How elevated CO2 affects our nutrition in rice, and how we can deal with it

Increased concentrations of atmospheric CO2 are predicted to reduce the content of essential elements such as protein, zinc, and iron in C3 grains and legumes, threatening the nutrition of billions of people in the next 50 years. However, this prediction has mostly been limited to grain crops, and m...

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Veröffentlicht in:	PloS one 2019-03, Vol.14 (3), p.e0212840-e0212840
Hauptverfasser:	Ujiie, Kazuhiro, Ishimaru, Ken, Hirotsu, Naoki, Nagasaka, Seiji, Miyakoshi, Yuichi, Ota, Masako, Tokida, Takeshi, Sakai, Hidemitsu, Usui, Yasuhiro, Ono, Keisuke, Kobayashi, Kazuhiko, Nakano, Hiroshi, Yoshinaga, Satoshi, Kashiwagi, Takayuki, Magoshi, Jun
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Sprache:	eng
Schlagworte:	Agricultural production Atmosphere - chemistry Biology and Life Sciences Carbon dioxide Carbon Dioxide - physiology Carbon dioxide atmospheric concentrations Carbon dioxide concentration Chromosomes Crop Production - methods Crop Production - trends Crop science Crops Crops, Agricultural - chemistry Crops, Agricultural - physiology Earth Sciences Ecology and Environmental Sciences Environmental science Fabaceae - chemistry Fabaceae - physiology Feeding Behavior - physiology Food Supply Genetic improvement Grain Grain crops Human nutrition Humans Iron Legumes Medicine and Health Sciences Micronutrients - administration & dosage Micronutrients - physiology Nitrogen Nutrition Oryza - chemistry Oryza - physiology Photosynthesis - physiology Physical Sciences Plants, Genetically Modified - chemistry Plants, Genetically Modified - physiology Predictions Proteins Research and Analysis Methods Rice Translocation Zinc
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creator	Ujiie, Kazuhiro Ishimaru, Ken Hirotsu, Naoki Nagasaka, Seiji Miyakoshi, Yuichi Ota, Masako Tokida, Takeshi Sakai, Hidemitsu Usui, Yasuhiro Ono, Keisuke Kobayashi, Kazuhiko Nakano, Hiroshi Yoshinaga, Satoshi Kashiwagi, Takayuki Magoshi, Jun
description	Increased concentrations of atmospheric CO2 are predicted to reduce the content of essential elements such as protein, zinc, and iron in C3 grains and legumes, threatening the nutrition of billions of people in the next 50 years. However, this prediction has mostly been limited to grain crops, and moreover, we have little information about either the underlying mechanism or an effective intervention to mitigate these reductions. Here, we present a broader picture of the reductions in elemental content among crops grown under elevated CO2 concentration. By using a new approach, flow analysis of elements, we show that lower absorption and/or translocation to grains is a key factor underlying such elemental changes. On the basis of these findings, we propose two effective interventions-namely, growing C4 instead of C3 crops, and genetic improvements-to minimize the elemental changes in crops, and thereby avoid an impairment of human nutrition under conditions of elevated CO2.
doi_str_mv	10.1371/journal.pone.0212840
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subjects	Agricultural production Atmosphere - chemistry Biology and Life Sciences Carbon dioxide Carbon Dioxide - physiology Carbon dioxide atmospheric concentrations Carbon dioxide concentration Chromosomes Crop Production - methods Crop Production - trends Crop science Crops Crops, Agricultural - chemistry Crops, Agricultural - physiology Earth Sciences Ecology and Environmental Sciences Environmental science Fabaceae - chemistry Fabaceae - physiology Feeding Behavior - physiology Food Supply Genetic improvement Grain Grain crops Human nutrition Humans Iron Legumes Medicine and Health Sciences Micronutrients - administration & dosage Micronutrients - physiology Nitrogen Nutrition Oryza - chemistry Oryza - physiology Photosynthesis - physiology Physical Sciences Plants, Genetically Modified - chemistry Plants, Genetically Modified - physiology Predictions Proteins Research and Analysis Methods Rice Translocation Zinc
title	How elevated CO2 affects our nutrition in rice, and how we can deal with it
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