最环保的革命——利用植物的力量帮助应对气候变化

Q4 Biochemistry, Genetics and Molecular Biology
Biochemist Pub Date : 2022-06-08 DOI:10.1042/bio_2022_113
Wolfgang Busch, Charlotte Miller
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引用次数: 2

摘要

当我们继续寻找能够阻止全球变暖的技术时,让我们花点时间想想植物。造成气候危机的一个关键因素是大气中二氧化碳的积累。数十亿年来,植物一直在捕捉二氧化碳,这使它们成为地球上最久经考验的碳捕捉机器。植物通过光合作用固定二氧化碳。经过多年的研究,我们现在知道了这一过程的关键调控因素,并掌握了开始改造具有更高光合能力的植物的知识。除了提高固碳效率外,我们还必须找到一种稳定储存植物捕获的碳的方法。要做到这一点,我们可以看看植物体的地下部分——根系。植物的根充满了碳,也会向土壤中散发富含碳的分子。设计具有更深、更广泛根系的未来植物,增强化学成分,增加碳含量,降低生物降解速度,提供了一种将大气中的碳储存在地下多年的方法。有了优化的根系,这些植物也将更好地探索周围土壤的水分和养分,这将最终提高植物的性能。这种方法还提供了一种补充我们碳耗尽的土壤的方法,这将通过改善水和养分的保留来提高土壤质量。因此,利用植物捕获碳的自然能力,不仅可以恢复碳循环的平衡,还可以改善土壤质量和未来的作物性能。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
The greenest revolution – harnessing the power of plants to help combat climate change
As we continue searching for the technologies that will halt global warming, let us take a moment to think about plants. A key contributor to our climate crisis is the accumulation of carbon dioxide in the atmosphere. Plants have been capturing carbon dioxide for billions of years, making them the most tried and tested carbon capture machinery on the planet. Plants fix carbon dioxide as part of photosynthesis. After years of research, we now know the key regulators of this process and have the knowledge to start engineering plants with increased photosynthetic capacity. In addition to improving the efficiency of carbon fixation, we must also find a way to stably store the carbon captured by plants. To achieve this, we can look to the below-ground part of the plant body – the root system. Plant roots are packed full of carbon and also exude carbon-rich molecules into the soil. Engineering future plants with deeper, more extensive root systems, with enhanced chemical composition that increases carbon content and reduces the rate of biodegradation, offers a way to store atmospheric carbon fixed by plants below ground for years to come. With optimized root systems, these plants would also be better equipped to explore their surrounding soils for water and nutrients, which would ultimately improve plant performance. This approach also offers a way to replenish our carbon-depleted soils, which would increase soil quality by improving water and nutrient retention. Harnessing the plants' natural ability to capture carbon, thus provides a way to not only restore balance to the carbon cycle, but also improve soil quality and future crop performance.
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来源期刊
Biochemist
Biochemist Biochemistry, Genetics and Molecular Biology-Biochemistry, Genetics and Molecular Biology (all)
CiteScore
1.20
自引率
0.00%
发文量
41
期刊介绍: This lively and eclectic magazine for all life scientists appears six times a year. Its quirky style and astute selection of serious and humorous articles ensures that the magazine"s appeal is by no means restricted to that of the avid biochemist. Specially commissioned articles from leading scientists bring a popular science perspective direct to you! Forthcoming themes include: RNAi, Money in Science, Extremophiles, Biosystems and Mathematical Modelling, Renascence of Mitochondria, Prions & Protein factors, Imaging live cells and Model organisms.
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