Vagaries of the ELISpot assay: specific detection of antigen responsive cells requires purified CD8(+) T cells and MHC class I expressing antigen presenting cell lines.

Quantification of antigen-specific CD8(+) T cells is important for monitoring infection, vaccination, and response to therapy in cancer and immune-mediated diseases. Cytokine enzyme-linked-immunospot (ELISpot) assays are often used for this purpose. We found that substantial spot formation in IFNγ ELISpot assays occurred independently of CD8(+) T cells even when classical MHC class I restricted peptides are used for stimulation. Using fractionated cells and intracellular cytokine staining, the non-CD8(+) T cell IFNγ production was attributed to the CD4(+) T cell fraction. We therefore refined a cell line-based ELISpot assay combining HLA-A*0201 expressing K562 cells for antigen presentation with purified CD8(+) T cells and demonstrated that it specifically detected CD8(+) T cell responses with detection limits comparable to traditional ELISpot assays and dextramer-based quantification. The assay was further adapted to whole antigen responses with antigen (pre-proinsulin)-expressing HLA-A*0201K562 cells. Thus, we revealed and corrected a weak spot of the CD8(+) ELISpot assay.

A Golgi PKD activity reporter reveals a crucial role of PKD in nocodazole-induced Golgi dispersal.

The protein kinase D (PKD) family comprises multifunctional serine/threonine-specific protein kinases with three mammalian isoforms: PKD1, PKD2 and PKD3. A prominent PKD function is the regulation of basolateral-targeted transport carrier fission from the trans-Golgi network (TGN). To visualize site-specific PKD activation at this organelle, we designed a molecular reporter consisting of a PKD-specific substrate sequence fused to enhanced green fluorescent protein (EGFP), specifically targeted to the TGN via the p230 GRIP domain. Quantitative analyses using a phosphospecific antibody and ratiometric fluorescence imaging revealed that Golgi-specific phosphorylation of the reporter was strictly dependent on stimulation of endogenous PKD or transient expression of active PKD constructs. Conversely, PKD-specific pharmacological inhibitors and siRNA-mediated PKD knockdown suppressed reporter phosphorylation. Using this reporter we investigated a potential role for PKD in the regulation of Golgi complex morphology. Interestingly, nocodazole-induced Golgi complex break-up and dispersal was associated with local PKD activation as measured by reporter phosphorylation and this was efficiently blocked by expression of a dominant-negative PKD mutant or PKD depletion. Our data thus identify a novel link between PKD activity and the microtubule cytoskeleton, whereby Golgi complex integrity is regulated.

Gene Expression-Based Identification of Antigen-Responsive CD8+ T Cells on a Single-Cell Level.

CD8+ T cells are important effectors of adaptive immunity against pathogens, tumors, and self antigens. Here, we asked how human cognate antigen-responsive CD8+ T cells and their receptors could be identified in unselected single-cell gene expression data. Single-cell RNA sequencing and qPCR of dye-labeled antigen-specific cells identified large gene sets that were congruently up- or downregulated in virus-responsive CD8+ T cells under different antigen presentation conditions. Combined expression of TNFRSF9, XCL1, XCL2, and CRTAM was the most distinct marker of virus-responsive cells on a single-cell level. Using transcriptomic data, we developed a machine learning-based classifier that provides sensitive and specific detection of virus-responsive CD8+ T cells from unselected populations. Gene response profiles of CD8+ T cells specific for the autoantigen islet-specific glucose-6-phosphatase catalytic subunit-related protein differed markedly from virus-specific cells. These findings provide single-cell gene expression parameters for comprehensive identification of rare antigen-responsive cells and T cell receptors.

CD8+ T cells specific for the islet autoantigen IGRP are restricted in their T cell receptor chain usage.

CD8+ T cells directed against beta cell autoantigens are considered relevant for the pathogenesis of type 1 diabetes. Using single cell T cell receptor sequencing of CD8+ T cells specific for the IGRP265-273 epitope, we examined whether there was expansion of clonotypes and sharing of T cell receptor chains in autoreactive CD8+ T cell repertoires. HLA-A*0201 positive type 1 diabetes patients (n = 19) and controls (n = 18) were analysed. TCR α- and ß-chain sequences of 418 patient-derived IGRP265-273-multimer+ CD8+ T cells representing 48 clonotypes were obtained. Expanded populations of IGRP265-273-specific CD8+ T cells with dominant clonotypes that had TCR α-chains shared across patients were observed. The SGGSNYKLTF motif corresponding to TRAJ53 was contained in 384 (91.9%) cells, and in 20 (41.7%) patient-derived clonotypes. TRAJ53 together with TRAV29/DV5 was found in 15 (31.3%) clonotypes. Using next generation TCR α-chain sequencing, we found enrichment of one of these TCR α-chains in the memory CD8+ T cells of patients as compared to healthy controls. CD8+ T cell clones bearing the enriched motifs mediated antigen-specific target cell lysis. We provide the first evidence for restriction of T cell receptor motifs in the alpha chain of human CD8+ T cells with specificity to a beta cell antigen.

Beta-cell autoimmunity.

Beta cell destruction in autoimmune diabetes is accompanied by the presence of autoantibodies and autoreactive T cells against beta cell antigens. Autoantibodies to insulin are predictive of future diabetes in man and in the non-obese diabetic mouse model. Furthermore, the detection of peripheral autoreactive CD8(+) T cells in this mouse model is indicative of beta cell killing and correlates with the development of diabetes. We describe two protocols that are helpful for the detection of beta-cell autoimmunity in mice. The first protocol describes the detection of insulin-specific autoantibodies using a radio-binding assay. The other is a general CD8(+) T cell ELISpot protocol for the detection of peptide-specific responses of CD8(+) T cells from secondary lymphoid organs or pancreatic islets.

G-PKDrep-live, a genetically encoded FRET reporter to measure PKD activity at the trans-Golgi-network.

The serine/threonine protein kinase D (PKD) is recruited to the trans-Golgi-network (TGN) by interaction with diacylglycerol (DAG) and Arf1 and promotes the fission of vesicles containing cargo destined for the plasma membrane. PKD activation is mediated by PKC(-induced phosphorylation. However, signaling pathways that activate PKD specifically at the TGN are only poorly characterized. Recently we created G-PKDrep, a genetically encoded fluorescent reporter for PKD activity at the TGN in fixed cells. To establish a reporter useful for monitoring Golgi-specific PKD activity in living cells we now refined G-PKDrep to generate G-PKDrep-live. Specifically, phosphorylation of G-PKDrep-live expressed in mammalian cells results in changes of fluorescence resonance energy transfer (FRET), and allows for indirect imaging of PKD activity. In a proof-of-principle experiment using phorbolester treatment, we demonstrate the reporter's capability to track rapid activation of PKD at the TGN. Furthermore, activation-induced FRET changes are reversed by treatment with PKD-specific pharmacological inhibitors. Thus, the newly developed reporter G-PKDrep-live is a suitable tool to visualize dynamic changes in PKD activity at the TGN in living cells. See accompanying commentary by Gautam DOI: 10.1002/biot.201100424.

Protein kinase D controls the integrity of Golgi apparatus and the maintenance of dendritic arborization in hippocampal neurons.

Protein kinase D (PKD) is known to participate in various cellular functions, including secretory vesicle fission from the Golgi and plasma membrane-directed transport. Here, we report on expression and function of PKD in hippocampal neurons. Expression of an enhanced green fluorescent protein (EGFP)-tagged PKD activity reporter in mouse embryonal hippocampal neurons revealed high endogenous PKD activity at the Golgi complex and in the dendrites, whereas PKD activity was excluded from the axon in parallel with axonal maturation. Expression of fluorescently tagged wild-type PKD1 and constitutively active PKD1(S738/742E) (caPKD1) in neurons revealed that both proteins were slightly enriched at the trans-Golgi network (TGN) and did not interfere with its thread-like morphology. By contrast, expression of dominant-negative kinase inactive PKD1(K612W) (kdPKD1) led to the disruption of the neuronal Golgi complex, with kdPKD1 strongly localized to the TGN fragments. Similar findings were obtained from transgenic mice with inducible, neuron-specific expression of kdPKD1-EGFP. As a prominent consequence of kdPKD1 expression, the dendritic tree of transfected neurons was reduced, whereas caPKD1 increased dendritic arborization. Our results thus provide direct evidence that PKD activity is selectively involved in the maintenance of dendritic arborization and Golgi structure of hippocampal neurons.