Assessing Antigen-Specific T Cell Responses Through IFN-γ Enzyme-Linked Immune Absorbent Spot (ELISpot).

T cells are instrumental in protecting the host against invading pathogens and the development of cancer. To do so, they produce effector molecules such as granzymes, interleukins, interferons, and perforin. For the development and immunomonitoring of therapeutic applications such as cell-based therapies and vaccines, assessing T cell effector function is paramount. This can be achieved through various methods, such as 51Cr release assays, flow cytometry, and enzyme-linked immune absorbent spot (ELISpot) assays. For T cell ELISpots, plates are coated with antibodies directed against the effector molecule of interest (e.g., IFN-g). Subsequently, peripheral blood mononuclear cells (PBMCs) or isolated T cells are cultured on the plate together with stimuli of choice, and the production of effector molecules is visualized via labeled detection antibodies. For clinical studies, ELISpot is currently the gold standard to determine antigen-specific T cell frequencies. In contrast to 51Cr release assays, ELISpot allows for the exact enumeration of responding T cells, and compared to flow cytometry, ELISpot is more cost-effective and high throughput. Here, we optimize and describe, in a step-by-step fashion, how to perform a controlled IFN-γ ELISpot experiment to determine the frequency of responding or antigen-specific T cells in healthy human volunteers. Of note, this protocol can also be employed to assess the frequency of antigen-specific T cells induced in, e.g., vaccination studies or present in cellular products.

ELISA to measure neutralizing capacity of anti-C1-inhibitor antibodies in plasma of angioedema patients.

BACKGROUND: Neutralizing autoantibodies (NAbs) against plasma serpin C1-inhibitor (C1-inh) are implicated in the rare disorder, acquired angioedema (AAE). There is insufficient understanding of the process of antibody formation and its correlation with disease progression and severity. We have developed an ELISA for detecting neutralizing capacity of anti-C1-inh positive plasma samples that can be used to study changes in NAb repertoire in patient plasma over the course of disease. METHODS: The ELISA is based on the specific interaction of active C1-inh with its target protease C1s. Decrease in the amount of C1s bound to immobilized C1-inh in the presence of test samples is proportional to the neutralizing capacity of the sample. Assay specificity, intra- and inter-assay variation and assay cut-off are determined using anti-C1-inh antibodies. Assay capability is demonstrated using plasma samples from AAE patients. RESULTS: The assay is specific to a neutralizing anti-C1-inh antibody and shows no interference by a non-neutralizing anti-C1-inh antibody or by the plasma matrix. Intra-assay and inter-assay variations are determined as 17 and 18% respectively. Neutralizing capacity of antibody positive AAE patient plasma samples (n=16) with IgG or IgM type antibodies is readily determined. All samples show positive neutralizing capacity. CONCLUSION: We have developed a robust, specific and semi-quantitative assay to detect the neutralizing capacity of plasma samples containing anti-C1-inh antibodies. This assay can be an important tool for the study of clinical implications of anti-C1-inh NAbs.

Nucleosome-releasing factor: a new role for factor VII-activating protease (FSAP).

Plasma proteins such as early complement components and IgM are involved in the removal of late apoptotic or secondary necrotic (sn) cells. We have recently described how a plasma protease that could be inhibited by the protease inhibitor aprotinin was essential to remove nucleosomes from sn cells. An obvious candidate, plasmin, did indeed have nucleosome-releasing factor (NRF) activity. However, recalcified plasma (r-plasma) retained its NRF activity after plasminogen depletion, which suggests the existence of another protease responsible for NRF activity in plasma. In this study we have used size-exclusion and anion-exchange chromatography to purify the protease responsible for NRF activity in plasma. SDS-PAGE analysis of chromatography fractions containing NRF activity revealed a protein band corresponding with NRF activity. Sequence analysis showed this band to be factor VII-activating protease (FSAP). We developed monoclonal antibodies to FSAP and were able to completely inhibit NRF activity in plasma with monoclonal antibodies to FSAP. Using affinity chromatography we were able to purify single-chain (sc) FSAP from r-plasma. Purified scFSAP efficiently removes nucleosomes from sn cells. We report that factor VII-activating protease may function in cellular homeostasis by catalyzing the release of nucleosomes from secondary necrotic cells.

A plasma nucleosome releasing factor (NRF) with serine protease activity is instrumental in removal of nucleosomes from secondary necrotic cells.

We observed that interaction of secondary necrotic (sn) cells with human serum or plasma leads to loss of DNA staining. The decrease turned out to be a result of nucleosome release and was specific for apoptotic cells as necrotic cells did not show this phenomenon. We named this activity in plasma nucleosome releasing factor (NRF). NRF activity was completely inhibited by trypsin inhibitors suggesting that a serine protease is involved. Upon testing a number of plasma candidate serine proteases we found that plasmin did have NRF activity. However, plasminogen-deficient plasma still had NRF activity indicating that NRF is not plasmin. We conclude that a yet unidentified plasma serine protease is involved in removal of nucleosomes from sn cells.

Complement activation by apoptotic cells occurs predominantly via IgM and is limited to late apoptotic (secondary necrotic) cells.

Apoptotic cells activate complement via various molecular mechanisms. It is not known which of these mechanisms predominate in a physiological environment. Using Jurkat cells as a model, we investigated complement deposition on vital, early and late apoptotic (secondary necrotic) cells in a physiological medium, human plasma, and established the main molecular mechanism involved in this activation. Upon incubation with recalcified plasma, binding of C3 and C4 to early apoptotic cells was similar to background binding on vital cells. In contrast, late apoptotic (secondary necrotic) cells consistently displayed substantial binding of C4 and C3 and low, but detectable, binding of C1q. Binding of C3 and C4 to the apoptotic cells was abolished by EDTA or Mg-EGTA, and also by C1-inhibitor or a monoclonal antibody that inhibits C1q binding, indicating that complement fixation by the apoptotic cells was mainly dependent on the classical pathway. Late apoptotic cells also consistently bound IgM, in which binding significantly correlated with that of C4 and C3. Depletion of plasma for IgM abolished most of the complement fixation by apoptotic cells, which was restored by supplementation with purified IgM. We conclude that complement binding by apoptotic cells in normal human plasma occurs mainly to late apoptotic, secondary necrotic cells, and that the dominant mechanism involves classical pathway activation by IgM.