aeruginosa lipopolysaccharide is the optimal target for protective antibodies, but the unusual and complex nature of their sugar substituents has made it difficult to define the range of these structures needed in an effective vaccine. Most clinical isolates of P. aeruginosa can be classified into 10 O-antigen serogroups, but slight chemical differences among O polysaccharides within a serogroup give rise to subtype epitopes. These epitopes could impact the reactivity of O-antigen-specific antibodies, as well as the susceptibility of a target strain to protective, opsonic antibodies. To define parameters of serogroup and subtype-epitope immunogenicity, antigenicity, and surface expression on P. aeruginosa cells, we prepared high-molecular-weight O-polysaccharide vaccines from strains of P. aeruginosa serogroup O2, for which eight structurally variant O antigens expressing six defined subtype epitopes (O2a to O2f) have been identified. A complex pattern of immune responses to these antigens was observed following vaccination of mice. The high-molecular-weight O polysaccharides were generally more immunogenic at low doses (1 and 10 μg) than at a high dose (50 μg) and usually elicited antibodies that opsonized the homologous strain for phagocytic killing. Some of the individual polysaccharides elicited cross-opsonic antibodies to a variable number of strains that express all of the defined serogroup O2 subtype epitopes. Combination into one vaccine of two antigens that individually elicited cross-reactive opsonic antibodies to most members of the O2 serogroup inhibited, instead of enhanced, the production of antibodies broadly reactive with most serogroup O2 subtype strains. Thus, immune responses to P. aeruginosa O antigens may be restricted to a limited range of epitopes on structurally complex O antigens, and combining multiple related antigens into a single vaccine formulation may inhibit the production of those antibodies best able to protect against most P. aeruginosa strains within a given O-antigen serogroup.It has been established through animal and human experimentation that the lipopolysaccharide (LPS) O antigen of Pseudomonas aeruginosa is a target for protective antibodies (3, 36, 38). The studies of Knirel and colleagues (17, 19) on the chemical composition and structure of the major O-side-chain polysaccharides have provided important insights into the immunochemical properties of these antigens, but our understanding of their antigenic and immunogenic properties is incomplete. This point is highlighted by the inability to date to develop effective, LPS-specific immunotherapies for human P. aeruginosa infection (7).Results obtained with animals by using immunogens and antibodies specific to the O polysaccharides have indicated that slight chemical differences among bacterial strains with otherwise closely related O-side-chain structures can produce a complex pattern of reactions between antibodies and related antigens (13). With standard serologic methods using whole-cell agglutinations, strains of P. aeruginosa can be classified as members of one serogroup (serotype); members of each serogroup share a group-specific antigen. Further subdivision into subtypes, which correlate with structural variants determined by Knirel and colleagues (17), can be accomplished with appropriate antisera (22).To develop safe and effective O-antigen-specific P. aeruginosa vaccines, we have utilized the high-molecular-mass (>100,000-Da) fraction of O polysaccharides. These antigens are safe and immunogenic in humans and animals (13, 27, 37) and elicit protective antibodies to the strains from which they are isolated. However, in recent studies of animals immunized with a heptavalent high-molecular-weight O-polysaccharide vaccine whose individual components were isolated from single strains representative of the major serogroups causing P. aeruginosa infection, opsonic antibody responses to the group-specific antigens were not commonly elicited (13). Thus, in spite of chemical and serologic relatedness among subtype strains within a P. aeruginosa serogroup, single antigens isolated from one subtype strain do not always elicit opsonic antibodies to all of the strains within the serogroup (13). Previous results showed that a particular O antigen from a given serogroup may elicit group-specific immunity, while an O antigen from another serogroup may elicit only immunity specific to the subtype epitopes expressed on that particular O antigen.To explore this situation further and gain additional insight into the serologic diversity among P. aeruginosa LPS O antigens, we prepared high-molecular-weight O-polysaccharide immunogens from five strains of P. aeruginosa serogroup O2 that, together, express all six of the identified subtype antigens (Table ​(Table1).1). These polysaccharides were used to immunize mice, and the resultant sera were assessed by enzyme-linked immunosorbent assay (ELISA) and for opsonic killing activity. The results showed a complex interaction among the strains with regard to high-molecular-weight O-polysaccharide immunogenicity, antigenicity, serogroup and subtype epitope density, and susceptibility to opsonic killing. These findings indicate that the current serogroup classifications of P. aeruginosa are probably inadequate to define the full range of LPS antigens needed to elicit comprehensive immunity to a wide range of clinical isolates.

TABLE 1

Strains used for immunogen production, their serologic classification by subtype epitope, and chemical structures of the associated O antigens Open in a separate window^aBoldface type indicates a feature of a structure that distinguishes it from a related structure of the same serogroup. Abbreviations: FucNAc, 2-acetamido-2,6-dideoxygalactose (N-acetylfucosamine); Man(NAc)₂A, 2,3-diacetamido-2,3-dideoxymannuronic acid; Man(2NAc3N)A, 2-acetamido-3-acetamidino-2,3-dideoxymannuronic acid; Gul(NAc)₂A, 2,3-diacetamido-2,3-dideoxyguluronic acid. ^bThe lower structure is also part of the O antigen of strain 170007; there is about a 2:1 ratio of the upper and lower structures.      

Association between platelet endothelial cellular adhesion molecule 1 (PECAM-1/CD31) polymorphisms and acute myocardial infarction: a study in patients from Sicily.

Adhesion of circulating cells to the arterial surface is among the first detectable events in atherogenesis. Cellular adhesion molecules, expressed by the vascular endothelium and by circulating leucocytes, mediate cell recruitment and their transendothelial migration. Platelet endothelial cellular adhesion molecule 1 (PECAM-1/CD31), involved in this migration, has been associated with the developmental course of atherosclerosis. A few studies have investigated an association between coronary heart disease and single nucleotide polymorphisms (SNPs) located in functionally important domains of the PECAM-1/CD31 gene. In particular, Ser563Asn and Gly670Arg SNPs have been described as susceptibility factors involved in acute myocardial infarction (AMI) in the Japanese male population. To confirm these observations, we studied 96 male patients (mean age 40 years; age range 20-46) affected by AMI and 118 healthy male controls (mean age 38 years, age range: 20-55), and analysed for the following PECAM-1/CD31 SNPs: Val125Leu, Asn563Ser and Gly670Arg. The frequency of the Gly670Arg polymorphism was significantly higher in patients with AMI (58.9% vs. 48.3%; P = 0.019), whereas the frequencies of the other two SNPs (Leu125Val and Ser563Asn) were not significantly different between patients and controls. By comparing the observed number of 670Arg/Arg genotypes in the patients with the expected number, calculated from the allele frequency in a healthy population, a significance of P = 0.02 (odds ratio, 2.04; 95% CI: 1.1-3.7) was obtained, supporting a recessive model of inheritance. Hence, the differences between patients and controls are significant, but relatively small. However, as AMI is a multifactorial disease, any single mutation will only provide a small or modest contribution to the risk, which also depends on environmental interaction. All in all, we believe that the results of the present study would add support to the role of pro/anti-inflammatory genotypes in determining susceptibility or resistance to immune-inflammatory diseases, including atherosclerosis.     

Genetic determinants: is there an "atherosclerosis gene"?

It is now clear that atherosclerotic disease is a chronic inflammatory disease triggered by a sequence of events initiated at sites with turbulent flow under normal conditions such as in the coronary arteries or at bifurcations or where normal laminar flow is replaced by turbulent flow because of vessel pathologies. Normally, laminar flow is protected by generation of NO by endothelial NO synthase (eNOS), which becomes activated via stretch activated channels. When the flow turns turbulent, such protective NO generation ceases, leading to endothelial cell activation and lipid deposition into the extra-cellular space. There, lipoproteins and specifically phospholipids become oxidized by cells of the monocytic-macrophage lineage. Only when the LDL-cholesterol level is high enough lipid peroxidation products are generated in sufficient amounts to perpetuate the disease by generating a feed forward loop of endothelial cell activation leading to an inflammatory response. That inflammatory response might also be added by bacterial or viral infections such as Chlamydia pneumoniae or viruses. The disease then progresses to a chronic inflammatory state, whereby the immune system seems to contribute significantly and markers of chronic inflammation such as fibrinogen, leukocytes, PAI-1 and CRP are found increased.