Immunology

Both IgA nephropathy and IgA vasculitis, formerly known as Henoch-Schӧnlein purpura, are immune deposition diseases. IgA nephropathy is caused by the deposition of aberrantly formed poly-IgA complexes from blood circulation to the kidney glomerulus; IgA vasculitis is characterized by IgA-dominant immune deposits to small vessels of the skin and other organs, including the kidney. Therefore, measuring the disease-causing poly-IgA contents in the plasma is needed to study these conditions. However, while clinical tests for the level of total plasma IgA are routinely performed, methods for specific detection of poly-IgA contents are unavailable in clinical medicine. In this protocol, we describe a practical solution for measuring poly-IgA in patient samples. The new method is based on the biological selectivity of IgA Fcα receptor I (FcαRI/CD89) toward poly-IgA species, in contrast to its relatively low affinity for normal monomeric IgA. By devising recombinant CD89 ectodomain as the “capturing” probe, we validated the feasibility of the assay for measuring plasma poly-IgA levels in a 96-well format. The methodology was able to differentiate plasma samples of IgA nephropathy, or related IgA vasculitis, from those of other autoimmune kidney disease types or from healthy controls. Moreover, the measured poly-IgA indices not only correlated with the severity of IgA nephropathy, but the levels also trended lower following corticosteroid or immunosuppressant treatments of patients. Therefore, we anticipate the new assay will provide useful measurements of the IgA nephropathy disease activity index for stratifying disease severity or for evaluating treatment response.

Graphical abstract:

The formation of neutrophil extracellular traps (NETs) is thought to play a critical role in infections and propagating sterile inflammation. Histone citrullination is an essential and early step in NETs formation, detectable prior to the formation of the hallmark extracellular DNA-scaffolded strands. In addition to the classical microscopy method, new technologies are being developed for studies of NETs and their detection, both for research and clinical purposes. Classical microscopy studies of NETs are subjective, low throughput and semi-quantitative, and limited in their ability to capture the early steps. We have developed this novel Imaging Flow Cytometry (IFC) method that specifically identifies and quantifies citrullination of histone H4 as a NETs marker and its relationship with other alterations at nuclear and cellular level. These include nuclear decondensation and super-condensation, multi-lobulated nuclei versus 1-lobe nuclei and cell membrane damage. NETs markers can be quantified following variable periods of treatment with NETs inducers, prior to the formation of the specific extracellular DNA-scaffolded strands. Because these high throughput image-based cell analysis features can be performed with statistical rigor, this protocol is suited for both experimental and clinical applications as well as clinical evaluations of NETosis as a biomarker.

Due to its particulate material, mono-sodium urate (MSU) crystals are potent activators of the NOD-like receptor NLRP3. Upon activation, NLRP3 induces the formation of inflammasome complexes, which lead to the production and release of mature IL-1β. Bioactive IL-1β is a potent activator of innate immune responses and promotes recruitment of inflammatory cells, including neutrophils from the blood into damaged/inflamed tissues. This protocol describes a method to study in vivo inflammasome activation via intraperitoneal injection of MSU crystals. MSU-injection results in a drastic increase of intraperitoneal IL-1β levels, promoting neutrophil infiltration. Early-stage neutrophil numbers correlate with the amount of released IL-1β and can be used as a read-out for the extent of in vivo inflammasome activation. In addition, this protocol might also be used as a sterile peritonitis model, to investigate mechanisms of neutrophil recruitment to the peritoneum, or as a means to obtain large numbers of in vivo activated neutrophils.

The apoptosis-associated speck-like protein with a caspase-recruitment domain (ASC) adaptor protein bridges inflammasome sensors and caspase-1. Upon inflammasome activation, ASC nucleates in a prion-like manner into a large and single platform responsible for the recruitment and the activation of caspase-1. Active caspase-1 will in turn promote the proteolytic maturation of the pro-inflammatory cytokine IL-1β. ASC oligomerization is direct evidence for inflammasome activation and its detection allows a read-out independent of caspase-1 and IL-1β. This protocol describes how to detect the oligomerization of ASC by Western blot.