Vibeke Sundvold-Gjerstad

VEGFR2 induces c-Src signaling and vascular permeability in vivo via the adaptor protein TSAd

VEGFR2 activates c-Src and induces vascular permeability by binding to the adaptor protein TSAd

The cellular mechanism by which complementary Id + and anti-Id antibodies communicate: T cells integrated into idiotypic regulation

The V region antigenic determinants (idiotopes (Ids)) of antibodies (Abs) have been suggested to be involved in regulating the immune system. Certain diseases such as diabetes mellitus have recently been associated with a disequilibrium between Id+ and anti‐Id Abs. However, it is unknown how Abs carrying complementary idiotypes (that is, Id+ and anti‐Id Abs) regulate each other at the level of B and T cells. In this study, we show that B lymphoma cells genetically equipped with anti‐Id BCR V regions receive a signal when exposed to Id+Ig. Moreover, they become × 104 more efficient at presenting exogenous Id+ Ab to CD4+ T cells in vitro. Activated Id‐specific T cells in turn regulated the Id‐specific B lymphoma cells. Similar results were obtained in vivo in a surrogate model in which an Id‐peptide was incorporated genetically into the C‐region of a recombinant Ab that targeted IgD on B cells. The findings suggest that conventional T–B collaboration can explain communication between complementary Id+ and anti‐Id Ab at the cellular level. A model is suggested that integrates present and previous data on B‐cell regulation by Id‐specific T cells.

The C terminus of T cell-specific adapter protein (TSAd) is necessary for TSAd-mediated inhibition of Lck activity.

T cell‐specific adapter protein (TSAd), encoded by the SH2D2A gene, is expressed in activated T cells. The function of TSAd is as yet unknown. We previously showed that TSAd may modulate T cell receptor‐triggered signaling events. TSAd contains a Src homology (SH)2 domain, ten tyrosines and a C‐terminal proline‐rich region. Here, we show that human TSAd interacts with Lck through the Lck SH2 and SH3 domains and is a substrate for Lck. The TSAd C terminus, including the proline‐rich region and five tyrosines, is both necessary and sufficient for TSAd interaction with and phosphorylation by Lck. Expression of TSAd in Jurkat TAg cells results in hyperphosphorylation of endogenous Lck on Y394 and to an even larger extent on Y505, resulting in a reduced Y394/Y505 phosphorylation ratio in these cells. Furthermore, full‐length TSAd, but not TSAd lacking the C terminus, inhibits the hyperactive Lck Y505F mutant when both are expressed in Jurkat T cells. In contrast, expression of the TSAd C terminus alone is sufficient to inhibit Lck Y505F in phosphorylating its substrates in Jurkat T cells. Our results indicate that the TSAd C terminus is essential for inhibition of Lck activity by TSAd, and suggest a mechanism for how TSAd may inhibit early T cell activation events.

T Cell Specific Adapter Protein (TSAd) Interacts with Tec Kinase ITK to Promote CXCL12 Induced Migration of Human and Murine T Cells

Background The chemokine CXCL12/SDF-1α interacts with its G-protein coupled receptor CXCR4 to induce migration of lymphoid and endothelial cells. T cell specific adapter protein (TSAd) has been found to promote migration of Jurkat T cells through interaction with the G protein β subunit. However, the molecular mechanisms for how TSAd influences cellular migration have not been characterized in detail. Principal Findings We show that TSAd is required for tyrosine phosphorylation of the Lck substrate IL2-inducible T cell kinase (Itk). Presence of Itk Y511 was necessary to boost TSAds effect on CXCL12 induced migration of Jurkat T cells. In addition, TSAds ability to promote CXCL12-induced actin polymerization and migration of Jurkat T lymphocytes was dependent on the Itk-interaction site in the proline-rich region of TSAd. Furthermore, TSAd-deficient murine thymocytes failed to respond to CXCL12 with increased Itk phosphorylation, and displayed reduced actin polymerization and cell migration responses. Conclusion We propose that TSAd, through its interaction with both Itk and Lck, primes Itk for Lck mediated phosphorylation and thereby regulates CXCL12 induced T cell migration and actin cytoskeleton rearrangements.

Modulation of Lck Function through Multisite Docking to T Cell-specific Adapter Protein

T cell-specific adapter protein (TSAd), encoded by the SH2D2A gene, interacts with Lck through its C terminus and thus modulates Lck activity. Here we mapped Lck phosphorylation and interaction sites on TSAd and evaluated their functional importance. The three C-terminal TSAd tyrosines Tyr280, Tyr290, and Tyr305 were phosphorylated by Lck and functioned as docking sites for the Lck Src homology 2 (SH2) domain. Binding affinities of the TSAd Tyr(P)280 and Tyr(P)290 phosphopeptides to the isolated Lck SH2 domain were similar to that observed for the Lck Tyr(P)505 phosphopeptide, whereas the TSAd Tyr(P)305 peptide displayed a 10-fold higher affinity. The proline-rich Lck SH3-binding site on TSAd as well as the Lck SH2 domain were required for efficient tyrosine phosphorylation of TSAd by Lck. Interaction sites on TSAd for both Lck SH2 and Lck SH3 were necessary for TSAd-mediated modulation of proximal TCR signaling events. We found that 20–30% of TSAd molecules are phosphorylated in activated T cells and that the proportion of TSAd to Lck molecules in such cells is ∼1:1. Therefore, in activated T cells, a considerable number of Lck molecules may potentially be engaged by TSAd. In conclusion, Lck binds to TSAd prolines and phosphorylates and interacts with the three C-terminal TSAd tyrosines. We propose that through multivalent interactions with Lck, TSAd diverts Lck from phosphorylating other substrates, thus modulating its functional activity through substrate competition.

Structure function analysis of SH2D2A isoforms expressed in T cells reveals a crucial role for the proline rich region encoded by SH2D2A exon 7

BackgroundThe activation induced T cell specific adapter protein (TSAd), encoded by SH2D2A, interacts with and modulates Lck activity. Several transcript variants of TSAd mRNA exist, but their biological significance remains unknown. Here we examined expression of SH2D2A transcripts in activated CD4+ T cells and used the SH2D2A variants as tools to identify functionally important regions of TSAd.ResultsTSAd was found to interact with Lck in human CD4+ T cells ex vivo. Three interaction modes of TSAd with Lck were identified. TSAd aa239–256 conferred binding to the Lck-SH3 domain, whereas one or more of the four tyrosines within aa239–334 encoded by SH2D2A exon 7 was found to confer interaction with the Lck-SH2-domain. Finally the TSAd-SH2 domain was found to interact with Lck. The SH2D2A exon 7 encoding TSAd aa 239–334 was found to harbour information essential not only for TSAd interaction with Lck, but also for TSAd modulation of Lck activity and translocation of TSAd to the nucleus. All five SH2D2A transcripts were found to be expressed in CD3 stimulated CD4+ T cells.ConclusionThese data show that TSAd and Lck may interact through several different domains and that Lck TSAd interaction occurs in CD4+ T cells ex vivo. Alternative splicing of exon 7 encoding aa239–334 results in loss of the majority of protein interaction motives of TSAd and yields truncated TSAd molecules with altered ability to modulate Lck activity. Whether TSAd is regulated through differential alternative splicing of the SH2D2A transcript remains to be determined.

cDNA cloning of a rat orthologue of SH2D2A encoding T-cell-specific adaptor protein (TSAd): expression in T and NK cells

The T-cell-specific adapter protein (TSAd), encoded by the SH2D2A gene, has been implicated in modulation of proximal signaling events as well as in transcriptional regulation in human T cells. We have isolated its rat homologue (rSH2D2A) from an NK cell cDNA library and mapped the corresponding gene to chromosome 2 with a hamster-rat radiation hybrid cell panel. rSH2D2A encodes a 376 amino acid protein (rTSAd) which shows greater homology to mouse than human TSAd. In rats, rTSAd was specifically expressed by NK cells and T cells but not by other leukocytes tested. Similarly, in humans we observed abundant transcripts for TSAd in NK cells and T cells. The data suggest that TSAd may have a regulatory role in cellular activation of T and NK cells.

The kinase Itk and the adaptor TSAd change the specificity of the kinase Lck in T cells by promoting the phosphorylation of Tyr192

Phosphorylation of a tyrosine residue in the SH2 domain of the kinase Lck alters its substrate specificity in T cells. Switching Lck’s Attention The Src family kinase (SFK) member Lck has distinct early and late functions in T cell signaling. Early after activation of the T cell receptor (TCR), Lck mediates signals close in space and time to the TCR; later, Lck regulates the actin cytoskeleton, reorganization of which is required for the stable interaction between T cells and antigen-presenting cells (APCs). Lck activity is determined by the balance in the phosphorylation status of two tyrosine residues, one activating and the other inhibitory. Granum et al. identified a third tyrosine residue, Tyr192, which was phosphorylated in response to TCR stimulation. T cells expressing a mutant Lck lacking this tyrosine failed to form stable interactions with APCs. Lck phosphorylated at Tyr192 preferentially associated with regulators of the actin cytoskeleton. Thus, phosphorylation of Tyr192 in Lck enables Lck to switch its attention from the TCR to the actin cytoskeleton, thereby fulfilling different functions at different stages of T cell activation. The substrate specificity of Src family kinases (SFKs) is partly determined by their Src homology 2 (SH2) domains. Thus, transient alterations in the SH2 domain of SFKs might change their binding partners and affect intracellular signaling pathways. Lck is an SFK that is central to the initiation of T cell activation in response to ligand binding to the T cell receptor (TCR) and is also critical for later signaling processes. The kinase activity of Lck requires both the phosphorylation of an activating tyrosine residue and the dephosphorylation of an inhibitory tyrosine residue. We found that a third conserved tyrosine phosphorylation site (Tyr192) within the SH2 domain of Lck was required for proper T cell activation and formation of cell-cell conjugates between T cells and antigen-presenting cells. Through phosphopeptide arrays and biochemical assays, we identified several regulators of the actin cytoskeleton that preferentially bound to Lck phosphorylated at Tyr192 compared to Lck that was not phosphorylated at this site. Two of these phosphorylation-dependent binding partners, the kinase Itk (interleukin-2–inducible Tec kinase) and the adaptor protein TSAd (T cell–specific adaptor), promoted the TCR-dependent phosphorylation of Lck at Tyr192. Our data suggest that phosphorylation transiently alters SH2 domain specificity and provide a potential mechanism whereby SFKs may be rewired from one signaling program to another to enable appropriate cell activation.

T cell specific adaptor protein (TSAd) promotes interaction of Nck with Lck and SLP-76 in T cells

BackgroundThe Lck and Src binding adaptor protein TSAd (T cell specific adaptor) regulates actin polymerization in T cells and endothelial cells. The molecular details as to how TSAd regulates this process remain to be elucidated.ResultsTo identify novel interaction partners for TSAd, we used a scoring matrix-assisted ligand algorithm (SMALI), and found that the Src homology 2 (SH2) domain of the actin regulator Non-catalytic region of tyrosine kinase adaptor protein (Nck) potentially binds to TSAd phosphorylated on Tyr280 (pTyr280) and pTyr305. These predictions were confirmed by peptide array analysis, showing direct binding of recombinant Nck SH2 to both pTyr280 and pTyr305 on TSAd. In addition, the SH3 domains of Nck interacted with the proline rich region (PRR) of TSAd. Pull-down and immunoprecipitation experiments further confirmed the Nck-TSAd interactions through Nck SH2 and SH3 domains. In line with this Nck and TSAd co-localized in Jurkat cells as assessed by confocal microscopy and imaging flow cytometry. Co-immunoprecipitation experiments in Jurkat TAg cells lacking TSAd revealed that TSAd promotes interaction of Nck with Lck and SLP-76, but not Vav1. TSAd expressing Jurkat cells contained more polymerized actin, an effect dependent on TSAd exon 7, which includes interactions sites for both Nck and Lck.ConclusionsTSAd binds to and co-localizes with Nck. Expression of TSAd increases both Nck-Lck and Nck-SLP-76 interaction in T cells. Recruitment of Lck and SLP-76 to Nck by TSAd could be one mechanism by which TSAd promotes actin polymerization in activated T cells.

Targeting Influenza Virus Hemagglutinin to Xcr1+ Dendritic Cells in the Absence of Receptor-Mediated Endocytosis Enhances Protective Antibody Responses.

Targeting Ags to conventional dendritic cells can enhance Ag-specific immune responses. Although most studies have focused on the induction of T cell responses, the mechanisms by which targeting improves Ab responses are poorly understood. In this study we present data on the use of human XCL1 (hXCL1) and hXCL2 fusion vaccines in a murine model. We show that the human chemokines bound type 1 conventional dendritic cells (cDC1), and that immunization with influenza virus hemagglutinin fused to hXCL1 or hXCL2 induced full protection against influenza challenge. Surprisingly, the hXCL1- and hXCL2-fusion vaccines induced better long-term protection associated with stronger induction of neutralizing Abs, and more Ab-secreting cells in bone marrow. In contrast, murine Xcl1 fusion vaccines induced stronger CD8+ T cell responses compared with hXCL1. Further analysis revealed that although murine Xcl1 fusion vaccines induced chemotaxis and were rapidly endocytosed by cDC1, hXCL1 and hXCL2 fusion vaccines did not induce chemotaxis, were less efficiently endocytosed, and consequently, remained on the surface. This difference may explain the enhanced induction of Abs when targeting Ag to cDC1 using hXCL1 and hXCL2, and suggests that immune responses can be manipulated in directing Abs or T cells based on how efficiently the targeted Ag is endocytosed by the DC.