Single-Cell Analysis of Cytokine mRNA and Protein Expression by Flow Cytometry.

Understanding how immune cells respond to external stimuli such as pathogens or drugs is a key component of biomedical research. Critical to the immune response are the expression of cell-surface receptors and the secretion of cytokines, which are tightly regulated by gene expression and protein synthesis. Previously, cytokine mRNA expression levels have been measured from bulk analysis of heterogeneous or sorted cell populations, and the correlation between cytokine mRNA expression and protein levels using these techniques can be highly variable. Flow cytometry is used to monitor changes in cell-surface and intracellular proteins, but some proteins such as cytokines may be transient and difficult to measure. Thus, a flow cytometry method that can simultaneously measure cytokine mRNA and protein levels in single cells is a very powerful tool. We defined a flow cytometry method that combines the conventional measurement of T cell surface proteins (CD45, CD3, CD4, CD8) and intracellular cytokines (IL-2, INF-γ) with fluorescent in situ hybridization and branched DNA technology for amplification and detection of IL-2 and INF-γ mRNA transcripts in activated T cells. This method has been applied to frozen peripheral mononuclear blood cells (PBMCs) and frozen blood samples, making it applicable to clinical trial specimens that require shipment to the test site. In CD4+ cells from activated PBMCs, the concordance between mRNA and protein levels was 41% for IL-2 and 21% for and INF-γ. In CD8+ cells from activated PBMCs, the concordance was 15% for IL-2 and 32% for INF-γ. © 2020 by John Wiley & Sons, Inc. Basic Protocol: Detection of IL-2 and IFN-γ mRNA and protein expression in frozen PBMCs Alternate Protocol: Detection of IL-2 and IFN-γ mRNA and protein expression in frozen blood.

Biological Characterization of a Stable Effector Functionless (SEFL) Monoclonal Antibody Scaffold in Vitro.

The stable effector functionLess (SEFL) antibody was designed as an IgG1 antibody with a constant region that lacks the ability to interact with Fcγ receptors. The engineering and stability and pharmacokinetic assessments of the SEFL scaffold is described in the accompanying article (Jacobsen, F. W., Stevenson, R., Li, C., Salimi-Moosavi, H., Liu, L., Wen, J., Luo, Q., Daris, K., Buck, L., Miller, S., Ho, S-Y., Wang, W., Chen, Q., Walker, K., Wypych, J., Narhi, L., and Gunasekaran, K. (2017) J. Biol. Chem 292). The biological properties of these SEFL antibodies were assessed in a variety of human and cynomolgus monkey in vitro assays. Binding of parent molecules and their SEFL variants to human and cynomolgus monkey FcγRs were evaluated using flow cytometry-based binding assays. The SEFL variants tested showed decreased binding affinity to human and cynomolgus FcγRs compared with the wild-type IgG1 antibody. In addition, SEFL variants demonstrated no antibody-dependent cell-mediated cytotoxicity in vitro against Daudi cells with cynomolgus monkey peripheral blood mononuclear cells, and had minimal complement-dependent cytotoxicity activity similar to that of the negative control IgG2 in a CD20+ human Raji lymphoma cell line. SEFL mutations eliminated off-target antibody-dependent monocyte phagocytosis of cynomolgus monkey platelets, and cynomolgus platelet activation in vitro These experiments demonstrate that the SEFL modifications successfully eliminated Fc-associated effector binding and functions.

Biomarkers for non-human primate type-I hypersensitivity: antigen-specific immunoglobulin E assays.

Immunoglobulin E (IgE) is the least abundant immunoglobulin in serum. However, development of an IgE immune response can induce IgE receptor-expressing cells to carry out potent effector functions. A reliable antigen-specific IgE biomarker method for use in non-human primate studies would facilitate (i) confirmation of Type-I hypersensitivity reactions during safety toxicology testing, and (ii) a better understanding of non-human primate models of allergic disease. We cloned and expressed a recombinant cynomolgus monkey IgE molecule in order to screen a panel of commercially available detection reagents raised against human IgE for cross-reactivity. The reagent most reactive to cynomolgus IgE was confirmed to be specific for IgE and did not bind recombinant cynomolgus monkey IgG1-4. A drug-specific IgE assay was developed on the MSD electrochemiluminescent (ECL) platform. The assay is capable of detecting 10 ng/mL drug-specific IgE. Importantly, the assay is able to detect IgE in the presence of excess IgG, the scenario likely to be present in a safety toxicology study. Using our ECL assay, we were able to confirm that serum from cynomolgus monkeys that had experienced clinical symptoms consistent with hypersensitivity responses contained IgE specific for a candidate therapeutic antibody. In addition, a bioassay for mast cell activation was developed using CD34(+)-derived cynomolgus monkey mast cells. This assay confirmed that plasma from animals identified as positive in the drug-specific IgE immunoassay contained biologically active IgE (i.e. could sensitize cultured mast cells), resulting in histamine release after exposure to the therapeutic antibody. These sensitive assays for Type-I hypersensitivity in the NHP can confirm that secondary events are downstream of immunogenicity.

An inter-laboratory retrospective analysis of immunotoxicological endpoints in non-human primates: flow cytometry immunophenotyping.

Non-human primates may be the only relevant species for pharmacology or toxicology studies of certain biologics, due to lack of activity in other species. Flow cytometry immunophenotyping is often included as a minimally invasive adjunct to standard toxicity testing. A retrospective inter-laboratory analysis was conducted to assess counts and variability of the main cell types monitored in toxicity studies, and to provide guidance for conduct and interpretation of immunophenotyping assessments in cynomolgus monkeys. Univariate and multivariate models were developed. Study design factors influencing cell counts and variability were identified and a power analysis was performed. Pre-study and on-study counts were generally similar; longitudinal analysis showed little drift in mean counts or within-animal variability over time. Within-animal variability was lower than inter-animal variability. Gender was associated with small but significant differences in mean counts and variability. Age was associated with significant differences in variability. Immunophenotype definitions were associated with significant differences in mean counts and within-animal variability for most cell types. Power analysis for groups of 6-8 animals showed that differences of ≈50% in counts of T-cells, T-cell subsets, and B-cells compared to pre-treatment values may be detected; for NK cells and monocytes, differences of ≈60-90% may be detected. This review yields some general points to consider for immunophenotyping studies, i.e. (a) analysis of log-transformed cell count data and comparisons using each animal as its own reference will improve ability to detect changes, (b) the magnitude of change detectable given study group size should be considered, (c) multiplication of sampling timepoints during a study seems unnecessary, (d) consideration should be given to using only one gender, when applicable, to increase power while minimizing animal usage, and (e) the choice of immunophenotype has impacts on cell counts and variability.

DNA-dependent protein kinase inhibitors as drug candidates for the treatment of cancer.

Cancer presents a difficult challenge for oncologists, as there are few therapies that specifically target disease cells. Existing treatment strategies rely heavily on physical and chemical agents that nonspecifically affect DNA metabolism. To improve the effectiveness of these treatments, we have identified a new class of protein kinase inhibitor that targets a major DNA repair pathway. A representative of this class, 1-(2-hydroxy-4-morpholin-4-yl-phenyl)-ethanone, inhibits the DNA-dependent protein kinase (DNA-PK) and differs significantly from previously studied DNA-PK inhibitors both structurally and functionally. DNA-PK participates in the cellular response to and repair of chromosomal DNA double-strand breaks (DSBs). These new selective inhibitors recapitulate the phenotype of DNA-PK defective cell lines including those from SCID mice. These compounds directly inhibit the repair of DNA DSBs and consequently enhance the cytotoxicity of physical and chemical agents that induce DSBs but not other DNA lesions. In contrast to previously studied DNA-PK inhibitors, these compounds appear benign, exhibiting no toxic effects in the absence of DSB-inducing treatments. Most importantly, 1-(2-hydroxy-4-morpholin-4-yl-phenyl)-ethanone synergistically enhances radiation-induced tumor control in a mouse-human xenograft assay. These studies validate DNA-PK as a cancer drug target and suggest a new approach for enhancing the effects of existing cancer therapies.