Anirudh J. Ullal

Microparticles as antigenic targets of antibodies to DNA and nucleosomes in systemic lupus erythematosus

Systemic lupus erythematosus is a prototypic autoimmune disease characterized by antibodies to DNA and other nuclear molecules. While these antibodies can form immune complexes, the mechanisms generating the bound nuclear antigens are not known. These studies investigated whether microparticles can form complexes with anti-DNA and other anti-nucleosomal antibodies. Microparticles are small membrane-bound vesicles released from dead and dying cells; these particles contain a variety of cellular components, including DNA. To assess antigenicity, microparticles generated in vitro from apoptotic cell lines were tested using murine monoclonal anti-DNA and anti-nucleosomal antibodies as well as plasma from lupus patients. Antibody binding was assessed by flow cytometry. As these studies showed, some but not all of the monoclonal antibodies bound to microparticles prepared from apoptotic HL-60, THP-1 and Jurkat cells. For HL-60 cells, both staurosporine and UV radiation led to the production of antigenically active particles. For the anti-DNA antibody with high particle binding, prior treatment of DNase reduced activity. With plasma from patients with SLE, antibody binding to microparticles was present although a clear relationship with anti-DNA antibody levels was not observed. To determine whether lupus plasma contains immune complexes with particle properties, particle preparations were tested for bound IgG by flow cytometry. These studies indicated that lupus plasma contains particles with IgG binding, with numbers correlated with anti-DNA levels. Together, these findings indicate that microparticles display DNA and nucleosomal molecules in an antigenic form and could represent a source of immune complexes in SLE.

Microparticles as a source of extracellular DNA.

Microparticles are small membrane-bound vesicles that display pro-inflammatory and pro-thrombotic activities important in the pathogenesis of a wide variety of diseases. These particles are released from activated and dying cells and incorporate nuclear and cytoplasmic molecules for extracellular export. Of these molecules, DNA is a central autoantigen in systemic lupus erythematosus (SLE). As studies in our laboratory show, DNA occurs prominently in microparticles, translocating into these structures during apoptotic cell death. This DNA is antigenically active and can bind to lupus anti-DNA autoantibodies. These findings suggest that microparticles are an important source of extracellular DNA to serve as an autoantigen and autoadjuvant in SLE.

The Blood Nucleome in the Pathogenesis of SLE

Systemic lupus erythematosus (SLE) is prototypic autoimmune disease characterized by the production of autoantibodies to DNA among other nuclear molecules. These antibodies can form immune complexes that promote pathogenesis by stimulating cytokine production and depositing in the kidney to instigate nephritis. The antigens that form these complexes arise from the blood nucleome, a pool of circulating macromolecules comprised of DNA, RNA and nuclear proteins released from cells. Cell death is a major source of these molecules, releasing DNA in a process that can be modeled in mice by the administration of cells killed ex vivo. In the mouse model, the appearance of blood DNA requires macrophages and differs between males and females. This finding raises the possibility that augmented levels of extracellular DNA and other nuclear antigens can contribute to the increased frequency of SLE in females. Extracellular DNA can occur in both a soluble and particulate form, with microparticles generated in vitro displaying antigenically active DNA. Together, these findings suggest that cell death is an important event in lupus pathogenesis and can provide a supply of blood DNA essential for immune complex formation.

Use of SYTO 13, a fluorescent dye binding nucleic acids, for the detection of microparticles in in vitro systems.

Microparticles (MPs) are small membrane‐bound vesicles that are released from activated or dying cells by a blebbing process. These particles contain nuclear and cytoplasmic components and represent unique biomarkers for disease. The small size of particles, however, limits detection using flow cytometry with either light scatter or staining for surface markers. Because MPs contain DNA and RNA, we have explored the use of SYTO 13, a member of the class of SYTO dyes, for particle detection. SYTO 13 is cell permeable and has a high fluorescent yield when bound to DNA or RNA. In this study, we compared detection of MPs using either light scatter or SYTO 13 staining, testing the hypothesis that, with fluorescence detection with SYTO 13, problems of “noise” with light scatter are reduced and the range of MP sizes detected is increased. In these experiments, particles were obtained from lymphoid cell lines treated in vitro to undergo apoptosis. As these results showed, STYO 13 allowed the detection of 1.5–2.9 times as many particles as did light scatter. The increased sensitivity was observed with three different cell lines and was independent of inducing stimulus. Treatment of fixed and permeabilized MPs with DNase and RNase showed that SYTO 13 binding resulted from interaction with both DNA and RNA. Together, these findings indicate that the nucleic acid content of MPs provides the basis for their detection in in vitro systems and suggests the utility of fluorescent dyes like SYTO 13 for more sensitive quantitative assays.

The Role of Microparticles in the Pathogenesis of Rheumatoid Arthritis and Systemic Lupus Erythematosus

Microparticles (MPs) are small membrane‐bound vesicles with potent biological activities that can promote the pathogenesis of rheumatoid arthritis and systemic lupus erythematosus (SLE). These particles contain diverse cellular components and are shed from cells during apoptosis or activation. MPs can drive inflammation and autoimmunity by multiple mechanisms reflecting their content of bioactive molecules and ability to engage multiple receptor systems simultaneously. In the rheumatoid joint, particles can stimulate synovitis via their display of cytokines, chemokines, complement and angiogenesis factors. In SLE, particles can serve as an important source of extracellular nuclear molecules to signal ‘danger’ and form pathogenic immune complexes. Future studies will define the pathways by which particles promote pathogenesis, strategies to block their activity and their utility as biomarkers to assess disease activity and the response to therapy.

HMGB1 and Microparticles as Mediators of the Immune Response to Cell Death

In a wide variety of diseases, cell death represents both an outcome and an important step in pathogenesis. This duality occurs because cell death leads to the extracellular release of molecules and structures that can potently induce the innate immune system. These mediators include the alarmins which are endogenous cellular constituents that exit activated or dying cells to stimulate toll-like receptors (TLRs) as well as non-TLR receptors. Of alarmins, the nonhistone protein HMGB1 is the prototype. Like DNA and RNA, HMGB1 can translocate from cells as they die. The activity of HMGB1 may reflect its interaction with other molecules such as LPS, DNA, and cytokines. In addition to alarmins, dead and dying cells can release subcellular organelles called microparticles that contain cytoplasmic and nuclear constituents, including DNA and RNA. These particles can impact on many cell types to induce inflammation. The release of HMGB1 and microparticles shows important similarities, occurring with cell death as well as stimulation of certain but not all TLRs. Furthermore, nitric oxide can induce the release of both. These observations suggest that the products of dead cells can serve as important mediators to drive immune responses and promote inflammation and autoreactivity.

The role of antigen specificity in the binding of murine monoclonal anti-DNA antibodies to microparticles from apoptotic cells.

Antibodies to DNA (anti-DNA) are the serological hallmark of systemic lupus erythematosus and markers of underlying immune system disturbances. These antibodies bind to both single-stranded and double-stranded DNA, mediating pathogenesis by forming immune complexes. As shown recently, DNA in blood exists in both free and particulate forms, with DNA representing an important component of microparticles. Microparticles are membrane-bound vesicles containing nuclear molecules, released by membrane blebbing during cell death and activation. A panel of monoclonal NZB/NZW F1 anti-DNA antibodies was tested for binding to microparticles generated from apoptotic THP-1 and Jurkat cells. These studies showed that only certain anti-DNA antibodies in the panel, specific for double-stranded DNA, bound to microparticles. Binding to particles was reduced by soluble DNA or DNase treatment. Together, these results indicate that particle binding is a feature of only certain anti-DNA antibodies, reflecting immunochemical properties of the antibodies and the nature of the exposed DNA antigens.

The role of microparticles in the generation of immune complexes in murine lupus

Systemic lupus erythematosus is a systemic inflammatory disease characterized by antibodies to nuclear molecules in association with immune complex deposition. As shown previously, microparticles (MPs), which are small membrane-bound vesicles released from dying and activated cells, contain nucleic acids and can form immune complexes found in patient blood. To assess the role of MPs in murine lupus, we used flow cytometry to measure the presence of MPs with bound IgG in the blood of MRL-lpr/lpr and NZB/W mice. These studies showed much higher numbers of MPs with bound IgG in the blood of MRL lpr/lpr compared to NZB/W mice. Furthermore, these studies showed that antibodies from MRL-lpr/lpr mice bound better to MPs from apoptotic cells than those from NZB/W mice. Together, these studies indicate important differences in the serological features of the two strains as reflected by the capacity of antibodies to bind to MPs.