Coexpression of the High Molecular Weight Glutenin Subunit 1Ax1 and Puroindoline Improves Dough Mixing Properties in Durum Wheat (Triticum turgidum L. ssp. durum)

Wheat end-use quality mainly derives from two interrelated characteristics: the compositions of gluten proteins and grain hardness. The composition of gluten proteins determines dough rheological properties and thus confers the unique viscoelastic property on dough. One group of gluten proteins, high molecular weight glutenin subunits (HMW-GS), plays an important role in dough functional properties. On the other hand, grain hardness, which influences the milling process of flour, is controlled by Puroindoline a (Pina) and Puroindoline b (Pinb) genes. However, little is known about the combined effects of HMW-GS and PINs on dough functional properties. In this study, we crossed a Pina-expressing transgenic line with a 1Ax1-expressing line of durum wheat and screened out lines coexpressing 1Ax1 and Pina or lines expressing either 1Ax1 or Pina. Dough mixing analysis of these lines demonstrated that expression of 1Ax1 improved both dough strength and over-mixing tolerance, while expression of PINA detrimentally affected the dough resistance to extension. In lines coexpressing 1Ax1 and Pina, faster hydration of flour during mixing was observed possibly due to the lower water absorption and damaged starch caused by PINA expression. In addition, expression of 1Ax1 appeared to compensate the detrimental effect of PINA on dough resistance to extension. Consequently, coexpression of 1Ax1 and PINA in durum wheat had combined effects on dough mixing behaviors with a better dough strength and resistance to extension than those from lines expressing either 1Ax1 or Pina. The results in our study suggest that simultaneous modulation of dough strength and grain hardness in durum wheat could significantly improve its breadmaking quality and may not even impair its pastamaking potential. Therefore, coexpression of 1Ax1 and PINA in durum wheat has useful implications for breeding durum wheat with dual functionality (for pasta and bread) and may improve the economic values of durum wheat.     

The identification of foam-forming soluble proteins from wheat (Triticum aestivum) dough

Proteomic methods have been used to identify foam-forming soluble proteins from dough that may play an important role in stabilising gas bubbles in dough, and hence influence the crumb structure of bread. Proteins from a soluble fraction of dough (dough liquor) or dough liquor foam have been separated by two-dimensional gel electrophoresis, and 42 identified using a combination of matrix-assisted laser desorption/ionization-time of flight and quadrupole-time of flight analyses. Major polypeptide components included beta-amylase, tritin and serpins, with members of the alpha-amylase/trypsin inhibitor family being particularly abundant. Neither prolamin seed storage proteins nor the surface-active protein puroindoline were found. Commonly used dough ingredients (NaCl, Na L-ascorbate) had only a minor effect on the 2-DE protein profiles of dough liquor, of which one of the more significant was the loss of 9 kDa nonspecific lipid transfer protein. Many proteins were lost in dough liquor foam, particularly tritin, whilst a number of alpha-amylase inhibitors were more dominant, suggesting that these are amongst the most strongly surface-active proteins in dough liquor. Such proteins may play a role determining the ability of the aqueous phase of doughs, as represented by dough liquor, to form an elastic interface lining the bubbles, and hence maintain their integrity during dough proving.     

Trapping of Aethina tumida Murray (Coleoptera: Nitidulidae) from Apis mellifera L. (Hymenoptera: Apidae) colonies with an in-hive baited trap

The effectiveness of two lures for trapping the small hive beetle, Aethina tumida, by means of in-hive traps was tested by field trials in apiaries located in Florida, Delaware, and Pennsylvania during 2003-2005. Both lures included a mixture (pollen dough) consisting of bee pollen and commercial pollen substitute formulated with or without glycerol and honey. Before it was used in the traps, the dough was conditioned either by the feeding of adult small hive beetles or by inoculation with the yeast Kodamaea ohmeri (NRRL Y-30722). Traps baited with conditioned dough captured significantly more beetles than unbaited traps, and traps positioned under the bottom board of a hive captured significantly more beetles than traps located at the top of a hive. In fact, baited in-hive bottom board traps nearly eliminated the beetles from colonies at a pollination site in Florida. However, when these honey bee colonies were moved to an apiary, trap catch increased markedly over time, indicating a resurgence of the beetle population produced by immigration of beetles from nearby hives or emerging from the soil. In tests at three Florida apiaries during 2006, yeast-inoculated dough baited bottom board traps captured significantly more beetles than unbaited traps, showing the effectiveness of yeast-inoculated dough as a lure and its potential as a tool in managing the small hive beetle.     

A cysteine in the repetitive domain of a high-molecular-weight glutenin subunit interferes with the mixing properties of wheat dough

The quality of wheat (Triticum aestivum L.) for making bread is largely due to the strength and extensibility of wheat dough, which in turn is due to the properties of polymeric glutenin. Polymeric glutenin consists of high- and low-molecular-weight glutenin protein subunits linked by disulphide bonds between cysteine residues. Glutenin subunits differ in their effects on dough mixing properties. The research presented here investigated the effect of a specific, recently discovered, glutenin subunit on dough mixing properties. This subunit, Bx7.1, is unusual in that it has a cysteine in its repetitive domain. With site-directed mutagenesis of the gene encoding Bx7.1, a guanine in the repetitive domain was replaced by an adenine, to provide a mutant gene encoding a subunit (MutBx7.1) in which the repetitive-domain cysteine was replaced by a tyrosine residue. Bx7.1, MutBx7.1 and other Bx-type glutenin subunits were heterologously expressed in Escherichia coli and purified. This made it possible to incorporate each individual subunit into wheat flour and evaluate the effect of the cysteine residue on dough properties. The Bx7.1 subunit affected dough mixing properties differently from the other subunits. These differences are due to the extra cysteine residue, which may interfere with glutenin polymerisation through cross-linkage within the Bx7.1 subunit, causing this subunit to act as a chain terminator.     

Microorganisms of the San Francisco Sour Dough Bread Process: I. Yeasts Responsible for the Leavening Action

Two hundred isolates from San Francisco sour dough French bread fermentations (40 from each of five different bakeries) were screened by fermentation tests and for their ability to grow in the presence of cycloheximide (Actidione). All of the isolates from four of the bakeries and 70% of those from the fifth were unable to utilize maltose but grew well on other sugars, even in the presence of cycloheximide. The remaining few isolates from the fifth bakery utilized maltose but not galactose and were inhibited by cycloheximide. No bakers' yeast types were found. Sixteen of the maltose-negative and five of the galactose-negative isolates were subjected to more rigorous taxonomic procedures. All of the maltose-negative isolates were identified as asporogenous strains of Saccharomyces exiguus (Torulopsis holmii) and the galactose-negative ones, as S. inusitatus. The predominance of S. exiguus, its vigor in the particular acidic environment of the sour dough, and the correlation of its numbers with the leavening function constitute strong evidence on the role of this organism in the sour dough system.     

Antimicrobial effect of fermented Ghanaian maize dough

Unhygienic conditions of a typical rural community in a developing country were simulated in the laboratory by inoculating fermented maize dough porridge with Shigella flexneri and enterotoxigenic Escherichia coli (ETEC). The antimicrobial effects of the different processes involved in the preparation of fermented maize dough porridge were assessed. The soaking process reduced the pH but no antimicrobial effect against shigella and ETEC was noted. Unfermented maize dough did not inhibit any of the test strains. When the fermentation process had become established, half of the strains tested were inhibited by the fermented maize dough when examined 8 h after inoculation. Cooking the fermented maize dough into porridge reduced the antimicrobial effect but there was still significant inhibition of pathogens. This suggests that the antimicrobial effect of fermented maize dough is not due to pH per se. Fermentation of maize dough appears to be a useful strategy for reducing contamination of weaning foods by Sh. flexneri and ETEC. The possible nature of the antimicrobial agent(s) produced during the fermentation of maize dough is discussed.     

Antimicrobial effect of fermented Ghanaian maize dough

Unhygienic conditions of a typical rural community in a developing country were simulated in the laboratory by inoculating fermented maize dough porridge with Shigella flexneri and enterotoxigenic Escherichia coli (ETEC). The antimicrobial effects of the different processes involved in the preparation of fermented maize dough porridge were assessed. The soaking process reduced the pH but no antimicrobial effect against shigella and ETEC was noted. Unfermented maize dough did not inhibit any of the test strains. When the fermentation process had become established, half of the strains tested were inhibited by the fermented maize dough when examined 8 h after inoculation. Cooking the fermented maize dough into porridge reduced the antimicrobial effect but there was still significant inhibition of pathogens. This suggests that the antimicrobial effect of fermented maize dough is not due to pH per se. Fermentation of maize dough appears to be a useful strategy for reducing contamination of weaning foods by Sh. flexneri and ETEC. The possible nature of the antimicrobial agent(s) produced during the fermentation of maize dough is discussed.     

Experimente mit Hefe (2)

The so‐called iodine test is ideal for demonstrating the role of the enzyme “amylase” in simple experiments based on a colour reaction when a yeast dough rises, when carbohydrates are digested or when dishes are washed in the dishwasher. The experiments presented can be used to clarify the question of which everyday substances are capable of degrading starch or whether a food contains starch or not. The central question of the experiments is, how yeast makes the bread dough rise despite of its “starch intolerance”.     

Effects of peroxidase and hydrogen peroxide on the dityrosine formation and the mixing characteristics of wheat-flour dough

The effects of adding hydrogen peroxide and peroxidase to wheat-flour dough on dityrosine formation and mixing characteristics were investigated. Dityrosine in wheat-flour dough was identified by HPLC with a fluorescence detector and by LC/MS/MS. Formation of dityrosine increased with the addition of hydrogen peroxide, and hydrogen peroxide plus peroxidase, to wheat-flour dough, while the addition of peroxidase had no effect on the amount of dityrosine formed. The mixing curve obtained by a doughgraph changed with the addition of hydrogen peroxide, and hydrogen peroxide plus peroxidase; the peak time was significantly delayed and the dough development time was extended. We found that dityrosine cross-links in wheat-flour dough increased with the addition of peroxidase plus hydrogen peroxide. It is thought that these cross-links can lead to polymerization of the proteins in wheat-flour dough.     

Glycerol Production by Fermenting Yeast Cells Is Essential for Optimal Bread Dough Fermentation

Glycerol is the main compatible solute in yeast Saccharomyces cerevisiae. When faced with osmotic stress, for example during semi-solid state bread dough fermentation, yeast cells produce and accumulate glycerol in order to prevent dehydration by balancing the intracellular osmolarity with that of the environment. However, increased glycerol production also results in decreased CO₂ production, which may reduce dough leavening. We investigated the effect of yeast glycerol production level on bread dough fermentation capacity of a commercial bakery strain and a laboratory strain. We find that Δgpd1 mutants that show decreased glycerol production show impaired dough fermentation. In contrast, overexpression of GPD1 in the laboratory strain results in increased fermentation rates in high-sugar dough and improved gas retention in the fermenting bread dough. Together, our results reveal the crucial role of glycerol production level by fermenting yeast cells in dough fermentation efficiency as well as gas retention in dough, thereby opening up new routes for the selection of improved commercial bakery yeasts.     

Effects of Peroxidase and Hydrogen Peroxide on the Dityrosine Formation and the Mixing Characteristics of Wheat-Flour Dough

The effects of adding hydrogen peroxide and peroxidase to wheat-flour dough on dityrosine formation and mixing characteristics were investigated. Dityrosine in wheat-flour dough was identified by HPLC with a fluorescence detector and by LC/MS/MS. Formation of dityrosine increased with the addition of hydrogen peroxide, and hydrogen peroxide plus peroxidase, to wheat-flour dough, while the addition of peroxidase had no effect on the amount of dityrosine formed. The mixing curve obtained by a doughgraph changed with the addition of hydrogen peroxide, and hydrogen peroxide plus peroxidase; the peak time was significantly delayed and the dough development time was extended. We found that dityrosine cross-links in wheat-flour dough increased with the addition of peroxidase plus hydrogen peroxide. It is thought that these cross-links can lead to polymerization of the proteins in wheat-flour dough.     

Use of selected enterococci and Rhizopus oryzae proteases to hydrolyse wheat proteins responsible for celiac disease

Aims:  This work aimed at using a pool of selected enterococci and fungal proteases to hydrolyse wheat gluten during long-time fermentation.
Methods and Results:  A liquid dough made with wheat flour (20% w/w) was fermented with three Enterococcus strains (dough A) or with the combination of enterococci and Rhizopus oryzae proteases (dough B). After 48 h of fermentation, dough A and B had a concentration of water-soluble peptides approximately threefold higher than the chemically acidified dough (CAD), used as the control. The same was found for the concentration of free amino acids, being higher in dough B with respect to dough A. SDS-PAGE analysis showed that albumin and glutenin fractions were partially hydrolysed, while gliadins almost disappeared in dough A and B, as confirmed by two-dimensional electrophoresis, RP-HPLC and R5-ELISA analyses.
Conclusions:  The combined use of enterococci and fungal proteases showed a decrease of the gluten concentration of more than 98% during long-time fermentation.
Significance and Impact of the Study:  The use of the mixture of selected enterococci and R. oryzae proteases should be considered as a potential tool to decrease gluten concentration in foods.     

Isolation of a cold-sensitive fermentation mutant of a baker's yeast strain and its use in a refrigerated dough process.

Conventional baker's yeast converts sugars in dough into CO2 and ethanol to a significant extent when the dough is stored for days at 5 degrees C. We have isolated Csf (cold-sensitive fermentation) mutants of a commercial baker's yeast by a selection method including as the critical step a nystatin treatment to mutagenized cells at 10 degrees C in the presence of antimycin A. The fermentative activity of mutant strain CSF3 was substantially zero at 5 degrees C and one-fifth that of the parent at 10 degrees C but was restored to the same level as the parental activity at 25 to 40 degrees C. In contrast with the parent, the mutant strain normally produced white bread dough and butter roll dough even after the dough was stored for a week at 5 degrees C.     

生态因子对不同冬小麦品种面粉拉伸参数的影响

选用6个有代表性的冬小麦品种（豫麦34、藁麦8901、豫麦49、豫麦70、洛阳8716、豫麦50）,连续两年在河南省5个不同纬度地点（32° N-36° N）种植,研究了生态因子、品种遗传因素与冬小麦拉伸参数之间的关系.结果表明： 品种遗传因素对拉伸参数的影响大于生态环境.豫麦34和藁麦8901的最大抗阻和拉伸面积均大于其他4个品种,且品种间差异达到显著水平.在豫南（信阳和驻马店）种植点的小麦拉伸参数均与豫北（武陟和汤阴）达到显著差异,但拉伸参数随纬度变化的规律在年际间并不一致.不同年份气象因子对拉伸参数的影响程度不同,其中2002年小麦灌浆-成熟期降雨量与小麦拉伸参数显著相关.小麦生育中后期的水分管理应充分考虑气象因素,以改善小麦面粉拉伸参数.     

优良面包酵母菌株的杂交育种

本文对实验室保存的面包酵母进行筛选,以不加糖面团发酵力最高的菌株BY-14和高糖面团发酵力最高的菌株BY-6作为两杂交亲本.二倍体菌株经过单倍体制备、分离和筛选后,利用群体杂交方法,获得了一株兼备两亲本优良性能的面包酵母菌株,其不加糖面团发酵力达到菌株BY-14水平,且高糖面团发酵力比菌株BY-6提高了25%.     

Detection of Active Yeast Cells (Saccharomyces cerevisiae) in Frozen Dough Sections

A new method based on fluorescence microscopy was developed to detect active yeast cells in cryosections of wheat dough. The sections were stained with 4′,6-diamidino-2-phenylindole (DAPI) and counterstained with Evans blue. The active yeast cells in the sections appeared brilliant yellow and were readily distinguished from the red dough matrix. The dead cells allowed penetration of the Evans blue through the cell membrane, which interfered with the DAPI staining and caused the dead cells to blend into the red environment. The number of active yeast cells in fermenting dough sections containing different proportions of living and dead yeast cells correlated well with the gas-forming capability of the yeast in the dough but not with the results of the conventional plate count method. The new method allows the study of yeast activity not only during the different stages of frozen dough processing but also during the fermentation of doughs.     

优良面包酵母菌株的杂交育种

本文对实验室保存的面包酵母进行筛选, 以不加糖面团发酵力最高的菌株BY-14和高糖面团发酵力最高的菌株BY-6作为两杂交亲本。二倍体菌株经过单倍体制备、分离和筛选后, 利用群体杂交方法, 获得了一株兼备两亲本优良性能的面包酵母菌株, 其不加糖面团发酵力达到菌株BY-14水平, 且高糖面团发酵力比菌株BY-6提高了25％。     

Application of xyloglucan to improve the gluten membrane on breadmaking

Effects of xyloglucan (XG) on the physical properties of dough and bread quality were studied. XG was fractionated to water-soluble (WS-XG) by enzymatic hydrolysis with cellulase, and the four kinds of WS-XG: WS-XG-A (average degree of polymerization; 17), WS-XG-B (32), WS-XG-C (78) and WS-XG-D (223) were obtained. XG without enzymatic hydrolysis was termed water-insoluble xyloglucan (WI-XG). Additions of WS-XG-A (3%), WS-XG-D (1–5%) and WI-XG (3%) increased the stability of the dough and improved the loaf and softness of bread samples. Especially, the WS-XG-D (1–5%) significantly improved the various factors of the final products, such as loaf volume, storage properties and good appearances with fine distribution of small size gas cells, and its addition of low level (1%) still showed improving effects, as compared with other additives. The more viscous gluten matrix could be observed in the mixed doughs with WS-XG-D, than the control sample without XG. WS-XG-D increased the water activity of the dough, and therefore the gluten matrix of dough became strong and uniform. Since the WS-XG-D had the higher degree of polymerization, it might be polymerized during mixing or fermentation, followed by the formation of new insoluble-XG after baking. Appropriate amount of the new WI-XG formed from WS-XG-D was considered to improve the storage properties with higher water holding property than WS-XG-D alone.     

Bánkúti 1201—an old Hungarian wheat variety with special storage protein composition

Bánkúti 1201, an old Hungarian wheat variety with special quality traits, was analysed to determine the relationships between its storage protein composition and superior quality-attributes for breadmaking. Based on the storage protein composition, the variety appears to have the nature of a population, containing several genotypes with different gluten protein alleles. Using molecular markers, a new mutant x-type HMW glutenin allele was identified, containing an extra cysteine residue and showing a moderate, positive-effect on gluten properties. In lines possessing subunits Bx7+By8 the overexpression of the Bx-type subunit could be detected, resulting in a higher unextractable polymeric protein (UPP) content and increased dough strength. It was found that the presence or absence of subunit Bx7 has an equilibrating effect on the dough extensibility, which is generally characteristic of the Bánkúti 1201 population. The complex good bread-making quality of the variety, which has strong but highly extensible dough, is probably due to the balance between lines which express subunit Bx7 and those which do not.