Characterization of sorghum grain and evaluation of sorghum flour in a Chinese egg noodle system

Sorghum is a gluten free grain that has potential to be used as an alternative to wheat flour for the Celiac Sprue market. There are thousands of sorghum lines that have not been characterized for grain, flour or end product quality. The objective of the research was to gain an understanding among grain sorghum quality factors and Chinese egg noodles quality. Four sorghum hybrids were characterized and evaluated for kernel characteristics, proximate analysis, flour composition and end product in a Chinese egg noodle system. Kernel size and weight affected the flour particle size and the amount of starch damage. Flour with fine particle size and high starch damage conferred noodles with high firmness and high tensile strength. Water uptake was highest for flour with smaller particle size (38 μm at 50% volume) and higher starch damage (6.14%). Cooking losses for all samples were below 10%. Starch of particle size <5 μm (C-type) contributed to firmer and higher tensile strength noodles. Water absorption was significantly affected by flour particle size, starch particle size and starch damage. Through control of sorghum grain and flour quality characteristics it is possible to manufacture a Chinese egg noodle with good physical attributes.     

Effect of A- and B-granules of wheat starch on Chinese noodle quality

To investigate the effect of A- and B-type granules of wheat starch on noodle quality, the fractionation and reconstitution method was used to prepare noodles with five different ratios of A-to B-granules (100A-0B, 75A-25B, 50A-50B, 25A-75B, 0A-100B). The pasting and swelling properties of reconstituted flours and the microstructure of noodles observed under a confocal laser scanning microscope (CLSM) indicated that there were at least two aspects were responsible for the changes in noodle quality. First, the water distribution, texture and cooking quality of noodles were influenced by the different physicochemical properties of A- and B-granules; and second, the gluten structure in noodles was altered by the granule size distribution, which further led to a difference in noodle quality. In general, with increasing number of B-granules, the A₂₂ (the proportion of less immobilized water) of raw noodles and the hardness, resilience and chewiness of cooked noodles increased first and then decreased, while the cooking loss, water absorption and protein loss showed the reverse trend. Raw noodle samples containing 50A-50B had the minimum T₂₂ (less immobilized water) but the maximum A₂₂ and, when cooked, had the greatest hardness, chewiness and resilience and the least cooking loss (6.6%) and water absorption (166.1%). These results have important implications for illustrating the mechanism by which A- and B-granules affect noodle quality and guide efforts to improve noodle quality and wheat breeding.     

The co-operative interaction of puroindolines in wheat grain texture may involve the hydrophobic domain

The puroindoline genes are causatively associated with wheat grain hardness, a commercially significant property. The proteins puroindoline (PIN) A and B are both required in their wild-type (WT) to impart soft grain texture, and absence of/mutations in either/both PIN(s) results in hard wheat. However, there is no biochemical clarity yet that explains this interdependence. This work critically analyses the roles of the tryptophan-rich domain (TRD), the little-known hydrophobic domain (HD), and certain other residues, in the physical associations of PINs. Site-directed mutagenesis-PCR was used to delete the TRD or HD and introduce an Arg39Gly substitution in PINA. The PINB-D1c mutant (Leu60Pro) was also investigated. The yeast two-hybrid system was used to assess the protein–protein interactions (PPI) of proteins. The TRD deletion or Arg39Gly substitution in PINA did not adversely affect its PPI, while deletion of HD resulted in a significant reduction. No effect on PPI was observed for Leu60Pro PINB. The results of this expression system strongly suggest that the HD is essential (but not sufficient) in higher-order associations of PINs. We propose a two-event model that explains the co-operative action of the PINs and why mutations outside the TRD may alter grain texture.     

Association analysis of Puroindoline-D1 and Puroindoline b-2 loci with 13 quality traits in European winter wheat (Triticum aestivum L.)

Grain hardness, a major determinant influencing end-use quality of common wheat, is mainly controlled by Puroindoline a-D1 (Pina-D1) and Puroindoline b-D1 (Pinb-D1) genes. Recently, additional puroindoline genes, designated Puroindoline b-2 (Pinb-2), were described. This study examined frequencies of Pin-D1 alleles and Pinb-2 variants in 94 West European wheat genotypes and assessed their association with 13 quality traits considering population and family structure. The survey was completed by analyzing the Grain softness protein-1 gene. Results indicated sequence variation only for Pinb-D1 and Pinb-B2 genes. Pinb-D1b was the predominant hard allele. Pinb-B2v3-1 was the most common Pinb-2 variant, followed by a newly discovered variant Pinb-B2v3-5. Association mapping carried out in the whole sample population showed that Pinb-D1 alleles were associated with 11 quality traits, whereas Pinb-B2 variants were only associated with semolina extraction. Considering only the panel of hard wheat genotypes, variation for flour ash content, sedimentation value, gluten index and loaf volume was found to be associated with Pinb-D1 mutations suggesting that different Pinb-D1 mutations might have particular effects on quality traits. Our study indicated that Pinb-D1d was associated with inferior sedimentation value, gluten index and loaf volume, for which reason this mutation should be disregarded in breeding for quality wheat.     

Effect of NaCl on rheological properties of dough and noodle quality

To assess the effect of NaCl on processing properties of different varieties of wheat flour and noodle quality, the rheological properties of dough, and the quality of white salted noodles made from three different varieties of wheat flour were evaluated. The results showed that the addition of NaCl had different effects on the rheological properties of different varieties of wheat flour. As NaCl concentration increased, the stability time of both intermediate-gluten and weak-gluten wheat flour increased, while that of strong-gluten wheat flour increased initially and then remained stable. The developing time of strong-gluten wheat flour increased, while those of both intermediate-gluten and weak-gluten wheat flour did not change significantly. The energy values of intermediate- and weak-gluten wheat flour did not change significantly while that of strong-gluten wheat flour increased. NaCl had no apparent effects on the hardness, springiness, gumminess, chewiness and resilience of noodles. The cooking loss of fresh noodles increased positively with increasing NaCl concentration. Microstructure of noodles showed that gluten network structure of noodles became more and more dense with increasing NaCl concentration. The effect of NaCl on gluten protein contributed to the change of rheological properties and noodle quality.     

Molecular characterization of the Puroindoline a-D1b allele and development of an STS marker in wheat (Triticum aestivum L.)

Kernel hardness is mainly controlled by one major genetic locus on the short arm of chromosome 5D in bread wheat. Twelve Chinese and CIMMYT wheat cultivars were characterized for the deletion region of Pina-D1b genotype and developing a novel STS marker for this allele. PCR and SDS-PAGE were used to confirm the Pina-D1b genotype, and then 20 pairs of primers were designed to amplify the fragment including deletion region in Pina-D1b genotype by primer walking strategy. An STS marker Pina-N spanning deletion region in Pina-D1b was developed and sequencing results showed that all of 10 Pina-D1b genotypes uniformly possessed a 15,380 bp deletion in comparison with that of Chinese Spring with wild type. This study provided an alternative method to exam Pina-D1b by molecular marker and will accelerate identification of puroindoline alleles in bread wheat.     

Puroindoline genotype,starch granule size distribution and milling quality of wheat

Genetically-diverse wheat samples from the Australian Winter Cereals Collection propagated in two environments were sequenced to identify puroindoline genotypes then the relationships between flour yield, genotype, starch granule size distribution and starch-bound puroindoline protein content were investigated. The Pina-D1a, Pinb-D1b genotype resulted in a higher average flour yield than either the Pina-D1b, Pinb-D1a or the Pina-D1a, Pinb-D1a but the ranges of flour yields for the three genotypes showed considerable overlap. For both hard wheat genotypes (Pina-D1a, Pinb-D1b or Pina-D1b, Pinb-D1a), a higher proportion of type A to type C starch granules was associated with higher flour yield and this relationship accounted for between 31% and 33% of the variation in flour yield. This result is consistent with previously reported findings for soft wheat. For the Pina-D1a, Pinb-D1b genotype, increased flour yield was also associated with a decrease in starch granule-bound puroindoline protein, which accounted for 31–35% of the variation in flour yield across the two environments. The combined effect of starch granule type and associated puroindoline content accounted for 68% of the variation in flour yield within the Pina-D1a, Pinb-D1b genotype.     

A novel Puroindoline b-2 variant present in Chinese winter wheat cultivar Yunong 202

The recently identified Puroindoline b-2 (Pinb-2) variants on the homoeologous group 7 chromosomes in bread wheat are Puroindoline-like genes that account for minor grain texture modulation and display activity against bacteria and phytopathogenic fungi. In this study, the coding sequence of the Pinb-2 gene in the Chinese winter wheat cultivar Yunong 202 (Triticum aestivum L.) was amplified with the universal primer, and the obtained 452-bp fragment was cloned and 36 plasmids encompassing the targeted fragment were sequenced from two strands. Results indicated that Yunong 202 possessed Pinb-2v1, Pinb-2v2, Pinb-2v3b and Pinb-2v4 alleles. A new Puroindoline-2 variant was discovered in Yunong 202 as well and was designated as Pinb-2v6. Full alignment showed that Pinb-2v6 possessed 74.0%, 95.4%, 94.7%, 92.3%, 98.7% and 98.0% identity at the DNA level with Pinb-D1a, Pinb-2v1, Pinb-2v2, Pinb-2v3a, Pinb-2v4 and Pinb-2v5 alleles, respectively. This study may provide useful information for further understanding the molecular and genetics basis of grain texture and for illustrating gene duplication events in wheat.     

Milling and Chinese raw white noodle qualities of common wheat near-isogenic lines differing in puroindoline b alleles

Understanding the effects of different alleles at the puroindoline b (Pinb) locus on processing quality will provide crucial information for quality improvement. Seven near-isogenic lines (NILs) planted at two locations in the 2008 cropping season were used to determine the effect of puroindoline b alleles on milling performance and Chinese raw white noodle (CRWN) quality. The Pina-D1b/Pinb-D1a genotype possessed significantly higher values in grain hardness, protein content and starch damage than other genotypes, whereas the Pina-D1a/Pinb-D1d genotype had the lowest grain hardness and starch damage, with higher break flour yield, and less reduction flour yield, higher flour colour L*, and lower flour colour b*, than other genotypes. Farinograph parameters, except for water absorption, were not significantly affected by variation of puroindoline b alleles. Pina-D1a/Pinb-D1e had the highest peak viscosity, whereas the lowest value was observed in a Pina-D1b/Pinb-D1a genotype. For CRWN quality, higher noodle viscoelasticity was obtained in the genotype Pina-D1a/Pinb-D1e and Pina-D1a/Pinb-D1g, whereas Pina-D1a/Pinb-D1d had a lower smoothness score. Genotypes with Pina-D1a/Pinb-D1e and Pina-D1a/Pinb-D1g produced the best total noodle score. It was concluded that genotype Pina-D1a/Pinb-D1d had better milling qualities, whereas Pina-D1a/Pinb-D1e and Pina-D1a/Pinb-D1g had slightly superior CRWN qualities in comparison with other genotypes.     

Assessment of commercial milling potential of hard wheat by measurement of the rheological properties of whole grain

The single-kernel characterisation system (SKCS) 4100 instrument has previously been shown to provide in situ measurements of the rheological properties of the bran and endosperm layers of wheat, otherwise only possible following their isolation by dissection or machining. The current study has confirmed that endosperm maximum stress (endosperm strength (ES) as measured using the SKCS 4100 correlates highly (r=0.898$r=0.898$) with compressive strength (maximum stress, σ_max) measurements performed on specimens of endosperm tissues of known dimensions, isolated from different subsamples of the same bulk wheat samples. This provides a means of scaling the stress axis of the crush–response profile plots to the Instron scale (MPa) so that the SKCS endosperm stress/strain curves for hard wheat, soft wheat and durum can be compared with Instron results presented in the literature. In addition, a simple method for the measurement of ES and stiffness, using the SKCS 4100, has been developed. The method has been shown to rank wheat samples according to their performance when processed on a 650 kg/h pilot mill. The criterion against which the SKCS-derived rankings were compared was the Milling Quality Index, which uses both the percentage flour extraction and Branscan speck count measurements.     

Structural,rheological and gelatinization properties of wheat starch granules separated from different noodle-making process

In this study, three typical wheat cultivars (ZM366, AK58, and ZM103) with high, medium, and low gluten strength, respectively, were selected as the raw material. The starch granules separated from different stages of the noodle-making process, including kneading, resting, sheeting, cutting, and drying, were used to explore the structure, dynamic rheology, and quality of the noodles. The D50 (median diameter) of the starch granules decreased during the noodle-making process, and the reduction was enhanced by an increase in the gluten strength of the flour. Between steps 4 and 5 of the noodle-making process, the solubility of ZM103 variety increased from 4.3% to 5.0% at 80 °C, while the peak viscosity decreased from 3626 to 3386 mPa s, which resulted in a decrease in the cooking loss of noodles. Similar trend was observed in the ZM366 and AK58 varieties. The gelatinization enthalpy was reduced, suggesting that the crystalline regions of the starch granules were destroyed during the kneading process. Between steps 4 and 5 of the noodle-making process, the elastic modulus of the starch granules significantly increased, while the temperature at which maximum elastic modulus was decreased, indicating an increase in the crystalline stability of starch during the drying process. Correlation analysis indicated that the changes occurred to the gelatinization property was primarily due to the change in the particle size.     

Pasting properties of transgenic lines of a commercial bread wheat expressing combinations of HMW glutenin subunit genes

Seven transgenic lines of a commercial wheat (Triticum aestivum L.) cultivar expressing transgenic subunits 1Ax1, 1Dx5 and 1Dy10, alone or in combination have been developed. Pasting properties were determined in these transgenic lines using a Rapid Visco Analyser (RVA) in order to determine the possible impact of HMW-GS transgene expression on the starch properties. Expression of the HMW-GS transgenes increased the proportions of the corresponding 1Ax, 1Dx and 1Dy subunits affecting significantly the ratios of HMW-GS:LMW-GS and x-type:y-type HMW-GS. Starch granule size distribution varied significantly among all transgenic lines, with the Anza control and transgenic line T616 (expressing subunits 1Ax1 and 1Dy10) showing the highest and the lowest percentage of B granules, respectively. All transgenic lines increased the water-binding capacities (WBC) at 25 °C and 90 °C. Line T606 (expressing subunits 1Ax1 and 1Dx5) and line T590 (expressing subunit 1Dy10) showed the lowest and the highest values for peak viscosity, respectively. Notably, lines expressing only transgenic x-type subunits (T580, T581 and T606), with high ratios of x-type:y-type HMW-GS, had low peak viscosities, final viscosities and breakdown viscosities. Line T590 had the highest breakdown viscosity while lines T606 and T581 had the lowest.     

Uptake and use efficiency of N, P, K, Ca and Al by Al-sensitive and Al-tolerant cultivars of wheat under a wide range of soil Al concentrations

The impacts of acidic soils and Al toxicity on wheat nutrient economy have been scarcely researched under field conditions even though these soils are widely spread in wheat production areas around the world. The main objective of this study was to quantitatively evaluate the element (N, P, K, Ca and Al) economy of an Al-sensitive and an Al-tolerant wheat cultivar growing under different soil Al concentrations at field conditions. To reach this objective, two field experiments were conducted in an Andisol in Valdivia (39°47′18″S, 73°14′05″W), Chile. Treatments were a factorial arrangement of: (i) two spring wheat cultivars (Al-sensitive, Domo.INIA and Al-tolerant, Dalcahue.INIA) and (ii) five exchangeable Al levels (0-2.7 cmol₍₊₎ kg⁻¹) with three replicates. At harvest, plant biomass was sampled and divided into 5 organ categories: ears, grains, blade leaves, stems plus sheath leaves and roots. The element content (N, P, K, Ca and Al) in each organ was measured to quantify element uptake and concentration, nutrient uptake efficiency (UPE) and nutrient utilization efficiency (UTE). Element uptake (N, P, K, Ca, and Al) was negatively affected by the increased soil Al concentration in above-ground and root biomass in both cultivars (R² = 0.61-0.98, p < 0.01), although clear differences were found between cultivars. On the contrary, the impact of soil exchangeable Al on the plant element concentration was minor, showing weak associations with soil Al levels. However, the Al concentration in above-ground tissues of the Al-sensitive cultivar was an exception because it increased exponentially with the Al soil concentration (R² = 0.96-0.99, p < 0.001). Nutrient uptake efficiencies, UPEs (N, P, K and Ca), were negatively affected by soil Al concentrations and were well described by linear equations in both cultivars (R² = 0.58-0.98, p < 0.05), with notable differences between them. Both nutrient uptake (capture) and UPE were the traits that best explained above-ground biomass production (R² = 0.82-0.99, p < 0.001, n = 20). Nutrient utilization efficiency, UTEs (N, P, K and Ca) responded more conservatively to the soil Al concentration, except for the Al sensitive cultivar under very high soil Al levels.     

Effect of particle size and addition level of wheat bran on quality of dry white Chinese noodles

Wheat bran is one of the major dietary fiber sources widely used in the food industry in order to produce fiber-rich foods. The effects of particle size and addition level of wheat bran on the quality of flour and of dry white Chinese noodles (DWCN) were investigated. Results suggested that increasing wheat bran concentration and particle size decreased midline peak value (MPV). However, the MTxW and MPT increased as particle size increased. Peak viscosity, trough, final viscosity, area of viscosity, breakdown, and setback of blends decreased significantly with increasing bran levels from 5% to 20%, but there were no significant differences in the impact of particle size on pasting properties. For the 5% and 10% addition levels, there was no distinct effect in breaking strength of the noodles when bran size was 0.21 mm and 0.53 mm. Hardness, gumminess and chewiness of cooked DWCN showed a downtrend with increasing addition levels and particle size, while adhesiveness showed uptrend. The total score of DWCN showed a downtrend with increasing of addition level and particle size. For the 5% bran level, the scores of cooked DWCN were more than 83 when wheat bran particle size was 0.21 mm and 0.53 mm. By using 5–10% fine bran or using 5% medium bran in wheat flour, it is possible to satisfactorily produce fiber-rich DWCN.     

Effects of elevated atmospheric CO2 on grain quality of wheat

Wheat (Triticum aestivum L.) is one of the most important agricultural crops worldwide. Due to its high content of starch and unique gluten proteins, wheat grain is used for many food and non-food applications. Although grain quality is an important topic for food and feed as well as industrial processing, the consequences of future increases in atmospheric carbon dioxide (CO₂) concentrations on quality parameters such as nutritional and bread-making rheological properties are still unclear. Wheat productivity increases under CO₂ enrichment. Concomitantly, the chemical composition of vegetative plant parts is often changed and grain quality is altered. In particular, the decrease in grain protein concentration and changes in protein composition may have serious economic and health implications. Additionally, CO₂ enrichment affects amino acid composition and the concentrations of macro- and micro-elements. However, experimental results are often inconsistent. The present review summarises the results from numerous CO₂ enrichment experiments using different exposure techniques in order to quantify the potential impacts of projected atmospheric CO₂ levels on wheat grain yield and on aspects of grain composition relevant to processing and human nutrition.     

低筋小麦配粉及其对加工品质的影响

为改良湿面筋含量较高、面筋指数和稳定时间较低的这一类型小麦的加工品质,选择这三个指标相差较大的三个小麦品种为材料进行配粉,将湿面筋含量较高、面筋指数和稳定时间较低的小麦品种郑麦618的面粉按照0、20%、40%、60%、80%和100%比例分别与面筋指数和稳定时间较高的小麦品种新麦26或郑麦7698的面粉混合,组成不同类型的配粉,对其湿面筋含量、面筋指数、沉淀指数、面团流变学特性、淀粉RVA糊化特性以及面条和馒头的加工品质进行了比较。结果表明,当两个原粉被测指标数值差异显著时,配粉的湿面筋含量、面团流变学特征参数、峰值粘度、最低粘度和最终粘度均随着原粉数值较大一方添加比例的增加而增加。当两个原粉被测指标数值差异不显著时,配粉被测指标的数值会出现大于或小于原粉的现象,比如面筋指数、延伸性和沉淀指数;但衰减值和糊化温度不符合此规律,衰减值更接近于数值较高的原粉,糊化温度更接近于数值较低的原粉。相关性分析表明,面条总分与峰值粘度、最低粘度、衰减值呈正相关,与面团流变学特性参数呈负相关,相关系数较小;馒头总分与面筋指数、沉淀指数、形成时间、稳定时间、能量、拉伸阻力、延伸性和最大拉伸阻力呈极显著负相关,与淀粉糊化各特征值相关性不显著。上述结果证实,优质面条粉和馒头粉均不需要面筋质量过高,优质面条粉的湿面筋含量为30.3%～32.2%,面筋指数为75.2～81.4,稳定时间为4.5～7.2 min,最高粘度为2 330～2 468 cP,最低粘度为1 504～1 607 cP;优质馒头粉的湿面筋含量为30.2%～32.0%,面筋指数为70.8～81.4,稳定时间为3.5～9.1 min。面条和馒头评分结果表明,湿面筋含量较高（30%以上）,面筋指数低的这一类型的小麦可以通过搭配面筋指数较高的小麦来改良其加工 品质。     

面条品质评价指标及评价方法的研究

为了全面科学地评价小麦品种的面条加工特性,测定了29个北方小麦品种的面粉品质和鲜湿面条的制作品质,采用相关分析和多元回归分析方法,分析了面粉品质指标与鲜面条加工品质之间的关系.结果表明,面条的蒸煮损失率、拉伸强度、拉断力、延伸率与面条综合得分间的相关系数分别为-0.429、0.944、0.796和0.398,相关性很强,可以用作面条品质的辅助评价指标,即辅助综合得分来评价面条品质;面团的形成时间、稳定时间及弱化度与面条的综合得分和蒸煮损失率均呈极显著相关,面粉中的总淀粉含量与面条的综合得分呈显著相关,并且面粉白度、蛋白质含量、湿面筋含量、沉淀值、吸水率、形成时间、稳定时间、弱化度、总淀粉含量、直链淀粉含量、支链淀粉含量、支直链淀粉比等12项指标都不同程度地进入了面条的上述5个品质评价指标的回归方程,进一步说明用这5个指标来综合评价面条品质是可取的.根据面条各品质指标的相关性推出各品质指标在面条综合评价中所占的权重,再将利用回归方程算出的5个面条品质评价指标的数据进行标准化处理以消除量纲的影响后,即可计算出某个小麦品种所生产面条的综合评价分数.本研究即通过这一方法从29个供试小麦品种中优选出了6个优质面条用小麦品种,它们分别是洛展1号、泰山23、温麦4号、太空6号、淮麦16、温麦8号.     

Effect of temperature variation during grain filling on wheat gluten resistance

The objective was to investigate effects of natural variation in temperature during grain filling on wheat (Triticum aestivum L) gluten quality. Seventeen field trials with four different varieties were conducted during the years 2005–2008. Temperature records were obtained from automatic weather stations located near the field trial sites. The period from heading to yellow ripeness was divided into 20 sub-phases of equal thermal time units, and a last sub-phase comprising the seven days after yellow ripeness. Partial Least Squares Regression was used to relate the temperature records of the different sub-phases to gluten quality analysed by the Kieffer Extensibility test and the SDS sedimentation test.     

Association of Puroindoline b-B2 variants with grain traits,yield components and flag leaf size in bread wheat (Triticum aestivum L.) varieties of the Yellow and Huai Valleys of China

A total of 169 wheat (Triticum aestivum L.) varieties (landraces and cultivars) were used to asses the relationship between Puroindoline D1 alleles and Puroindoline b-B2 variants and grain hardness, other grain traits, yield components, and flag leaf size. Results indicated that the average SKCS hardness of Pinb-B2v3 varieties was significantly greater than that of Pinb-B2v2 varieties within the soft Puroindoline D1 haplotype sub-group. Conversely, no statistically significant difference was obtained for SKCS hardness between varieties with the Pinb-B2v3 vs. Pinb-B2v2 alleles within the two hard Puroindoline D1 haplotypes (Pinb-D1b and Pinb-D1p sub-groups). Therefore, the Puroindoline b-B2 gene may have a bigger impact on soft wheat varieties than hard. Across all varieties, thousand-kernel weight, grain weight per spike, grain diameter, grain number per spike, flag leaf width and area of Pinb-B2v3 varieties were significantly greater than those possessing Pinb-B2v2. These results indicated that the Pinb-B2v3 allele was associated with preferable grain yield traits compared to the Pinb-B2v2 allele in bread wheat. This study provides evocative information for better understanding the molecular and genetic basis of wheat grain yield.