Depending on the stimuli they encounter, B lymphocytes engage in signaling events that lead to immunity or tolerance. Both responses are mediated through antigen interactions with the B cell antigen receptor (BCR). Antigen valency is thought to be an important parameter in B cell signaling, but systematic studies are lacking. To explore this issue, we synthesized multivalent ligands of defined valencies using the ring-opening metathesis polymerization (ROMP). When mice are injected with multivalent antigens generated by ROMP, only those of high valencies elicit antibody production. These results indicate that ligands synthesized by ROMP can activate immune responses in vivo. All of the multivalent antigens tested activate signaling through the BCR. The ability of antigens to cluster the BCR, promote its localization to membrane microdomains, and augment intracellular Ca2+ concentration increases as a function of antigen valency. In contrast, no differences in BCR internalization were detected. Our results indicate that differences in the antigenicity of BCR ligands are related to their ability to elicit increases in intracellular Ca2+ concentration. Finally, we observed that unligated BCRs cluster with BCRs engaged by multivalent ligands, a result that suggests that signals mediated by the BCR are amplified through receptor arrays. Our data suggest a link between the mechanisms underlying signal initiation by receptors that must respond with high sensitivity.
CD22 is an inhibitory coreceptor on the surface of B cells that attenuates B cell antigen receptor (BCR) signaling and, therefore, B cell activation. Elucidating the molecular mechanisms underlying the inhibitory activity of CD22 is complicated by the ubiquity of CD22 ligands. Although antigens can display CD22 ligands, the receptor is known to bind to sialylated glycoproteins on the cell surface. The propinquity of CD22 and cell-surface glycoprotein ligands has led to the conclusion that the inhibitory properties of the receptor are due to cis interactions. Here, we examine the functional consequences of trans interactions by employing sialylated multivalent antigens that can engage both CD22 and the BCR. Exposure of B cells to sialylated antigens results in the inhibition of key steps in BCR signaling. These results reveal that antigens bearing CD22 ligands are powerful suppressors of B cell activation. The ability of sialylated antigens to inhibit BCR signaling through trans CD22 interactions reveals a previously unrecognized role for the Siglec-family of receptors as modulators of immune signaling.B cell antigen receptor ͉ multivalency ͉ sialic acid ͉ siglec ͉ autoimmunity T he initiation of an immune response or the prevention of autoimmunity depends upon the ability of the B cell antigen receptor (BCR) to transmit signals that positively or negatively regulate B lymphocyte survival, proliferation, and differentiation (1). To avoid detrimental autoimmune responses, a means of differentiating between foreign and self-antigens is required; coreceptors that modulate BCR signaling can ensure that these distinctions are made. CD22 is an inhibitory coreceptor that can attenuate BCR signaling (2, 3). CD22 null mice possess hyperresponsive B cells (4), illustrating a role for CD22 in establishing a threshold for B cell activation. Specifically, an increase in intracellular Ca 2ϩ ion concentration is a hallmark of B cell activation (5, 6), and B cells isolated from CD22 null mice display increased Ca 2ϩ flux in response to antigen (4, 7). Thus, loss of CD22 results in a lowering of the threshold for B cell activation. Other data also support this conclusion: CD22 null mice exhibit increased serum IgM concentrations, decreased surface IgM levels on peripheral B cells, increased induction of apoptosis in response to BCR crosslinking, and increased serum autoantibody titers (8). These observations are consistent with the loss of CD22 leading to increased sensitivity and chronic B cell activation.The process of B cell activation ensues upon binding of multivalent antigen to the BCR. Antigen-induced clustering elicits phosphorylation of the cytoplasmic immunoreceptor tyrosinebased activation motifs (ITAMs), which are present in the BCRassociated signaling proteins Ig␣/. The phosphorylation reaction is catalyzed by Src-family kinases such as Lyn. Upon phosphorylation of the BCR components, Syk kinase is recruited to the BCR signaling complex (9). Syk is essential for propagating BCR signaling (10, 11). It acts along with...
With a significant reduction of the bowel perforation rate and a reduction of circumferential margin involvement and wound abscess formation, ELAPE improves important surrogate parameters for local recurrence rate and survival.
In the majority of participating EDs, diagnostic standards for PES were known but were not routinely applied. It has to be assumed that many psychiatric disorders, in particular suicide attempts and suicidal ideation are not discovered. In many EDs psychiatric knowledge was available but a psychiatric consultation was only rarely requested. Physicians in the ED report a high degree of legal uncertainty with psychiatric patients. The use of screening instruments is recommended.
Our investigation demonstrates that the response of tumor to neoadjuvant therapy is an independent prognostic factor in patients with rectal carcinoma.
ELAPE results in lower local recurrence rates as compared with conventional APE. We conclude that the extralevator approach should be the procedure of choice for advanced low rectal cancer not amenable to sphincter preserving procedures.
The role of SNAP-25 (synaptosomal associated protein of 25 kDa) isotypes in the neurotransmitter release process was examined by varying their relative abundance during PC12 cell differentiation induced by nerve growth factor (NGF). Norepinephrine release by NGF-differentiated PC12 cells is more sensitive to type A botulinum toxin (BoNT/A) than by nondifferentiated cells, while both differentiated and nondifferentiated PC12 cells are equally sensitive to type E botulinum toxin (BoNT/E). The differential sensitivity to BoNT/A corresponds to an altered susceptibility of SNAP-25 isotypes to BoNT/A cleavage in vitro, whereas both isotypes are equally vulnerable to cleavage by BoNT/E. Using recombinant SNAP-25 preparations, we show that BoNT/A cleaves SNAP-25b (present in differentiated cells) 2-fold more readily than SNAP-25a (present in both differentiated and nondifferentiated cells). Structural studies using far-ultraviolet circular dichroism (UV--CD) and thermal denaturation suggest a difference in the polypeptide folding as the underlying molecular basis for the differential sensitivity of SNAP-25b and SNAP-25a to BoNT/A cleavage. We propose differential roles for SNAP-25b and SNAP-25a in the neurotransmitter release process since our results suggest that BoNT/A inhibits neurotransmitter release by primarily cleaving SNAP-25b.
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