Critical evaluation of strategies for mineral fortification of staple food crops

Staple food crops, in particular cereal grains, are poor sources of key mineral nutrients. As a result, the world’s poorest people, generally those subsisting on a monotonous cereal diet, are also those most vulnerable to mineral deficiency diseases. Various strategies have been proposed to deal with micronutrient deficiencies including the provision of mineral supplements, the fortification of processed food, the biofortification of crop plants at source with mineral-rich fertilizers and the implementation of breeding programs and genetic engineering approaches to generate mineral-rich varieties of staple crops. This review provides a critical comparison of the strategies that have been developed to address deficiencies in five key mineral nutrients—iodine, iron, zinc, calcium and selenium—and discusses the most recent advances in genetic engineering to increase mineral levels and bioavailability in our most important staple food crops.     

High mineral contents explain the low construction cost of leaves, stems and fruits of tomato plants

The construction cost of plant tissues is used in crop models to convert the products of photosynthesis into biomass. As for other greenhouse crops, tomato tissues are specific in that they have a high mineral content. The consequences of this accumulation of minerals on the construction cost of the tissues and the possible interactions with the physiological age of the organs and with the CO2 concentration in the atmosphere was examined. For that purpose, three methods of estimating the construction cost were used and compared. Large quantities of minerals accumulated in the tissues of tomato plants (ranging from 0.05 in fruits to 0.26 g g^-1 DM in leaves). The subsequent dilution of the organic matter explained why the estimated construction cost of the dry matter (organic matter + minerals) was fairly low in comparison to that of other crops species. The construction cost was higher in fruits than in vegetative organs, partly because of a lower mineral content. It decreased by 7-12% from top to bottom of the canopy, following the increase in the physiological age of the tissues. This ontogenic drift was partly explained by the accumulation of minerals in the older organs. In the conditions of CO2 enrichment of a commercial greenhouse, no effect of CO2 concentration on the mineral content and on the construction cost of tissues was observed. Such a variability of the construction cost of tomato plant tissues due to the accumulation of minerals or to the ontogeny questions the use of standard values in crop models.Key words: Lycopersicon esculentum Mill., construction cost, heat of combustion, elemental composition, mineral content.      

气候变化对作物矿质元素利用率影响研究进展

作物矿质元素利用率对气候变化的响应是目前全球变化研究中既重要、又复杂,且认知最少的科学领域。这个科学问题的研究关系到解密或预测陆地植物及农作物矿质胁迫对全球气候变化响应的机理,为将来农业投入提供理论依据,是应对气候变化的当务之急。目前只有少数研究,通过模拟试验,探索性地开展了CO_2浓度或温度升高的环境条件下,矿质元素在土壤-植物系统迁移、分布和储存特征的研究。从相关的文献报道来看,CO_2浓度升高环境条件下,小麦和水稻作物籽粒中大量和痕量元素的富集水平一般呈下降趋势。但温度升高情况下,作物各器官对对矿质元素的吸收情况则更为复杂。正由于气候因素与植物矿质元素利用率之间关系的复杂性,在气候变化背景下,解密作物矿质胁迫对全球气候变化响应的科学问题,尚需改进试验方法、手段,从土壤性质、作物生态生理,以及农业生态系统中矿质元素在土壤-作物系统中迁移转化的过程,全面考察作物矿质元素利用率对气候变化的响应机理。     

Analysis of genetic factors that control shoot mineral concentrations in rapeseed (Brassica napus) in different boron environments

Mineral nutrients are essential for plant cell function, and understanding the genetic and physiological basis of mineral concentration is therefore important for the development of nutrient-efficient crop varieties that can cope with a shortage of mineral resources. In the present study, we investigated the profiles of B, Ca, Fe, Cu, Mg, P and Zn concentrations in shoots and analyzed the genetic variation in a rapeseed (Brassica napus) double haploid population at normal and deficient boron (B) levels in hydroponic conditions. Significant correlations between the concentrations of different minerals, such as Ca and Mg, Ca and P, and Cu and Fe, existed in both B environments. A total of 35 quantitative trait loci (QTL) and 74 epistatic interaction pairs for mineral concentrations were identified by whole genome analysis of QTL and epistatic interactions. The individual phenotypic contributions of the QTL ranged from 4.4% to 19.0%, and the total percentage of genetic variance that was due to QTL and epistatic interactions varied from 10.4% to 82.4%. Most of these QTL corresponded specifically to one of the two B conditions except for one stable main-effect P-QTL across the B environments. Three QTL for Ca and Mg were found to co-localize under normal B condition. These results revealed that genetic factors control mineral homeostasis in plants and multigenes involving ion transport are required to regulate mineral balance in plants under conditions of diverse nutrient stress. In addition, 26 genes involved in ion uptake and transport in Arabidopsis thaliana were in silico mapped onto the QTL intervals of B. napus by comparative genomic analysis. These candidate orthologous genes in B. napus allowed the selection of genes involved in the controlling mineral concentration that may account for the identified QTL.     

QTL for seed iron and zinc concentration and content in a Mesoamerican common bean (Phaseolus vulgaris L.) population

Iron and zinc deficiencies are human health problems found throughout the world and biofortification is a plant breeding-based strategy to improve the staple crops that could address these dietary constraints. Common bean is an important legume crop with two major genepools that has been the focus of genetic improvement for seed micronutrient levels. The objective of this study was to evaluate the inheritance of seed iron and zinc concentrations and contents in an intra-genepool Mesoamerican × Mesoamerican recombinant inbred line population grown over three sites in Colombia and to identify quantitative trait loci (QTL) for each mineral. The population had 110 lines and was derived from a high-seed iron and zinc climbing bean genotype (G14519) crossed with a low-mineral Carioca-type, prostrate bush bean genotype (G4825). The genetic map for QTL analysis was created from SSR and RAPD markers covering all 11 chromosomes of the common bean genome. A set of across-site, overlapping iron and zinc QTL was discovered on linkage group b06 suggesting a possibly pleiotropic locus and common physiology for mineral uptake or loading. Other QTL for mineral concentration or content were found on linkage groups b02, b03, b04, b07, b08 and b11 and together with the b06 cluster were mostly novel compared to loci found in previous studies of the Andean genepool or inter-genepool crosses. The discovery of an important new locus for seed iron and zinc concentrations may facilitate crop improvement and biofortification using the high-mineral genotype especially within the Mesoamerican genepool.     

Functional Characterization of 14 Pht1 Family Genes in Yeast and Their Expressions in Response to Nutrient Starvation in Soybean

Background

Phosphorus (P) is essential for plant growth and development. Phosphate (Pi) transporter genes in the Pht1 family play important roles in Pi uptake and translocation in plants. Although Pht1 family genes have been well studied in model plants, little is known about their functions in soybean, an important legume crop worldwide.

Principal Findings

We identified and isolated a complete set of 14 Pi transporter genes (GmPT1-14) in the soybean genome and categorized them into two subfamilies based on phylogenetic analysis. Then, an experiment to elucidate Pi transport activity of the GmPTs was carried out using a yeast mutant defective in high-affinity Pi transport. Results showed that 12 of the 14 GmPTs were able to complement Pi uptake of the yeast mutant with Km values ranging from 25.7 to 116.3 µM, demonstrating that most of the GmPTs are high-affinity Pi transporters. Further results from qRT-PCR showed that the expressions of the 14 GmPTs differed not only in response to P availability in different tissues, but also to other nutrient stresses, including N, K and Fe deficiency, suggesting that besides functioning in Pi uptake and translocation, GmPTs might be involved in synergistic regulation of mineral nutrient homeostasis in soybean.

Conclusions

The comprehensive analysis of Pi transporter function in yeast and expression responses to nutrition starvation of Pht1 family genes in soybean revealed their involvement in other nutrient homeostasis besides P, which could help to better understand the regulation network among ion homeostasis in plants.     

MSH1-Induced Non-Genetic Variation Provides a Source of Phenotypic Diversity in Sorghum bicolor

MutS Homolog 1 (MSH1) encodes a plant-specific protein that functions in mitochondria and chloroplasts. We showed previously that disruption or suppression of the MSH1 gene results in a process of developmental reprogramming that is heritable and non-genetic in subsequent generations. In Arabidopsis, this developmental reprogramming process is accompanied by striking changes in gene expression of organellar and stress response genes. This developmentally reprogrammed state, when used in crossing, results in a range of variation for plant growth potential. Here we investigate the implications of MSH1 modulation in a crop species. We found that MSH1-mediated phenotypic variation in Sorghum bicolor is heritable and potentially valuable for crop breeding. We observed phenotypic variation for grain yield, plant height, flowering time, panicle architecture, and above-ground biomass. Focusing on grain yield and plant height, we found some lines that appeared to respond to selection. Based on amenability of this system to implementation in a range of crops, and the scope of phenotypic variation that is derived, our results suggest that MSH1 suppression provides a novel approach for breeding in crops.     

小麦子粒铁、锌元素含量的研究进展

目前,铁、锌元素营养失衡已严重影响人类健康,而小麦作为人们的主要食物,其子粒中铁、锌元素含量普遍较低。因此,通过小麦育种策略提高铁、锌元素含量则被认为是最经济有效的手段,这也引起了国内外学者的广泛关注。本文概述了小麦子粒铁、锌元素含量的遗传差异、影响因素以及分子机理的研究现状,并展望了提高小麦子粒铁、锌元素含量的研究前景及途径。