Mizuno Takuya, Rothstein Thomas L
Department of Medicine, Boston University School of Medicine, Boston, MA 02118, USA.
J Immunol. 2005 May 15;174(10):6062-70. doi: 10.4049/jimmunol.174.10.6062.
BCR signaling is propagated by a series of intermediaries and eventuates in NF-kappaB activation, among other outcomes. Interruption of several mediators that constitute the signalosome, such as PI3K and phospholipase Cgamma2, completely blocks BCR signaling for NF-kappaB. We show here that this accepted, conventional paradigm is, in fact, limited to naive B cells. CD40L treatment reprograms normal B cells such that a novel, alternate pathway for BCR signaling is created. Through this alternate pathway BCR triggering induces nuclear NF-kappaB without the need for PI3K or for phospholipase Cgamma2. Induction of NF-kappaB via the alternate pathway is accompanied by IkappaB kinase beta (IKKbeta) phosphorylation, IkappaBalpha phosphorylation, and IkappaBalpha degradation, and inhibition of IKKbeta blocked IkappaBalpha degradation. Several key events in the conventional pathway, including early protein tyrosine phosphorylation, were unimpeded by generation of the alternate pathway which appears to operate in parallel, rather than in competition, with classical BCR signaling. These results demonstrate cross-talk between CD40 and BCR, such that the requirements for BCR signaling are altered by prior B cell exposure to CD40L. The alternate BCR signaling pathway bypasses multiple signalosome elements and terminates in IKKbeta activation.
BCR信号通过一系列中间分子进行传导,最终导致NF-κB激活等结果。对构成信号小体的几种介质(如PI3K和磷脂酶Cγ2)的阻断,会完全阻断BCR信号向NF-κB的传导。我们在此表明,这种被广泛接受的传统模式实际上仅限于初始B细胞。CD40L处理可对正常B细胞进行重编程,从而创建一条新的、替代的BCR信号传导途径。通过这条替代途径,BCR触发可诱导核内NF-κB,而无需PI3K或磷脂酶Cγ2。通过替代途径诱导NF-κB伴随着IkappaB激酶β(IKKβ)磷酸化、IkappaBα磷酸化和IkappaBα降解,并且对IKKβ的抑制会阻断IkappaBα降解。传统途径中的几个关键事件,包括早期蛋白酪氨酸磷酸化,不受替代途径产生的影响,替代途径似乎与经典BCR信号并行运作,而非相互竞争。这些结果表明CD40与BCR之间存在相互作用,使得BCR信号的需求因B细胞先前暴露于CD40L而发生改变。替代的BCR信号途径绕过多个信号小体元件,并以IKKβ激活为终点。
