小麦铁锌营养品质研究进展

"隐性饥饿",即铁、锌等微量元素缺乏症,已成为困扰我国居民的首要营养不良问题.选育高铁、锌含量、强植酸酶活性或低植酸含量的"微量营养强化型"小麦品种对于改善我国西部居民的营养状况具有重要的意义.本文主要介绍小麦铁锌营养品质的遗传改良研究进展,包括铁锌营养品质的相关化学组分(铁、锌、植酸和植酸酶)及改善小麦铁锌营养品质的遗传途径等两方面,并指出了小麦铁锌营养品质的研究方向和工作重点.     

Effect of different soaking conditions on inhibitory factors and bioaccessibility of iron and zinc in pearl millet

Pearl millet was decorticated to obtain a bran rich and endosperm rich fraction. The two fractions were soaked in solutions with varying pH. Pearl millet grains were germinated and steamed followed by decortication to obtain two fractions. It was observed that bran rich fractions contained high concentrations of iron, zinc, polyphenols, phytic acid, fibre and flavonoids. Soaking for short duration of 3 h did not result in major mineral losses but decreased the inhibitory factors which depended on the pH. Alkaline soaking decreased flavonoid content by 62.7% in the endosperm rich fraction, while acidic soaking decreased phytic acid content to the maximum in the bran rich fraction. Combination of treatments like germination and heat decreased the phytate content to the maximum in the endosperm rich fraction. Acidic conditions improved zinc bioaccessibility in the bran rich fraction (35%) and iron bioaccessibility (2.5%) in the endosperm rich fraction. Bran rich fraction from germinated grain also had enhanced bioaccessibility of both the minerals but comparatively lesser when compared to soaking under acidic conditions. Soaking the grain components under slightly less than neutral conditions also decreased some of the inhibitory factors and improved the zinc bioaccessibility to some extent in the bran rich fraction.     

Tef: The Rising Ancient Cereal: What do we know about its Nutritional and Health Benefits?

This review covers the nutritional significance of tef cereal as compared to other common cereals with emphasis on carbohydrate content and starch digestibility, protein content, iron and zinc bioavailability and antioxidant potentials. Tef is a gluten free cereal and contains the highest iron and calcium among other cereals. It has high micro- and macro- nutritional profile and is becoming globally popular in the healthy grain food chain. Tef starch has a high gelatinization temperature, an essential precondition in the preparation of low glycemic index foods. There are significantly conflicting reports of iron content of tef ranging from 5 to 150 mg/100 g dm. The traditional fermentation of injera reduced majority of the phytic acid but no significant change to mineral bioavailability was observed. This review indicated that studies on starch digestibility, protein characterization, amylase and protease inhibitors, mineral bioavailability and antioxidant potentials are needed to further explore the nutritional and health benefits of tef.     

Phytase activity, phytate, iron, and zinc contents in wheat pearling fractions and their variation across production locations

Pearling is an effective method for evaluating the distribution of chemical components in wheat grain. Twelve pearling fractions (P₁–P₁₂) of wheat grain were obtained using two rice polishers for 10 cultivars (six soft red wheats and four hard white wheats) grown at two locations with different environmental conditions in Jiangsu Province, China. The results show that the effects of cultivar, location, and pearling on wheat flour phytase activity, phytate, iron, and zinc contents were all significant, with pearling having the greatest effect. All the four components showed a diminishing trend as pearling progressed from the outer layers to the inner part of wheat grain. Generally, the P₂ fraction (the outer 4–8% layer of wheat grain) had the highest phytase activity and phytate and iron contents, whereas the P₁ fraction (the outer 0–4% layer) ranked the highest for zinc content. Growing location had a large influence on grain phytase, phytate, and iron, but the differences between locations decreased as pearling level increased.     

Effect of germination-hydrothermal treatments followed by fractionation on inhibitory factors, β-carotene and iron-zinc bioaccessibility in pearl millet fractions

Combination of strategies involving germination-hydrothermal treatments and fractionation were adopted to separates the native and treated grain into coarse (bran & germ) and fine (endosperm) fractions. The inhibitory factors, polyphenol oxidase, and phytase activity were higher in coarse fractions. On treatment, the phytic acid content in the coarse fraction decreases significantly by 49% while polyphenols decreased 13% in the fine fraction and increased 6% in the coarse fraction. Galloyls reduced by 21% and 48% in the fine and coarse fraction while catechols increased by 74% in the fine fraction and reduced by 27% in the coarse fraction. In the fine fraction, the soluble and insoluble fibre increased by 27.8% and 28.7% while in the coarse fraction is reduced by 23.5% and 24.1%. The β-carotene content reduced slightly in the coarse fraction with no variation in the fine fraction. Iron bioaccessibility was enhanced from 1.79 to 5.7% in the fine fraction and 3.06–6.05% in the coarse fraction. Zinc bioaccessibility increased from 15.44 to 24.67% and 18.59–47.6% in the fine and coarse fraction, respectively. In the treated coarse fraction the iron-zinc bioaccessibility increased due to a significant reduction in phytic acid (49%), insoluble dietary fibre (24%), galloyls (48%) and catechols (27%).     

Transgenic Expression of the Recombinant Phytase in Rice （Oryza sativa）

In many plants, phytic acid (phytate, 1, 2, 3, 4, 5, 6-hexakisphosphate) is one of the main storage forms of phosphate. About 80% of phosphorus (P) in cereal plants, including rice is stored as phytic acid [1-2]. P in phytic acid can’t be utilized by monogastric animals including human, while it was estimated that only 1/3 of the total P in most of the vegetal feedstuff could be efficiently utilized by the livestock. Therefore, for animal feed with P supplementation is expected to meet the d…     

Phytase activity in extracts of flour and bran from wheat cultivars: enhanced extractability with β-glucanase and endo-xylanase

Phytase (EC 3.1.3.8) hydrolyzes phytic acid to myo-inositol and inorganic phosphate through intermediate myo-inositol phosphates. Microbial phytase has been employed to minimize the negative effects of phytic acid in cereal-based feeds, however, other sources such as wheat, would be natural alternatives. Investigations were therefore carried out to determine the levels of phytase activity in various cultivars and how the extraction of the enzyme may be enhanced using buffers fortified with glycanases. We screened 23 cultivars and the results showed that bran from hard white wheat cultivars had relatively lower levels of activity, ranging from about 1.5 to about 2.5 FTU/g bran, whereas hard red wheat cultivars had much higher levels, ranging from approximately 2 to 5.5 FTU/g bran. These levels were greatly enhanced, up to 5-fold, when extraction buffer contained a commercial preparation consisting of β-glucanase (EC 3.2.1.6) and endo-xylanase (EC 3.2.1.8) (Natugrain) (opt 1%) from BASF. The effect of glycanases was concentration and cultivar dependent, but not significantly influenced by temperature exposure of mixtures of samples with extraction buffers prior to extraction. Relative increases were more substantial in hard white than in hard red wheat cultivars. The additional value of supplementing grain-based diets with glycanases for monogastric animals is discussed.     

Yield benefit and underlying cost of insect-resistance transgenic rice: Implication in breeding and deploying transgenic crops

The rapid development of transgenic biotechnology has greatly promoted the commercialization of genetically modified (GM) crops including the insect-resistant crops worldwide. Apart from the enormous yield benefits brought by the GM crops, the cryptic fitness cost associated with transgenes has also been detected under experimental conditions although it is considered to be rare. To estimate the yield benefit and cost of insect-resistant GM rice, we studied field performances of three insect-resistant GM rice lines, involving their non-GM parental variety as comparison. Great benefits as estimated by the yield-related traits were observed in the GM rice lines when high insect pressure was recorded, but a cryptic yield loss was detected when the level of insect pressure was extremely low. Given the fact that cryptic yield loss presented in the GM rice lines under the low insect pressure, a strategic field deployment should be required when insect-resistant GM rice are commercialized to circumvent the unnecessary yield losses. This is probably true for other insect-resistant GM crops. Effective biotechnology and breeding measures are also needed to particularly minimize the potential underlying cost of an insect-resistance transgene before commercial production of the GM crops.     

Genotype × environment interaction for zinc and iron concentration of wheat grain in eastern Gangetic plains of India

Zinc and iron are important micronutrients for human health for which widespread deficiency occurs in many regions of the world including South Asia. Breeding efforts for enriching wheat grains with more zinc and iron are in progress in India, Pakistan and CIMMYT (International Maize and Wheat Improvement Centre). Further knowledge on genotype × environment interaction of these nutrients in the grain is expected to contribute to better understand the magnitude of this interaction and the potential identification of more stable genotypes for this trait. Elite lines from CIMMYT were evaluated in a multilocation trial in the eastern Gangetic plains (EGP) of India to determine genotype × environment (GE) interactions for agronomic and nutrient traits. Agronomic (yield and days to heading) data were available for 14 environments, while zinc and iron concentration of grains for 10 environments. Soil and meteorological data of each of the locations were also used. GE was significant for all the four traits. Locations showed contrasting response to grain iron and zinc. Compared to iron, zinc showed greater variation across locations. Maximum temperature was the major determinant for the four traits. Zinc content in 30–60 cm soil depth was also a significant determinant for grain zinc as well as iron concentration. The results suggest that the GE was substantial for grain iron and zinc and established varieties of eastern Gangetic plains India are not inferior to the CIMMYT germplasm tested. Hence, greater efforts taking care of GE interactions are needed to breed iron and zinc rich wheat lines.     

NaCl胁迫对低植酸小麦突变体材料种子萌发特性的影响

植酸广泛存在于禾谷类和豆类等作物种子中,近年来利用诱变技术选育低植酸作物新品种已成研究热点。本研究在不同NaCl浓度处理下,对前期通过60Co-γ辐射获得的9份低植酸小麦突变体材料进行萌发试验。结果表明,0.5%NaCl能促进种子萌发,而1.0%、1.5%NaCl明显抑制种子萌发,在其胁迫下,种子幼苗和主根生长受到抑制。初步筛选到耐盐性较好的低植酸小麦突变体材料4份,分别为lp14、lp49、lp55、lp50。     

In vitro dephytinization and bioavailability of essential minerals in several wheat varieties

Twelve wheat varieties were studied for their phytic acid, calcium, iron, zinc, copper and phosphorus contents, which respectively ranged between 114–166, 25.1–53.5, 3.41–5.55, 0.71–3.00, 0.65–1.32 and 298–314 mg/100 g. The molar ratios as Ca:Phy, Phy:Fe, Phy:Zn, Phy:Cu were found to be 0.14–0.29, 1.96–3.86, 5.11–20.5 and 13.0–23.9, respectively. Significant dephytinization, ranging between 35.3 and 69.3% in different varieties, was achieved on exogenous enzymatic treatment. Enzymatic dephytinization in the in vitro simulated gastrointestinal digestion resulted in significant increase in the bioavailability of essential minerals. The increase in bioavailability of calcium, iron, zinc and copper on exogenous enzymatic dephytinization ranged between, respectively (x-folds): 1.30–1.96, 1.11–1.52, 1.22–1.78 and 1.11–1.73.     

Meeting demands for increased cereal production in China

Meeting demands for increased cereal production in China is a great challenge and this paper provides updated information on cereal production and the potential adaptation of cropping systems to climate change, as well as on progress in improving yield potential and developing molecular markers and GM cereals in China. Maize production and soybean imports are increasing significantly to meet the strong demand for feed by a rapidly growing livestock industry. Extension of the rice and maize growing seasons in northeastern China and improvement of the cropping system through delayed wheat planting have contributed to improving cereal productivity despite changing climatic conditions. Significant improvements in yield potential of rice, maize, and wheat have been achieved. Comparative genomics has been successfully used to develop and validate functional markers for processing quality traits in wheat, and also for developing new varieties. Although transgenic Bt rice and maize, and maize expressing phytase have been developed, their commercialization has not been officially permitted. International collaboration has contributed significantly to cereal production by providing germplasm and improved crop management practices. Full integration of applied molecular technologies into conventional breeding programs and promotion of lower-input technologies, will play a key role in increasing and sustaining future cereal production.     

低植酸水稻种质资源筛选、遗传生理调控与环境生态适应性研究进展

提高或维持水稻产量的同时,提高稻米品质已成为目前水稻育种的首要目标之一。其中,通过降低籽粒中植酸等抗营养因子,增加锌、铁生物有效性以提升水稻营养品质,是目前水稻品质改良的一个重要方向。本文主要综述了水稻籽粒中植酸合成的代谢路径、低植酸水稻的筛选及相关功能基因的遗传特点、植酸生理代谢的调控网络、低植酸水稻农艺性状劣变和生态适应性降低的生理原因、籽粒植酸合成的环境调控效应等相关研究进展。可为低植酸水稻品质改良以及栽培调优提供借鉴。     

籽粒植酸含量降低率作为磷高效大豆品种辅助筛选指标的可行性研究

为了明确籽粒植酸含量降低率作为磷高效大豆品种筛选指标的可行性,本试验以26个大豆品种为材料,采用沙培盆栽法,测定正常磷和低磷水平下各品种产量、农艺性状、生理指标和植酸含量并分析各指标间的相关性。根据产量损失率将26个品种聚类成A^G共7个类型,A类品种产量损失率均小于10%,G类品种产量损失率大于60%;B^F各类品种产量损失率介于A、G中间。产量、植酸含量与株高、茎粗、叶绿素含量、净光合速率、地上及地下部含磷量均呈正相关关系,其中与茎粗和净光合速率呈显著正相关。在正常磷及低磷条件下,A^G各类型品种籽粒植酸含量变化无明显规律,但A类大豆品种籽粒植酸含量降低率小于30%,G类则大于80%。田间种植试验进一步证实植酸含量降低率低于30%的品种耐低磷指数大于1.0,属于强磷高效类型;G类品种耐低磷指数小于0.6,属于弱磷高效类型;B^F各类品种介于A、G中间。综上所述,正常磷与低磷水平下大豆籽粒植酸含量降低率可以作为又一个关键指标,与产量及部分农艺性状协同筛选磷高效大豆品种。     

Effect of wheat bran and enzyme addition on dough functional performance and phytic acid levels in bread

Effects of bran concentration, bran particle size distribution, and enzyme addition – fungal phytase, fungal alpha-amylase – on the mixing and fermentative behaviour of wheat dough and on the amount of phytic acid remaining in bread have been investigated using a factorial design of samples 2⁴. Bran concentration and bran particle size significantly affected all Farinograph parameters, whereas enzyme effects were particularly observed on both the water absorption of the flour and the parameters characterizing the overmixing. Water absorption was maximized in doughs with higher fine bran addition and/or in doughs with no enzymes, and was minimized in blends containing coarse added bran and alpha-amylase and/or alpha-amylase and phytase. alpha-Amylase addition had a significant positive effect on dough development and gassing power parameters during proofing. At low bran addition, phytate hydrolysis takes place to a greater extent than at high bran addition levels. Combination of bran with amylolytic and phytate-degrading enzymes could be advisable for overcoming the detrimental effect of bran on the mineral availability (phytase) or on the technological performance of doughs (alpha-amylase).     

Effect of wheat bran and enzyme addition on dough functional performance and phytic acid levels in bread

Effects of bran concentration, bran particle size distribution, and enzyme addition – fungal phytase, fungal alpha-amylase – on the mixing and fermentative behaviour of wheat dough and on the amount of phytic acid remaining in bread have been investigated using a factorial design of samples 2⁴. Bran concentration and bran particle size significantly affected all Farinograph parameters, whereas enzyme effects were particularly observed on both the water absorption of the flour and the parameters characterizing the overmixing. Water absorption was maximized in doughs with higher fine bran addition and/or in doughs with no enzymes, and was minimized in blends containing coarse added bran and alpha-amylase and/or alpha-amylase and phytase. alpha-Amylase addition had a significant positive effect on dough development and gassing power parameters during proofing. At low bran addition, phytate hydrolysis takes place to a greater extent than at high bran addition levels. Combination of bran with amylolytic and phytate-degrading enzymes could be advisable for overcoming the detrimental effect of bran on the mineral availability (phytase) or on the technological performance of doughs (alpha-amylase).     

Genetic variation for phytic acid content in mungbean(Vigna radiata L. Wilczek)

Mungbean(Vigna radiata L. Wilczek) is a short-duration legume crop cultivated for seeds that are rich in protein and carbohydrates. Mungbeans contain phytic acid(PA), an anti-nutritional factor that is the main storage form of organic phosphorus in seeds. It is a strong inhibitor against the absorption of nutrients including iron, zinc, calcium and magnesium in monogastric animals. Genotypes with low phytic acid(lpa) in seed may show increased assimilation of nutrients and be useful in breeding lpa cultivars. The present study was conducted to identify lpa sources, genetic variation, heritability, and association with seed coat color, inorganic phosphorus(IP), and seed size in 102 mungbean genotypes including released varieties, land races, mutants, and wild species grown in two seasons: summer 2011 and rabi 2012. PA and IP in dry seeds were estimated by modified colorimetric method and Chen's modified method,respectively. PA, IP, and 100-seed weight differed significantly in the two seasons. PA content in102 genotypes ranged from 5.74 to 18.98 mg g-1and 5.85 to 20.02 mg g-1in summer 2011 and rabi 2012, respectively. High heritability was found for PA(0.87 and 0.86) and seed size(0.82 and0.83) but low heritability for IP(0.61 and 0.60). A negative correlation was found between PA and seed size(r =-0.183 and-0.267). Yellow and green seed coat genotypes contained significantly less PA than black seed coat genotypes. Cluster analysis revealed the distinctness of wild species, land races and cultivated varieties on the basis of PA content. The genotypes YBSM(6.001 mg g-1) and JL-781(6.179 mg g-1) showed lowest PA. These lpa sources can be used to develop high-yielding mungbean cultivars with low phytic acid.     

Transgenic cereals: Current status and future prospects

This review summarises the history of transgenic (GM) cereals, principally maize, and then focuses on the scientific literature published in the last two years. It describes the production of GM cereals with modified traits, divided into input traits and output traits. The first category includes herbicide tolerance and insect resistance, and resistance to abiotic and biotic stresses; the second includes altered grains for starch, protein or nutrient quality, the use of cereals for the production of high value medical or other products, and the generation of plants with improved efficiency of biofuel production. Using data from field trial and patent databases the review considers the diversity of GM lines being tested for possible future development. It also summarises the dichotomy of response to GM products in various countries, describes the basis for the varied public acceptability of such products, and assesses the development of novel breeding techniques in the light of current GM regulatory procedures.     

Localization of iron in rice grain using synchrotron X-ray fluorescence microscopy and high resolution secondary ion mass spectrometry

Cereal crops accumulate low levels of iron (Fe) of which only a small fraction (5–10%) is bioavailable in human diets. Extensive co-localization of Fe in outer grain tissues with phytic acid, a strong chelator of metal ions, results in the formation of insoluble complexes that cannot be digested by humans. Here we describe the use of synchrotron X-ray fluorescence microscopy (XFM) and high resolution secondary ion mass spectrometry (NanoSIMS) to map the distribution of Fe, zinc (Zn), phosphorus (P) and other elements in the aleurone and subaleurone layers of mature grain from wild-type and an Fe-enriched line of rice (Oryza sativa L.). The results obtained from both XFM and NanoSIMS indicated that most Fe was co-localized with P (indicative of phytic acid) in the aleurone layer but that a small amount of Fe, often present as “hotspots”, extended further into the subaleurone and outer endosperm in a pattern that was not co-localized with P. We hypothesize that Fe in subaleurone and outer endosperm layers of rice grain could be bound to low molecular weight chelators such as nicotianamine and/or deoxymugineic acid.