David Depoil

The Membrane Skeleton Controls Diffusion Dynamics and Signaling through the B Cell Receptor

Summary Early events of B cell activation after B cell receptor (BCR) triggering have been well characterized. However, little is known about the steady state of the BCR on the cell surface. Here, we simultaneously visualize single BCR particles and components of the membrane skeleton. We show that an ezrin- and actin-defined network influenced steady-state BCR diffusion by creating boundaries that restrict BCR diffusion. We identified the intracellular domain of Igβ as important in mediating this restriction in diffusion. Importantly, alteration of this network was sufficient to induce robust intracellular signaling and concomitant increase in BCR mobility. Moreover, by using B cells deficient in key signaling molecules, we show that this signaling was most probably initiated by the BCR. Thus, our results suggest the membrane skeleton plays a crucial function in controlling BCR dynamics and thereby signaling, in a way that could be important for understanding tonic signaling necessary for B cell development and survival.

Phospholipase C-γ2 and Vav cooperate within signaling microclusters to propagate B cell spreading in response to membrane-bound antigen

B cell receptor (BCR) recognition of membrane-bound antigen initiates a spreading and contraction response, the extent of which is controlled through the formation of signaling-active BCR-antigen microclusters and ultimately affects the outcome of B cell activation. We followed a genetic approach to define the molecular requirements of BCR-induced spreading and microcluster formation. We identify a key role for phospholipase C-γ2 (PLCγ2), Vav, B cell linker, and Brutons tyrosine kinase in the formation of highly coordinated “microsignalosomes,” the efficient assembly of which is absolutely dependent on Lyn and Syk. Using total internal reflection fluorescence microscopy, we examine at high resolution the recruitment of PLCγ2 and Vav to microsignalosomes, establishing a novel synergistic relationship between the two. Thus, we demonstrate the importance of cooperation between components of the microsignalosome in the amplification of signaling and propagation of B cell spreading, which is critical for appropriate B cell activation.

Dynamic cortical actin remodeling by ERM proteins controls BCR microcluster organization and integrity

By dynamically remodeling the cortical actin network, ezrin and moesin control BCR microcluster formation, organization, and integrity.

Early Events of B Cell Activation by Antigen

B cells undergo membrane spreading and contraction during activation in response to antigen-presenting cells. The activation of B cells confers long-lasting protection from a plethora of infectious diseases through the generation of plasma cells that produce high-affinity antibodies and memory cells. Engagement of the B cell receptor (BCR) with cognate antigen initiates intracellular signaling and subsequent internalization of antigen. Membrane-bound antigens are now considered the predominant forms that initiate B cell activation in vivo. We have shown that upon recognition of antigen on the surface of a presenting cell, the B cell undergoes a dramatic change in morphology characterized by rapid spreading followed by more prolonged contraction along the presenting surface. This two-phase response increases the amount of antigen that the B cell accumulates, internalizes, and subsequently presents to T cells. Thus, the spreading and contraction response shapes the outcome of B cell activation. We used a combination of planar lipid bilayers and total internal reflection fluorescence microscopy to investigate the early events that occur after engagement of the BCR and before B cell spreading. We observed the rapid formation of BCR-antigen microclusters, which we redefine as “microsignalosomes” because they mediate the coordinated recruitment of intracellular effectors, such as the kinases Lyn and Syk, the adaptor Vav, and phospholipase C–γ2 (PLC-γ2). We identified an essential role for the co-receptor CD19 in mediating spreading, and thus B cell activation, in response to membrane-bound antigen. Preliminary evidence suggests that the cellular morphology changes described in vitro are likely to occur upon recognition of antigen presented on the surface of macrophages in lymph nodes in vivo.

The role of integrins and coreceptors in refining thresholds for B-cell responses

Summary:  Despite compelling evidence that a large proportion of antigens encountered in vivo by B cells are membrane bound, the general view is that B cells are mainly activated by soluble antigens. This notion may have been biased somewhat over the years because the high affinity of the B‐cell receptor (BCR) for soluble intact ligands allows efficient B‐cell stimulation in vitro. In vivo, however, even soluble antigens are likely to be deposited on the surface of antigen‐presenting cells, either by complement or Fc receptors in the form of immune complexes, thus becoming more potent stimulators of B‐cell activation. In this framework, the BCR works in a complex environment of integrins and coreceptors, as well as the B‐cell cytoskeleton. Over the last few years, we have focused on B‐cell membrane‐bound antigen recognition. Here, we discuss some of our findings in the context of what is currently known in this exciting new field.