Conversely, two Syk ligands were approximately twofold enriched w

Conversely, two Syk ligands were approximately twofold enriched with the S297A mutant, i.e. Igβ and ubiquitin. Hence, our “reverse proteome approach” directly confirmed the critical role of the major Syk phosphorylation site for 14-3-3 binding and indicated that this complex inhibits BCR recruitment and ubiquitinylation of Syk. Reduced BCR recruitment is likely to attenuate Syk function while ubiquitinylation of Syk

has been associated with its increased degradation 8, Selleck ABT263 9. We tested the functional impact of 14-3-3γ for Syk-mediated activation of the Ca2+ mobilization pathway. Importantly, all subsequently described studies were conducted with batches Selleckchem LDK378 of retrovirally transduced B cells expressing identical amounts of WT or mutant Syk (Fig.

4A, right panel). Hence, we could exclude that conclusions are based on individual responses of single cell clones produced and selected by conventional transfection methods. We immunoprecipitated the proximal Syk substrate SLP65 from resting and BCR-activated B cells expressing either WT Syk or its S297A variant, and subjected the obtained proteins to anti-phosphotyrosine immunoblot analysis (Fig. 4A, upper left panel). SLP65 purified from S297A-expressing cells showed strongly enhanced and prolonged phosphorylation compared to SLP65 obtained from cells expressing WT Syk. Similarly, PLC-γ2 that was co-immunoprecipitated with SLP65 and also acts as important Syk substrate exhibited increased and sustained tyrosine phosphorylation in the absence Protein kinase N1 of the Syk/14-3-3γ complex (Fig. 4B, upper left panel). The latter finding was directly demonstrated by anti-phosphotyrosine immunoblotting of anti-PLC-γ2 precipitates (Fig. 4B). Equal loading of purified proteins was confirmed by reprobing the blots with antibodies to SLP65 or PLC-γ2, respectively (Fig. 4A and B, lower panels). Hence, loss of 14-3-3γ binding promotes phosphorylation of Syk substrates. Flow cytometric recording

of BCR-induced Ca2+ responses demonstrated that this effect translated into dramatically prolonged Ca2+ fluxing (Fig. 4C). Interestingly, the maximal Ca2+ peaks of WT and mutant B cells were almost identical. We conclude that 14-3-3γ binding to phospho-S297 of Syk serves as negative feedback regulation that limits the activation of BCR-proximal signaling events. Next, we assessed how 14-3-3γ inhibits Syk function. Two main mechanisms control Syk activation and interaction of Syk with downstream targets. Doubly phosphorylated ITAMs in Igα and Igβ recruit Syk to the plasma membrane and concomitantly provide an allosteric trigger for its catalytic activity. The latter is further amplified by auto- and trans-phosphorylation on activatory tyrosine residues 6.

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