Immunodiversity of plant receptor kinase networks for synthetic circuit design

用于合成电路设计的植物受体激酶网络的免疫多样性

• 批准号: 10709286
• 负责人: Adam D Steinbrenner
• 金额: $ 37.93万
• 依托单位: UNIVERSITY OF WASHINGTON
• 依托单位国家: 美国
• 财政年份: 2023
• 资助国家: 美国
• 起止时间: 2023-08-01 至 2028-07-31
• 项目状态: 未结题
• 来源: https://reporter.nih.gov/project-details/10709286
• 关键词: Agonist; Amino Acid Substitution; Animals; BAK1 gene; Binding; Binding Sites; Biotechnology; Cell Surface Receptors; DNA Library; Engineering; Epitopes; Evolution; G-Protein-Coupled Receptors; Gene Family; Genes; Genome; Genomics; Heterodimerization; Human; Human Engineering; Immune; Immune signaling; Immune system; Immunoglobulins; Immunologic Receptors; Inflammation; Leucine-Rich Repeat; Libraries; Life; Ligand Binding; Ligands; Medicine; Molecular Biology; Monitor; Natural Immunity; Orphan; Pathway interactions; Peptides; Phosphorylation; Phosphotransferases; Plant Model; Plants; Protein Kinase; Proteins; Receptor Activation; Receptor Gene; Reporter; Signal Pathway; Signal Transduction; Specificity; Structure; Toll-like receptors; Variant; Yeast Model System; design; extracellular; insight; network architecture; pathogen; protein aminoacid sequence; receptor; reconstruction; scaffold; sensor; synthetic construct; tool

PROJECT SUMMARY Immune systems across kingdoms of life recognize pathogen-associated molecules through germline-encoded innate immune receptors. Receptor repertoires in plants have evolved to detect an especially diverse set of ligands due to massive expansion of the receptor kinase gene family with specialized ligand recognition functions. Pairing receptor sequence diversity with specific recognition functions across 100 million RK genes (350,000 plant species * 500 receptors per genome) is a grand challenge in plant molecular biology. It also presents the opportunity to develop a new class of protein-based sensors for biotechnology. The Steinbrenner lab aims to characterize and deploy this vast plant immunodiversity for ligand-induced modulation of engineered signaling pathways. First, we will define the full ligand space that is monitored by plant receptors by focusing on the large subfamily of leucine-rich repeat receptor kinases (termed receptors here) which bind small peptide epitopes to initiate immune signaling. We will combine evolution- and structure-guided approaches to decode the basis of receptor:ligand specificity, including an extensive phylogenomic analysis, peptide variant libraries, and ancestral sequence reconstruction. We hypothesize that transitions in ligand specificity are marked by amino acid substitutions in predicted ligand binding sites among ancestral receptor genes. For “orphan” receptors lacking defined functions, we will conduct a genomic screen using synthetic DNA libraries encoding candidate pathogen epitopes using both plant and yeast models as reporters for receptor activation. We hypothesize that most receptors involved in plant innate immunity will be activated by specific pathogen-derived peptide sequences. Combined, these approaches will provide basic insights into receptor:ligand specificity as well as a toolkit of extracellular sensor domains responsive to specific peptide agonists. Second, we will leverage the unique network architecture of plant immune networks to engineer synthetic signaling pathways that do not interfere with endogenous animal signaling pathways. The plant receptors studied here signal through heterodimerization with a common co-receptor called BAK1. Co-receptor activation culminates in phosphorylation of substrates based on defined phosphocode motifs. We are currently engineering the human inflammation signaling pathway to accept orthogonal input from plant receptors by incorporating plant kinase substrates into specific, phosphoregulated signaling factors. In parallel, we will use plant receptor:co-receptor heterodimerization as a platform to scaffold endogenous human immune signaling domains from Toll-like receptors. We hypothesize that engineered pathways will allow modular tuning by diverse peptide ligands, providing an alternative to current immunoglobulin or GPCR-based synthetic tools. In summary our lab is poised to deploy tools for receptor de-orphanization and signaling pathway engineering to leverage the immense diversity driven by plant-pathogen co-evolution. (30 lines)

项目概要 生命王国中的免疫系统通过种系编码识别病原体相关分子 植物中的先天免疫受体已经进化到可以检测一组特别多样化的受体。 由于具有专门配体识别功能的受体激酶基因家族的大量扩展而产生的配体 将受体序列多样性与 1 亿个 RK 基因的特定识别功能配对。 （350,000种植物*每个基因组500个受体）也是植物分子生物学的巨大挑战。 Steinbrenner 提供了开发新型基于蛋白质的生物技术传感器的机会。 实验室旨在表征和部署这种巨大的植物免疫多样性，以进行配体诱导的调节 工程信号通路。 首先，我们将通过关注大亚家族来定义植物受体监测的完整配体空间 富含亮氨酸的重复受体激酶（此处称为受体），其结合小肽表位以启动 我们将结合进化和结构引导的方法来解码免疫信号的基础。 受体：配体特异性，包括广泛的系统发育分析、肽变体库和 我们勇敢地承认配体特异性的转变是由氨基标记的。 祖先受体基因中预测的配体结合位点的酸取代 对于“孤儿”受体。 由于缺乏定义的功能，我们将使用编码候选基因的合成 DNA 文库进行基因组筛选 我们使用植物和酵母模型来产生病原体表位以激活受体。 大多数参与植物先天免疫的受体将被特定的病原体衍生肽激活 结合起来，这些方法将为受体：配体特异性以及 响应特定肽激动剂的细胞外传感器域工具包。 其次，我们将利用植物免疫网络独特的网络架构来设计合成 信号通路不干扰内源性动物信号通路 植物受体。 这里研究了通过与称为 BAK1 的共同受体激活的异二聚化产生的信号。 基于定义的磷酸化基序的底物磷酸化达到顶峰。 设计人类炎症信号通路以接受来自植物受体的正交输入 同时，我们将使用植物激酶底物纳入特定的磷酸调节信号因子。 植物受体：共受体异二聚化作为支架内源性人类免疫信号传导的平台 我们勇敢地说，工程化的途径将允许通过模块化调整。 多种肽配体，为当前免疫球蛋白或基于 GPCR 的合成工具提供了替代方案。 摘要我们的实验室准备部署受体去孤儿化和信号通路工程工具 利用植物-病原体共同进化驱动的巨大多样性（30 个品系）。