Optimization by mitochondrial metabolism of photosynthetic carbon assimilation

机译：光合碳同化的线粒体代谢优化

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Photosynthesis is a process of reduction and respiration is a process of oxidation. Both the processes provide ATP for cellular needs. The nature of these two metabolic pathways implies that they complement each other. The sites of photosynthesis andrespiration are chloroplasts and mitochondria. Although chloroplasts and mitochondria are traditionally considered to be autonomous organelles, recent literature has established that these two organelles are not only interdependent in their functions but also are mutually beneficial in their interaction. There are reviews that examine in detail the different aspects of mitochondrial respiration in the light and its interaction with photosynthesis (Raghavendra et al. 1994, Kromer 1995, Gardestrom and Lernmark 1995, Hoefnagel et al. 1998, Padmasree and Raghavendra 1998, 2000, Atkin et al. 2000, Gardestrom et al. 2001, Padmasree et al. 2001).

机译：光合作用是一种减少和呼吸的过程是氧化过程。这两个过程都提供了ATP的蜂窝需求。这两个代谢途径的性质意味着它们彼此相互补充。光合作用的位点是叶绿体和线粒体。虽然传统上叶绿体和线粒体被认为是自主体细胞器，但最近的文献已经确定，这两个细胞器不仅相互依存在其功能中，而且还在其相互作用中是互利的。有综述，详细介绍线粒体呼吸的不同方面，以及它与光合作用的互动（Raghavendra等，1994，Kromer 1995，GardeRrom和Lernmark 1995，Hoefnagel等，1998，Padmasree和Raghavendra 1998,2000，Atkin等人。2000，Gardestrom等人。2001年，Padmasree等，2001）。

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《International Congress on Photosynthesis》|2001年||共6页
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L. Padmavathi; K. Padmasree; A. S. Raghavendra;
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中图分类 Q945-532;
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alternative pathway; chloroplasts; cytochrome pathway; interorganelle interaction; respiration;

机译：替代途径;叶绿体;细胞色素途径;室内联的互动;呼吸;

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专利

1. Importance of ROS and antioxidant system during the beneficial interactions of mitochondrial metabolism with photosynthetic carbon assimilation [J] . Dinakar C, Abhaypratap V, Yearla SR, Planta: An International Journal of Plant Biology . 2010,第2期

机译：在线粒体代谢与光合碳同化的有益相互作用中，ROS和抗氧化系统的重要性
2. Importance of ROS and antioxidant system during the beneficial interactions of mitochondrial metabolism with photosynthetic carbon assimilation [J] . Challabathula Dinakar, Vishwakarma Abhaypratap, Srinivasa Rao Yearla, Planta . 2010,第2期

机译：在线粒体代谢与光合碳同化的有益相互作用中，ROS和抗氧化系统的重要性
3. Beneficial interactions of mitochondrial metabolism with photosynthetic carbon assimilation [Review] [J] . Raghavendra AS, Padmasree K Trends in Plant Science . 2003,第11期

机译：线粒体代谢与光合碳同化的有益相互作用[综述]
4. Optimization by mitochondrial metabolism of photosynthetic carbon assimilation [C] . L. Padmavathi, K. Padmasree, A. S. Raghavendra International Congress on Photosynthesis . 2001

机译：光合碳同化的线粒体代谢优化
5. Improved temperature response functions for modeling photosynthetic carbon assimilation in the context of rising carbon dioxide. [D] . Bernacchi, Carl Joseph. 2002

机译：改进的温度响应函数，用于在二氧化碳上升的情况下对光合碳同化进行建模。
6. Optimizing the Distribution of Resources between Enzymes of Carbon Metabolism Can Dramatically Increase Photosynthetic Rate: A Numerical Simulation Using an Evolutionary Algorithm [O] . Xin-Guang Zhu, Eric de Sturler, Stephen P. Long 2007

机译：优化碳代谢酶之间的资源分配可以显着提高光合速率：使用进化算法的数值模拟
7. Low CO 2 results in a rearrangement of carbon metabolism to support C 4 photosynthetic carbon assimilation in Thalassiosira pseudonana [O] . Adam B. Kustka, Allen J. Milligan, Haiyan Zheng, 2014

机译：低二氧化碳导致碳代谢的重排，以支持Thalassiosira伪p纳的C 4光合碳同化

Optimization by mitochondrial metabolism of photosynthetic carbon assimilation

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