Department of Chemistry, University of California, Davis, California 95616, USA.
Biochemistry. 2010 Feb 23;49(7):1469-76. doi: 10.1021/bi9020132.
The navel orangeworm, Amyelois transitella (Walker), is an agricultural insect pest that can be controlled by disrupting male-female communication with sex pheromones, a technique known as mating disruption. Insect pheromone-binding proteins (PBPs) provide fast transport of hydrophobic pheromones through the aqueous sensillar lymph and promote sensitive delivery of pheromones to receptors. Here we present the three-dimensional structure of a PBP from A. transitella (AtraPBP1) in solution at pH 4.5 determined by nuclear magnetic resonance (NMR) spectroscopy. Pulsed-field gradient NMR diffusion experiments, multiangle light scattering, and (15)N NMR relaxation analysis indicate that AtraPBP1 forms a stable monomer in solution at pH 4.5 in contrast to forming mostly dimers at pH 7. The NMR structure of AtraPBP1 at pH 4.5 contains seven alpha-helices (alpha1, L8-L23; alpha2, D27-F36; alpha3, R46-V62; alpha4, A73-M78; alpha5, D84-S100; alpha6, R107-L125; alpha7, M131-E141) that adopt an overall main-chain fold similar to that of PBPs found in Antheraea polyphemus and Bombyx mori. The AtraPBP1 structure is stabilized by three disulfide bonds formed by C19/C54, C50/C108, and C97/C117 and salt bridges formed by H69/E60, H70/E57, H80/E132, H95/E141, and H123/D40. All five His residues are cationic at pH 4.5, whereas H80 and H95 become neutral at pH 7.0. The C-terminal helix (alpha7) contains hydrophobic residues (M131, V133, V134, V135, V138, L139, and A140) that contact conserved residues (W37, L59, A73, F76, A77, I94, V111, and V115) suggested to interact with bound pheromone. Our NMR studies reveal that acid-induced formation of the C-terminal helix at pH 4.5 is triggered by a histidine protonation switch that promotes rapid release of bound pheromone under acidic conditions.
脐形粘虫,Amyelois transitella (Walker),是一种农业昆虫害虫,可以通过性信息素来干扰雌雄之间的交流来进行控制,这种技术被称为交配干扰。昆虫信息素结合蛋白(PBPs)为疏水性信息素提供了在水性感觉淋巴液中的快速运输,并促进了信息素向受体的敏感传递。在这里,我们通过核磁共振(NMR)光谱法在 pH 4.5 下测定了一种来自 A. transitella 的 PBP(AtraPBP1)的三维结构。脉冲场梯度 NMR 扩散实验、多角度光散射和(15)N NMR 弛豫分析表明,与在 pH 7 下主要形成二聚体相比,AtraPBP1 在 pH 4.5 下的溶液中形成稳定的单体。在 pH 4.5 下,AtraPBP1 的 NMR 结构包含七个α-螺旋(α1,L8-L23;α2,D27-F36;α3,R46-V62;α4,A73-M78;α5,D84-S100;α6,R107-L125;α7,M131-E141),采用类似于在 Antheraea polyphemus 和 Bombyx mori 中发现的 PBP 的总体主链折叠。AtraPBP1 结构由三个二硫键(由 C19/C54、C50/C108 和 C97/C117 形成)和三个盐桥(由 H69/E60、H70/E57、H80/E132、H95/E141 和 H123/D40 形成)稳定。在 pH 4.5 下,所有五个 His 残基均带正电荷,而 H80 和 H95 在 pH 7.0 下变为中性。C 末端螺旋(α7)包含与保守残基(W37、L59、A73、F76、A77、I94、V111 和 V115)相互作用的疏水性残基(M131、V133、V134、V135、V138、L139 和 A140),这些残基被认为与结合的信息素相互作用。我们的 NMR 研究表明,在 pH 4.5 下,酸诱导 C 末端螺旋的形成是由组氨酸质子化开关触发的,该开关在酸性条件下促进了结合信息素的快速释放。