FcγRIIIa-Syk Co-signal Modulates CD4+ T-cell Response and Up-regulates Toll-like Receptor (TLR) Expression.

CD4(+) T-cells in systemic lupus erythematosus (SLE) patients show altered T-cell receptor signaling, which utilizes Fc-receptor γ-chain FcRγ-Syk. A role for FcγRIIIa activation from immune complex (IC) ligation and sublytic terminal complement complex (C5b-9) in CD4(+) T-cell responses is not investigated. In this study, we show that the ICs present in SLE patients by ligating to FcγRIIIa on CD4(+) T-cells phosphorylate Syk and provide a co-stimulatory signal to CD4(+) T-cells in the absence of CD28 signal. This led to the development of pathogenic IL-17A(+) and IFN-γ(high) CD4(+) T-cells in vitro. Cytokines IL-1ß, IL-6, TGF-ß1, and IL-23 were the only requirement for the development of both populations. SLE patients CD4(+) T-cells that expressed CD25, CD69, and CD98 bound to ICs showed pSyk and produced IFN-γ and IL-17A. This FcγRIIIa-mediated co-signal differentially up-regulated the expression of IFN pathway genes compared with CD28 co-signal. FcγRIIIa-pSyk up-regulated several toll-like receptor genes as well as the HMGB1 and MyD88 gene transcripts. ICs co-localized with these toll-like receptor pathway proteins. These results suggest a role for the FcγRIIIa-pSyk signal in modulating adaptive immune responses.

Glomerulopatías C3. Una nueva perspectiva en enfermedades glomerulares / C3 Glomerulopathies. A new perspective on glomerular diseases

El término glomerulonefritis membranoproliferativa denota un patrón general de daño glomerular fácilmente reconocido por microscopía óptica. Con estudios adiciones de microscopía electrónica e inmunofluorescencia, la clasificación en subgrupos es posible. El estudio por microscopía electrónica resuelve las diferencias según la localización de los depósitos electrodensos, mientras que la inmunofluorescencia detecta la composición de los depósitos electrodensos. La glomerulopatía C3 es una entidad descrita de forma reciente, una glomerulonefritis proliferativa (normalmente, pero no siempre), con un patrón de glomerulonefritis membranoproliferativa en la microscopía óptica y con depósitos de C3 aislados en el estudio de inmunofluorescencia, implicando una hiperactividad de la vía alternativa del complemento. La evaluación de un paciente con glomerulopatía C3 debe centrarse en la cascada del complemento, en la desregulación de la vía alternativa del complemento y en la cascada terminal del complemento. Aunque no hay actualmente tratamientos específicos para las glomerulopatías C3, una mejor comprensión de la patogénesis sentaría las bases para el posible uso de drogas anticomplemento como terapia de elección, como el eculizumab. En la presente revisión, se resume la patogenia de las glomerulopatías C3, centrándonos en el papel del complemento, las series de casos recientemente publicados y las opciones terapéuticas hasta el momento actual (AU)

Membranoproliferative glomerulonephritis (MPGN) denotes a general pattern of glomerular injury that is easily recognized by light microscopy. With additional studies, MPGN subgrouping is possible. For example, electron microscopy resolves differences in electron-dense deposition location, while immunofluorescence typically detects the composition of electron-dense deposits. A C3 glomerulopathy (C3G) is a recently described entity, a proliferative glomerulonephritis (usually but not always), with a MPGN pattern on light microscopy, with C3 staining alone on inmunoflouresencie, implicating hyperactivity of the alternative complement pathway. The evaluation of C3G should focus on the complement cascade, as dysregulation of the alternative pathway and terminal complement cascade underlies pathogenesis. Although there are no specific treatments currently available for C3G, a better understanding of their pathogenesis would set the stage for the possible use of anti-complement drugs, as eculizumab. In this review, we summarise the pathogenesis of the C3 glomerulopathies, focusing on the role of complement, the patient cohorts recently reported and options of treatment up to the current moment (AU)

Terminal complement complexes concomitantly stimulate proliferation and rescue of Schwann cells from apoptosis.

The consequences of sublytic terminal complement complex (TCC) assembly on Schwann cell proliferation and apoptosis were examined by using purified complement proteins (C5*-9) or antibody-sensitized Schwann cells in the presence of a serum that was depleted of the seventh component of complement (C7dHS) and reconstituted with purified C7. Stimulation of cultured Schwann cells with antibody plus 10% C7dHS and C7 or C5*-9 induced DNA synthesis over antibody plus 10% C7dHS alone or in Schwann cells in which C5*-9 insertion was inhibited by heat inactivation, respectively. Cell cycle analysis with propidium iodide showed that, at 24 h, viable Schwann cells in defined medium were synchronized in G1/G0 phase. C5*-9 shifted 64% of these cells into S or G2/M phases in a manner similar to beta-neuregulin (beta-NRG), a known Schwann cell mitogen. Furthermore, antibody with 10% C7dHS and C7 or purified C5*-9 induced proliferation of viable Schwann cells. These effects were mediated by signal-transduction pathways involving p44 ERK1 (extracellular-regulated kinase 1), Gi proteins, and protein kinase C. Culturing in defined medium for 24 h resulted in apoptosis of up to 50% of Schwann cells that was prevented by treatment with beta-NRG or TCC. Sublytic C5*-9 significantly inhibited apoptosis 41% by 24 h, as determined by a terminal deoxyuridine triphosphate-biotin nick end labeling assay, and also decreased annexin-V binding at 4 h. Collectively, these data suggest that sublytic TCC, like beta-NRG, is a potent Schwann cell trophic factor that is capable of stimulating mitogenesis and apoptotic rescue. TCC assembly on Schwann cells during inflammatory demyelination of peripheral nerves may promote survival of mature cells to enhance repair and remyelination processes.

Characterization of soluble terminal complement complex assembled in C8beta-deficient plasma and serum.

Sera genetically deficient in either the alpha-gamma or the beta-subunit of complement component C8 virtually lack haemolytic activity. We have studied the formation and the structural organization of the soluble terminal complement complex (TCC) assembled in these sera following activation with cobra venom factor (CVF). The TCC concentration in the activated C8alpha-gamma and C8beta-deficient samples was 0.2% and 4%, respectively, when compared with zymosan-activated normal serum. TCC was purified from the activated C8beta-deficient samples by affinity chromatography and analysed by immunoblotting and enzyme immunoassay. No C8beta was detected in one TCC preparation, while 7% of the normal level was present in the other. The level of the other terminal components, including that of C8alpha-gamma, was normal. The ability of C8alpha-gamma to promote the assembly of TCC in the presence of a limited amount of C8beta or in the apparent absence of this subunit was confirmed using purified components, by mixing C5b6 and either of the purified C8 subunits together with C7 and C9. These data show that soluble TCC can be formed in C8beta-deficient sera that contain little or no C8beta.

Terminal components of carp complement constituting a membrane attack complex.

The membrane attack complex (MAC) of carp complement was extracted with deoxycholate from rabbit erythrocytes lysed by carp serum and purified by a two-step chromatographic procedure. On two-dimensional SDS-PAGE of carp MAC, eight bands were detected. The band of M(r) 91,000 was identified as carp C9 by western blotting using anti-carp C9, and two bands of M(r) 62,000 and one band of M(r) 22,000 were confirmed as those of carp C8 alpha, C8 beta and C8 gamma, respectively, by their N-terminal amino acid sequences. The bands of M(r) 102,000 and 73,000, which generated from a 180,000 band under reducing conditions, were those corresponding to human C5b alpha and C5b beta, respectively. The remaining bands of M(r) 115,000 and 106,000 were identified as those corresponding to human C6 and C7, as determined by their molecular size, single-chain structures and similarities in N-terminal amino acid sequences to their mammalian counterparts. Densitometric scan of the gels showed the molar ratio of C5b, C6, C7, C8 and C9 in carp MAC to be 1:1:1:1:4. Based on these results, it appears that, as with mammals, the cytolytic pathway of bony fish complement is composed of five terminal components from C5 to C9.

Eosinophilia myalgia syndrome: absence of immunoglobulin reactivity suggests a cellular rather than humoral mechanism.

The idiopathic disorder Eosinophilia Myalgia Syndrome (EMS), characterized by peripheral eosinophilia, myalgia and frequently fasciitis, can be triggered by ingestion of some commercial preparations of L-Tryptophan. Activated T-lymphocytes and macrophages are involved in the pathogenesis of EMS. We investigated immunohistochemically the potential role of immunoglobulins and of the terminal C5b-9 complement factor (membrane attack complex) in EMS. We found no evidence for direct involvement of immunoglobulins. However, membrane attack complex immunoreactivity was present in vessel walls in EMS, but completely absent in controls. These observations suggest that the fasciitis in EMS involves a cellular rather than a humoral reaction and that complement activation could be of importance.

Formation of ion-conducting channels by the membrane attack complex proteins of complement.

The effects of sequential additions of purified human complement proteins C5b-6, C7, C8, and C9 to assemble the C5b-9 membrane attack complex (MAC) of complement on electrical properties of planar lipid bilayers have been analyzed. The high resistance state of such membranes was impaired after assembly of large numbers of C5b-8 complexes as indicated by the appearance of rapidly fluctuating membrane currents. The C5b-8 induced conductance was voltage dependent and rectifying at higher voltages. Addition of C9 to membranes with very few C5b-8 complexes caused appearance of few discrete single channels of low conductance (5-25 pS) but after some time very large (greater than 0.5 nS) jumps in conductance could be monitored. This high macroscopic conductance state was dominated by 125-pS channels having a lifetime of approximately 1 s. The high conductance state was not stable and declined again after a period of 1-3 h. Incorporation of MAC extracted from complement-lysed erythrocytes into liposomes and subsequent transformation of such complexes into planar bilayers via an intermediate monolayer state resulted in channels with characteristics similar to the ones produced by sequential assembly of C5b-9. Comparison of the high-conductance C5b-9 channel characteristics (lifetime, ion preference, ionic-strength dependence) with those produced by poly(C9) (the circular or tubular aggregation product of C9) as published by Young, J.D.-E., Z.A. Cohn, and E.R. Podack. (1986. Science [Wash. DC]. 233:184-190.) indicates that the two are significantly different.

Evasion of Yersinia enterocolitica serotype 03 from complement-mediated killing.

Using isogenic strains of Y. enterocolitica serotype 03 (isolate 75) differing in LPS side chains (S and R), plasmid content (p+ and p-) or selective failure of YOP1 expression (YOP1-) we observed comparable C9 consumption via the alternative pathway by all strains. Differences became apparent in the bactericidal assays in which the 75S p+ strain was resistant whereas the plasmid-negative S and R strains were killed. Increased but submaximal resistance was observed with the 75R p+ and 75S YOP1- strains indicating that LPS side chains and plasmid-encoded factors other than YOP1 also contribute to serum resistance. Deposition of C9 and terminal complement complex (TCC) formation were greatly reduced on the resistant 75S p+ strain compared to the sensitive 75S p- strain. The 75S YOP1- variant behaved like the 75S p- strain with respect to C9 deposition and TCC formation suggesting that YOP1 prevents terminal C activation. A comparison of TCC deposited on resistant and sensitive Y. enterocolitica revealed no differences with respect to their salt- and protease-resistance and their size. We conclude from our experiments that serum resistance of 75S p+ depends on several surface components YOP1 being the most important. The YOP1 protein clearly interferes with C9 deposition and TCC formation and thereby contributes to serum resistance of plasmid-positive, YOP1 expressing Y. enterocolitica.