Plant Biosystems Design for a Carbon-Neutral Bioeconomy.

Q2 Agricultural and Biological Sciences
生物设计研究(英文) Pub Date : 2020-06-11 eCollection Date: 2020-01-01 DOI:10.34133/2020/7914051
Udaya C Kalluri, Xiaohan Yang, Stan D Wullschleger
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引用次数: 0

Abstract

Our society faces multiple daunting challenges including finding sustainable solutions towards climate change mitigation; efficient production of food, biofuels, and biomaterials; maximizing land-use efficiency; and enabling a sustainable bioeconomy. Plants can provide environmentally and economically sustainable solutions to these challenges due to their inherent capabilities for photosynthetic capture of atmospheric CO2, allocation of carbon to various organs and partitioning into various chemical forms, including contributions to total soil carbon. In order to enhance crop productivity and optimize chemistry simultaneously in the above- and belowground plant tissues, transformative biosystems design strategies are needed. Concerted research efforts will be required for accelerating the development of plant cultivars, genotypes, or varieties that are cooptimized in the contexts of biomass-derived fuels and/or materials aboveground and enhanced carbon sequestration belowground. Here, we briefly discuss significant knowledge gaps in our process understanding and the potential of synthetic biology in enabling advancements along the fundamental to applied research arc. Ultimately, a convergence of perspectives from academic, industrial, government, and consumer sectors will be needed to realize the potential merits of plant biosystems design for a carbon neutral bioeconomy.

Abstract Image

碳中和的生物经济的植物生物系统设计。
我们的社会面临着多重艰巨的挑战,包括找到缓解气候变化的可持续解决方案;高效生产食品、生物燃料和生物材料;最大限度地提高土地利用效率;以及实现可持续的生物经济。植物可以为这些挑战提供环境和经济上可持续的解决方案,因为它们具有光合作用捕获大气二氧化碳、将碳分配到各种器官和分配成各种化学形式的内在能力,包括对土壤总碳的贡献。为了提高作物生产力并同时优化地上和地下植物组织的化学成分,需要变革性的生物系统设计策略。需要协调一致的研究工作,以加快植物品种、基因型或在地上生物质衍生燃料和/或材料和地下强化碳固存的背景下合作的品种的开发。在这里,我们简要讨论了我们对过程理解中的重大知识差距,以及合成生物学在推动从基础到应用研究的发展方面的潜力,消费者部门将需要实现碳中和的生物经济的植物生物系统设计的潜在优势。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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来源期刊
CiteScore
3.90
自引率
0.00%
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0
审稿时长
12 weeks
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