Localization of translation and non-translated mRNAs; functions, mechanisms and novel compartments

翻译和非翻译 mRNA 的定位；

• 批准号: RGPIN-2019-07009
• 负责人: Zerges, William
• 金额: $ 3.64万
• 依托单位: Concordia University
• 依托单位国家: 加拿大
• 项目类别: Discovery Grants Program - Individual
• 财政年份: 2022
• 资助国家: 加拿大
• 起止时间: 2022-01-01 至 2023-12-31
• 项目状态: 已结题
• 来源: https://www.nserc-crsng.gc.ca/ase-oro/Details-Detailles_eng.asp?id=745961
• 关键词: Localization; translation; non; translated; mRNAs

Plants and algae obtain energy for growth and reproduction from light using a process called photosynthesis. Photosynthesis occurs in subcellular organelles called chloroplasts. Our previous research revealed that chloroplasts contain compartments for the synthesis of proteins and RNA quality control. We are analyzing these compartments as an avenue to understand biogenesis and quality control in this organelle and, we hope, reveal general principles of Cell Biology. One goal of this research program is to understand how the membranes that make up thylakoid vesicles within chloroplasts are made. Thylakoid vesicles carry out the light-driven reactions of photosynthesis. We have identified a special region of the membranous envelope that encloses the chloroplast where proteins and chlorophyll of the thylakoids are generated. We show for the first time that the ribosomes of the cell's cytoplasm are synthesizing proteins in direct contact with the chloroplast. This has been show for most other organelles, but not for chloroplasts. Characterization of the composition of this novel biogenic domain of the chloroplast envelope will lead to new insights regarding the long-standing mystery regarding the developmental origins of thylakoid membranes and how they arise from the chloroplast envelope. Another goal is to characterize a compartment within the chloroplast that handles quality control of RNA. RNA is an important molecule in the transfer of genetic information from the gene to generate functional proteins. Chloroplasts have their own genome and gene expression system because they evolved from a free-living photosynthetic bacterium which took up residence in the primordial plant cell some 1-2 billion year ago. Since, chloroplasts have retained a downsized genome and gene expression system, including RNA. We identified and study structures are called "chloroplast stress granules" which handle RNA that has just left the protein synthesis machinery and is not being translated. These chloroplast stress granules are similar to stress granules found in all eukaryotic cells examined and even in bacteria called stress granules. We will characterize chloroplast stress granules to learn about how this organelle handles RNA quality control and, we hope, provide general insights into stress granule functions in all organisms. In summary, the results will be relevant to the development of biotechnologies for Canadian industries because algae are used in the food industry and as biosensors for environmental pollutants for decades. Algae are being engineered to efficiently produce high-value molecules at industrial scales; e.g. pharmaceuticals, vaccines, and food supplements. Realization of this potential will benefit from our research results regarding how proteins are synthesized in chloroplasts. The results will also contribute to the basic knowledge that will be required for the biotechnological improvement of crop plants in agriculture.

植物和藻类利用光合作用从光中获得生长和繁殖所需的能量。光合作用发生在称为叶绿体的亚细胞器中。我们以前的研究表明，叶绿体含有蛋白质合成和RNA质量控制的隔室。我们正在分析这些隔间，作为了解这个细胞器中生物发生和质量控制的途径，我们希望揭示细胞生物学的一般原理。 这项研究计划的一个目标是了解叶绿体内构成类囊体囊泡的膜是如何形成的。类囊体囊泡进行光合作用的光驱动反应。我们已经确定了一个特殊的区域的膜包膜，包围叶绿体的蛋白质和叶绿素的类囊体的产生。我们第一次证明了细胞质中的核糖体与叶绿体直接接触，合成蛋白质。这在大多数其他细胞器中已经显示出来，但在叶绿体中却没有。这一新的生物结构域的叶绿体被膜的组成的表征将导致新的见解，长期以来的奥秘，关于类囊体膜的发育起源，以及它们是如何产生的叶绿体被膜。 另一个目标是表征叶绿体内处理RNA质量控制的隔室。RNA是从基因转移遗传信息以产生功能蛋白质的重要分子。叶绿体有自己的基因组和基因表达系统，因为它们是从大约10 - 20亿年前在原始植物细胞中居住的自由生活的光合细菌进化而来的。从那时起，叶绿体保留了缩小的基因组和基因表达系统，包括RNA。我们确定和研究的结构被称为“叶绿体应激颗粒”，它处理刚刚离开蛋白质合成机器而没有被翻译的RNA。这些叶绿体应激颗粒类似于在所有被检测的真核细胞中发现的应激颗粒，甚至在细菌中也被称为应激颗粒。我们将描述叶绿体压力颗粒，了解这个细胞器如何处理RNA质量控制，我们希望，提供一般的见解在所有生物体的压力颗粒功能。总之，研究结果将与加拿大工业生物技术的发展有关，因为藻类几十年来一直用于食品工业和作为环境污染物的生物传感器。藻类正在被改造以在工业规模上有效地生产高价值分子;例如药物，疫苗和食品补充剂。实现这一潜力将受益于我们的研究成果，关于蛋白质是如何合成的叶绿体。研究结果还将有助于获得农业作物生物技术改良所需的基本知识。