Protein tyrosine nitration of 15-hydroxy prostaglandin dehydrogenase in the human mast cell line LAD2.

Mast cells (MC) play a pivotal role in allergic inflammation and nitric oxide (NO) is known to regulate MC function. One mechanism of NO mediated actions is the post-translational modification protein tyrosine nitration mediated by reactive nitrogen species. In this study we identified targets for nitration in the human mast cell line LAD2 after treatment with a nitric oxide donor and with peroxynitrite. Using two dimensional gel electrophoresis and western blot analyses with monoclonal and polyclonal antibodies we identified 15-hydroxy prostaglandin dehydrogenase (PGDH), a major prostaglandin catabolizing enzyme, as a target for nitration in LAD2. This is the first report on expression of this enzyme in MC and also the first report that PGDH is a target of protein tyrosine nitration. Since MC synthesize and metabolize many prostaglandins including prostaglandin E(2), the major substrate for PGDH, nitration of this prostaglandin catabolizing enzyme is likely functionally significant.

Protein tyrosine nitration of aldolase in mast cells: a plausible pathway in nitric oxide-mediated regulation of mast cell function.

NO is a short-lived free radical that plays a critical role in the regulation of cellular signaling. Mast cell (MC)-derived NO and exogenous NO regulate MC activities, including the inhibition of MC degranulation. At a molecular level, NO acts to modify protein structure and function through several mechanisms, including protein tyrosine nitration. To begin to elucidate the molecular mechanisms underlying the effects of NO in MCs, we investigated protein tyrosine nitration in human MC lines HMC-1 and LAD2 treated with the NO donor S-nitrosoglutathione. Using two-dimensional gel Western blot analysis with an anti-nitrotyrosine Ab, together with mass spectrometry, we identified aldolase A, an enzyme of the glycolytic pathway, as a target for tyrosine nitration in MCs. The nitration of aldolase A was associated with a reduction in the maximum velocity of aldolase in HMC-1 and LAD2. Nuclear magnetic resonance analysis showed that despite these changes in the activity of a critical enzyme in glycolysis, there was no significant change in total cellular ATP content, although the AMP/ATP ratio was altered. Elevated levels of lactate and pyruvate suggested that S-nitrosoglutathione treatment enhanced glycolysis. Reduced aldolase activity was associated with increased intracellular levels of its substrate, fructose 1,6-bisphosphate. Interestingly, fructose 1,6-bisphosphate inhibited IgE-mediated MC degranulation in LAD2 cells. Thus, for the first time we report evidence of protein tyrosine nitration in human MC lines and identify aldolase A as a prominent target. This posttranslational nitration of aldolase A may be an important pathway that regulates MC phenotype and function.

CD8 alpha is expressed by human monocytes and enhances Fc gamma R-dependent responses.

BACKGROUND: CD8 alpha enhances the responses of antigen-specific CTL activated through TCR through binding MHC class I, favoring lipid raft partitioning of TCR, and inducing intracellular signaling. CD8 alpha is also found on dendritic cells and rat macrophages, but whether CD8 alpha enhances responses of a partner receptor, like TCR, to activate these cells is not known. TCR and FcR, use analogous or occasionally interchangeable signaling mechanisms suggesting the possibility that CD8 alpha co-activates FcR responses. Interestingly, CD8 alpha+ monocytes are often associated with rat models of disease involving immune-complex deposition and FcR-mediated pathology, such as arthritis, glomerulonephritis, ischaemia, and tumors. While rat macrophages have been shown to express CD8 alpha evidence for CD8 alpha expression by mouse or human monocytes or macrophages was incomplete. RESULTS: We detected CD8 alpha, but not CD8 beta on human monocytes and the monocytic cell line THP-1 by flow cytometry. Reactivity of anti-CD8 alpha mAb with monocytes is at least partly independent of FcR as anti-CD8 alpha mAb detect CD8 alpha by western blot and inhibit binding of MHC class I tetramers. CD8 alpha mRNA is also found in monocytes and THP-1 suggesting CD8 alpha is synthesized by monocytes and not acquired from other CD8 alpha+ cell types. Interestingly, CD8 alpha from monocytes and blood T cells presented distinguishable patterns by 2-D electrophoresis. Anti-CD8 alpha mAb alone did not activate monocyte TNF release. In comparison, TNF release by human monocytes stimulated in a FcR-dependent manner with immune-complexes was enhanced by inclusion of anti-CD8 alpha mAb in immune-complexes. CONCLUSION: Human monocytes express CD8 alpha. Co-engagement of CD8 alpha and FcR enhances monocyte TNF release, suggesting FcR may be a novel partner receptor for CD8 alpha on innate immune cells.

Role of nitric oxide in mast cells: controversies, current knowledge, and future applications.

Mast cells (MC) are important effector cells in allergic disorders. Recently, the role of MC in innate and adaptive immunity is gaining prominence. Nitric oxide is an important signaling molecule and its production in mast cell has been reported widely. However, controversy exists about whether MC produce NO. This review addresses the role of NO in MC biology and the reasons behind the controversy and discusses effects of NO in regulation of MC phenotype and function.