Iron content and bioavailability in rice

Iron deficiency is probably the most widespread micronutrient deficiency in humans. Since rice is the main staple food for more than half of the global population, improving the iron content and bioavailability in rice is a perspective and an effective way to alleviate or even solve this problem. The present paper evaluates the iron content in different cereal foods (black rice, rice, red rice, sticky rice and millet) and different rice seeds as well as in the milling products, and the iron bioavailability of different forms. The data show that the iron content in black rice is higher than in the other rice types, and in rice chaff and husk the content is still fairly high. However, the iron content in rice and fine rice, which are the people's main staple food, is fairly low. As to the bioavailability of iron, it is fairly low in vegetable foods, almost at the level of 10%. Several methods have been applied to improve iron content and bioavailability in rice seed. Apart from breeding and genetic engineering, biochemical and physical approaches have frequently been used as prospective methods to regulate iron content and bioavailability in rice grains.     

Genetic engineering approaches to enrich rice with iron and vitamin A

Major staple crops are often deficient in some of the nutrients required in human diet. Thus, malnutrition is a major problem, especially in developing countries, where a diversified diet is not affordable for the majority. Several strategies have been adopted to improve nutrition. However, micronutrient deficiency is still widely spread. Rice is one of the most important staple foods for a large part of the world's population. Therefore, even a small improvement in nutritional content of rice seeds can have a dramatic impact on human health. Different approaches are being exploited to produce rice enhanced in nutrients with iron and provitamin A.     

Iron Fortification of Banana by the Expression of Soybean Ferritin

Iron deficiency anemia is one of the serious ailments related to nutrition in the developing countries. Fruit and vegetable crops favor the bioavailability of iron. Banana is consumed as a staple food in the tropics. Iron-fortified bananas provide an effective means of controlling the iron deficiency. Embryogenic cells of banana cv. Rasthali (AAB) were transformed with soybean ferritin cDNA using two different expression cassettes pSF and pEFE-SF to express ferritin. Transgenic nature of the regenerated plants was confirmed by PCR. Transgenic plants were regenerated and analyzed through PCR and PCR-Southern analysis. The expression of ferritin was confirmed by RT-PCR. Iron and zinc levels in the transgenic and control plants were estimated by atomic absorption spectroscopy. A 6.32-fold increase in iron accumulation and a 4.58-fold increase in the zinc levels were noted in the leaves of transgenic plants. Thus, iron- and zinc-fortified bananas could be developed as a functional food to overcome the malnutrition-related iron deficiency. This is the first report on the iron and zinc fortification of banana.     

Nicotianamine,a Novel Enhancer of Rice Iron Bioavailability to Humans

Background

Polished rice is a staple food for over 50% of the world''s population, but contains little bioavailable iron (Fe) to meet human needs. Thus, biofortifying the rice grain with novel promoters or enhancers of Fe utilization would be one of the most effective strategies to prevent the high prevalence of Fe deficiency and iron deficiency anemia in the developing world.

Methodology/Principal Findings

We transformed an elite rice line cultivated in Southern China with the rice nicotianamine synthase gene (OsNAS1) fused to a rice glutelin promoter. Endosperm overexpression of OsNAS1 resulted in a significant increase in nicotianamine (NA) concentrations in both unpolished and polished grain. Bioavailability of Fe from the high NA grain, as measured by ferritin synthesis in an in vitro Caco-2 cell model that simulates the human digestive system, was twice as much as that of the control line. When added at 1∶1 molar ratio to ferrous Fe in the cell system, NA was twice as effective when compared to ascorbic acid (one of the most potent known enhancers of Fe bioavailability) in promoting more ferritin synthesis.

Conclusions

Our data demonstrated that NA is a novel and effective promoter of iron utilization. Biofortifying polished rice with this compound has great potential in combating global human iron deficiency in people dependent on rice for their sustenance.     

Effects of different water management on absorption and accumulation of selenium in rice

Rice is the staple food for more than half of the world's population, but selenium (Se) is low in many rice growing countries. Water management model affects rice soil pH and Eh, and then affects the bioavailability of Se in soil. A pot experiment was conducted to investigate the effects of water management on soil Se species, dynamics and selenium uptake by rice plants. Sodium selenite was added to the soil so that the soil selenium content reached 0.5 mg kg^?1 to study the effects of 3 different water management modes on soil selenium uptake by rice plants. These three modes are flood irrigation (F), aerobic irrigation (A) and alternate flood and aerobic irrigation (AFA). The results showed that flooded irrigation treatment increased the soil soluble selenium concentration, and the selenium in soil solution mainly existed in the form of selenite and selenomethionine selenium oxide. The content of selenium in grain was 2.44 and 1.84 times that of flooded irrigation treatment under A and AFA respectively. The content of selenium in straw was 1.32 and 1.58 times that of flooded treatment under A and AFA respectively. After rice grain enzyme hydrolysis, HPLC-ICP-MS analysis showed that Selenomethionine was the main selenium speciation in rice grains. This study showed that aerobic flooded treatment is one of the most effective ways to increase selenium content in rice field.     

Differential degradation of photosystem I subunits under iron deficiency in rice

Rice (Oryza sativa) is one of the staple foods of the world. Iron (Fe) deficiency is a major abiotic stress factor that contributes world-wide to losses in crop yield and decline in nutritional quality. As cofactor for many enzymes and proteins, iron is an essential element. It plays a pivotal role in chlorophyll (Chl) biosynthesis, and iron deficiency may result in decreased Chl production and, thus, reduced photosynthetic capacity. Photosystem I (PSI) is a prime target of iron deficiency because of its high iron content (12 Fe per PS). To understand the protein level changes in the light-harvesting complex (LHC) of PSI (LHCI) under iron deficiency, rice seedlings were grown in Hoagland's nutrient medium with and without Fe. Chlorophyll content and photosynthetic efficiency decreased under iron deficiency. Protein gel blots probed with antibodies against the PSI core and Lhca 1-4 proteins revealed that the core subunits PsaA and PsaB remained stable under iron deficiency, whereas PsaC and PsaD decreased by about 50%, and PsaE was completely degraded. Among the LHCI subunits, Lhca1 and Lhca2 decreased by 40 and 50%, respectively, whereas Lhca3 and Lhca4 were completely degraded. We propose that the dissociation of LHCI subunits may be due to increased levels of reactive oxygen species, which is suggested by the increased activity of superoxide dismutase.     

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.     

Improving iron, zinc and vitamin A nutrition through plant biotechnology

Recent understanding of plant metabolism has made it possible to increase the iron, zinc and beta-carotene (provitamin A) content in staple foods by both conventional plant breeding and genetic engineering. Improving the micronutrient composition of plant foods may become a sustainable strategy to combat deficiencies in human populations, replacing or complementing other strategies such as food fortification or nutrient supplementation.     

Effect of different cooking methods on loss of iron and zinc micronutrients in fortified and non-fortified rice

Malnutrition is considered as major public health concern and is emerging challenge to food and nutrition security particularly in developing countries. Rice is the staple food and consumed by the half of the world's population which is the source of daily requirement of the nutrients. Attempts are being made to fortify rice with micronutrients, but the loss or retention of these micronutrients in different cooking methods is not well studied and documented especially in fortified rice. In the present study, paddy seeds of six Indian varieties were fortified with iron and zinc by parboiling process. Consequently, fortified polished rice had higher micronutrient contents (Fe, 106.31 ± 12.56; Zn, 97.72 ± 9.75) than non-fortified polished rice (Fe, 7.44 ± 1.05; Zn, 14.74 ± 2.94) expressed in ppm. Polished rice of both fortified and non-fortified were cooked under five different cooking conditions and analyzed for remaining iron and zinc content. Cooking rice in rice cooker without prior washing (NRC) retained highest concentration of Fe and Zinc in both fortified and non-fortified rice varieties. It also showed that fortified rice suffered higher percentage loss of micronutrient, than the non-fortified rice. But the average retained micronutrient amount measured in ppm, was higher in fortified rice (Fe, 43.54 ± 6.88; Zn, 36.7 ± 3.12) than in non-fortified rice (Fe, 4.24 ± 0.87; Zn, 9.3 ± 2.11). Hence, adopting appropriate cooking method, higher amount of micronutrients will be retained in the cooked food which will in turn help in combating the malnutrition and improve health.     

Genetic engineering approaches to improve the bioavailability and the level of iron in rice grains

Iron deficiency is the most widespread micronutrient deficiency world-wide. A major cause is the poor absorption of iron from cereal and legume-based diets high in phytic acid. We have explored three approaches for increasing the amount of iron absorbed from rice-based meals. We first introduced a ferritin gene from Phaseolus vulgaris into rice grains, increasing their iron content up to two-fold. To increase iron bioavailability, we introduced a thermotolerant phytase from Aspergillus fumigatus into the rice endosperm. In addition, as cysteine peptides are considered a major enhancer of iron absorption, we overexpressed the endogenous cysteine-rich metallothionein-like protein. The content of cysteine residues increased about seven-fold and the phytase level in the grains about 130-fold, giving a phytase activity sufficient to completely degrade phytic acid in a simulated digestion experiment. High phytase rice, with an increased iron content and rich in cysteine-peptide, has the potential to greatly improve iron nutrition in rice-eating populations. Received: 15 April 2000 / Accepted: 12 May 2000     

Availability of Food Iron

Iron has been extracted from 25 common foods under conditions resembling those prevailing in the stomach under physiological conditions. In most cases less than half the iron in the foods is released into solution. The soluble iron is mainly in ionizable form, except in the case of meat products and black pudding. The amount of food iron released is influenced by cooking and the presence of iron-binding substances in some foods. The total dietary iron probably does not represent the amount available for absorption.     

Biofortification of iron and zinc in rice and wheat

Iron and zinc are critical micronutrients for human health. Approximately two billion people suffer from iron and zinc deficiencies worldwide, most of whom rely on rice (Oryza sativa) and wheat (Triticum aestivum) as staple foods. Therefore, biofortifying rice and wheat with iron and zinc is an important and economical approach to ameliorate these nutritional deficiencies. In this review, we provide a brief introduction to iron and zinc uptake, translocation, storage, and signaling pathways in rice and wheat. We then discuss current progress in efforts to biofortify rice and wheat with iron and zinc. Finally, we provide future perspectives for the biofortification of rice and wheat with iron and zinc.     

Long-term trends in food habits of Asiatic black bears in the Misaka Mountains on the Pacific coast of central Japan

I did the food habits of the Asiatic black bear Ursus thibetanus from 1013 fecal samples collected between 1999 and 2005 in the Misaka Mountains on the Pacific coast of central Japan. The food habits of the bears showed clear seasonal changes, and I classified the food resources of the bears into three types. Staple foods were green vegetation in spring, soft mast (Prunus spp.) and insects in summer, and hard mast (Quercus spp.) in autumn. Alternative foods were green vegetation and other soft mast (Rubus spp.) in summer and Japanese chestnuts Castanea crenata and vine fruits in autumn. Foods of opportunity were hard mast (Quercus spp.) that had been shed in the previous autumn and were found in spring and other fruits in autumn. Seasonal food habits showed yearly variations: bears used alternative foods and foods of opportunity in response to the yearly variation in staple food amount, but the magnitude of variability of food habits differed among seasons, with large variability in autumn and small variability in summer and spring. The primary influence on the yearly variation in food habit is presumably the fluctuation in fruit production among years. Summer is probably the most difficult season in terms of the bear's food supply, because the number of fruiting species is limited and staple foods such as new green vegetation and fruits are less available. Long-term studies of the availability of the main food items and food habits of bears will be critical for further understanding these animals’ feeding ecology and for determining the factors that influence their behavior.     

不同类型特种稻种质营养及功能性成分含量的差异

本研究以具有有色种皮、巨胚、甜味、香味、糯性等单一特殊性状或2个以上特殊性状聚合于一体的新创制特种稻种质39份和1份白米种质(对照)为试验材料,进行了黑米、黑褐米、红米、香糯米、黑巨胚糯米、红巨胚糯米、巨胚糯米、黑甜米、红甜米、白甜米等不同类型特种稻种质的营养及功能性成分含量的差异评价。结果表明,供试特种稻类型在大部分氨基酸含量和矿质元素含量上与白米差异不显著,只在个别氨基酸和矿质元素含量上与白米呈显著或极显著差异。黑褐米、红米、黑巨胚糯米、红巨胚糯米、巨胚糯米、红甜米和白甜米等7种类型的赖氨酸含量显著或极显著高于白米,高2.91%~24.68%;黑米、黑褐米、红米、香糯米、黑巨胚糯米和红甜米等6种类型的铁含量显著或极显著高于白米,高17.62%~68.09%;黑褐米、红米、黑巨胚糯米、红巨胚糯米、黑甜米、红甜米、白甜米等7种类型的钙含量显著或极显著高于白米,高23.56%~49.46%;黑米、黑褐米、红米、黑甜米、红甜米、白甜米等6种类型的锌含量显著或极显著高于白米,高12.21%~55.87%。由此表明,具有有色种皮、巨胚、甜味、香味、糯性等单一特殊性状或2~3个特殊性状的聚合对赖氨酸含量与铁、钙和锌含量的提高方面具有一定的增加效应,认为在今后以赖氨酸、铁、钙和锌含量为目标性状的功能性水稻育种中,多个特殊性状的聚合将是增加上述功能性成分含量的有效途径之一。通过鉴定评价,从创新种质中还筛选出一些功能性成分含量相对较高的优异种质,白甜米1553和红巨胚糯米1476的赖氨酸含量较高,比白米分别高29.37%和23.42%;红米1439和红米1440的铁含量较高,比白米分别高99.05%和80.00%;黑甜米1511和黑甜米1515的硒含量较高,比白米分别高194.14%和136.48%;白甜米1551和香糯米1446的γ-氨基丁酸含量较高,比白米分别高14.56%和11.83%;黑巨胚糯米1464和黑米1432的花色苷含量较高,比供试18份有色稻米的平均值分别高253.23%和248.83%。这些新创制的功能性成分含量较高的水稻种质有待于今后在育种、生态适应性鉴定与产业化中进一步得到利用。     

Traditional healthful fermented products of Japan

A variety of fermentation products, such as foods containing probiotic bacteria, black rice vinegar (kurosu), soy sauce (shoyu), soybean-barley paste (miso), natto and tempeh, are sold in food stores in Japan. These fermented food products are produced by traditional methods that exploit mixed cultures of various non-toxic microorganisms. These microorganisms include lactic acid bacteria, acetic acid bacteria, sake yeast, koji molds and natto bacteria. Many traditional fermented foods have been studied and their effects on metabolism and/or immune system have been demonstrated in animal and/or human cells. This review summarizes the scientific basis for the effects of these traditional food products, which are currently produced commercially in Japan.     

Yeast diversity in rice-cassava fermentations produced by the indigenous Tapirapé people of Brazil

The Tapirapé people of the Tapi'it?wa tribe of Brazil produce several fermented foods and beverages, one of which is called 'cauim'. This beverage usually makes up the main staple food for adults and children. Several substrates are used in its production, including cassava, rice, corn, maize and peanuts. A fermentation using rice and cassava was conducted, and samples were collected at 4-h intervals for microbial analysis. The yeast population was low at the beginning of the fermentation and reached 6.9 x 10(7) CFU mL(-1) after 48 h. During the fermentation process common yeast species were identified by sequencing of the D1/D2 domain of the large-subunit (26S) rRNA gene. The predominant yeast species found was Candida tropicalis. Candida intermedia, Candida parapsilosis, Pichia guilliermondii, Saccharomyces cerevisiae and Trichosporon asahii were also found in high numbers during the fermentation. Exophiala dermatidis, often associated with blastomycosis, was found in the mass before inoculation and during the initial stages of the fermentation. Examination of these indigenous fermented foods may provide clues as to how food production and preservation can be expanded and thereby contribute to improve nutrition in native tribes in the region.     

水稻营养品质的改良

稻米是我国的主要食粮 ,但其蛋白质含量低、营养不够全面 ,满足不了人们对营养的需求。长期以来 ,人们一直采用传统的育种方法来选育高蛋白质的水稻新品种 ,但收效不大。近年来 ,水稻遗传转化技术的飞速发展和不断完善 ,应用生物技术改良水稻营养品质已逐步变为现实 ,并显示出诱人的前景。综述了利用生物技术进行水稻营养品质改良的途径、研究进展 ,并指出在水稻营养品质改良中存在的问题及解决途径。     

Iron bioavailability from diets containing isolated or intact sources of lignin

Experiments were conducted to determine effects of isolated lignin and intact lignin in foods on bioavailability of intrinsic iron in lignincontaining foods and of supplemental iron (FeSO₄·H₂O). Standard curve and slope ratio methodology were employed to determine iron bioavailability to chicks. In one experiment, lignin content of foods ranged from 2 to 25% and iron bioavailability ranged from −20 to 140%, but no association between lignin content and bioavailability existed. In other experiments, increasing dietary lignin concentration from some natural sources reduced total iron availability, whereas increasing isolated lignin concentration had no effect. These results suggest that lignin structure or other unidentified factors determine intrinsic iron availability. No lignin source significantly decreased supplemental iron bioavailability.     

Foliar Manganese Supply Enhances Crop Productivity,Net Benefits,and Grain Manganese Accumulation in Direct-Seeded and Puddled Transplanted Rice

Journal of Plant Growth Regulation - Manganese (Mn) deficiency in human nutrition is widespread in the rice–wheat cropping system where cereal grains are the staple food. Agronomic...