Quantitative study of the formation of endoproteolytic activities during malting and their stabilities to kilning

The proteinases of germinating barley (Hordeum vulgare L.) hydrolyze storage proteins into amino acids and small peptides that can be used by the growing plant or, during brewing, by yeast. They are critical for the malting and brewing processes because several aspects of brewing are affected by the amounts of protein, peptide, and amino acids that are in the wort. This study was carried out to quantitatively measure when endoproteinases form in green malt and whether they are inactivated at the high temperatures that occur during malt kilning. Little endoproteolytic activity was present in ungerminated barley, but the activities began forming 1 day into the "germination" phase of malting, and they were nearly maximal by the third germination day. Quantitative studies with azogelatin "in solution" assays showed that the green malt endoproteolytic activities were not inactivated under commercial kilning conditions that use temperatures as high as 85 degrees C but that some actually increased during the final kilning step. Qualitative (2-D, IEF x PAGE) analyses, which allow the study of individual proteases, showed that some of the enzymes were affected by heating at 68 and 85 degrees C, during the final stages of kilning. These changes obviously did not, however, decrease the overall proteolytic activity.     

Interactions of malt and barley (Hordeum vulgare L.) endoproteinases with their endogenous inhibitors.

For producing worts that are optimal for beer production, some, but not all, of the barley proteins must be degraded during malting and mashing. This protein hydrolysis is controlled by endoproteinases, and, in turn, is partially regulated by the presence of low-molecular-weight (LMW) proteinaceous inhibitors. This paper reports studies of the interactions between the proteinases and inhibitors and an "affinity" method for concentrating the inhibitors. The malt inhibitors (I) and proteinases (E) quickly formed strong (E-I) complexes when dissolved together, and all of the I was complexed. Heating at 100 degrees C, but not 70 degrees C, dissociated the complex, even though the enzyme activities were destroyed at 70 degrees C. The released I readily recomplexed with fresh E. Barley, however, contained insufficient E to complex all of its I complement. The E-I complex was treated with salts, detergents, and reducing agents to release active E molecules, but none disrupted the complex. By removing the LMW proteins from a malt E-I extract and dissociating the complex by heating, the concentration of I molecules was greatly increased. This "affinity" method can thus be used to concentrate the I molecules for further purification.     

The effect of mashing on malt endoproteolytic activities

During malting and mashing, the proteinases of barley (Hordeum vulgare L.) and malt partially hydrolyze their storage proteins. These enzymes are critical because several aspects of the brewing process are affected by the soluble proteins, peptides and/or amino acids that they release. To develop improved malting barleys and/or malting and brewing methods, it is imperative to know whether and when the green malt endoproteinases are inactivated during malting and mashing. These enzyme activities are totally preserved during kilning and, in this study, we have determined when they were inactivated during mashing. Samples were removed from experimental mashes that mirrored those used in commercial breweries and their endoproteolytic activities were analyzed. The malt endoproteinases were stable through the 38 degrees C protein rest phase, but were quickly inactivated when the mash temperature was raised to 72 degrees C for the conversion step. All of the proteinase activities were inactivated at about the same rate. These findings indicate that the soluble protein levels of worts can be varied by adjusting the protein rest phase of mashing, but not by altering the conversion time. The rates of hydrolysis of individual malt proteins probably cannot be changed by altering the mash temperature schedule, since the main enzymes that solubilize these proteins are affected similarly by temperature.     

Purification and identification of barley (Hordeum vulgare L.) proteins that inhibit the alkaline serine proteinases of Fusarium culmorum

It has been proposed that microbial proteinase inhibitors, which are present in abundance in cereal grains, protect the seed against plant pathogens. So far, however, very little is known about the interactions of those inhibitors with the proteinases of phytopathogenic microbes. The increased alkaline proteinase activities of Fusarium head blight (FHB) diseased wheat and barley grain imply that the Fusarium fungi synthesize those enzymes during the colonization of the kernel. To study which barley proteins can inhibit Fusarium proteinases, and hence, possibly protect the seed from FHB, the proteins of a grain extract have been separated and tested for their abilities to inhibit two alkaline serine proteinases that we previously isolated from F. culmorum. The proteins were separated by size exclusion, ion exchange, and reversed-phase-HPLC chromatographies. The purified inhibitors were identified by their molecular masses and N-terminal amino acid sequences. The proteins that inhibited the subtilisin-like Fusarium proteinase were the chymotrypsin/subtilisin (CI) inhibitors 1A, 1B, and 2A and the barley alpha-amylase/subtilisin inhibitor (BASI). Only one of the purified proteins inhibited the trypsin-like proteinase, the barley Bowman-Birk inhibitor (BBBI). No novel inhibitors were detected.     

Polymorphism of Aspartic Proteinases in Resting and Germinating Barley Seeds

Both resting and germinated barley seeds (Hordeum vulgare L. ‘Morex’) contain aspartic endopeptidase activities, and the activities increase during germination. We have extracted and partially purified aspartic endopeptidases from both resting seeds and green malt (four-day germinated barley). Six aspartic proteinase activities were found in resting barley seeds while only four activities were detected in green malt. All of the aspartic proteinases had similar pH activity optima (pH 3.5–4.5) and pI values (≈4.5). The purified green malt aspartic proteinases selectively digested a group of barley seed proteins, postulated to serve as defensive proteins, that are coded by the amylase-trypsin inhibitor super gene family. The aspartic proteinases that bound to a pepstatin A affinity column at pH 4.5 cross-reacted with antiserum raised against aspartic proteinases purified from barley seed. However, those that did not bind the affinity column also did not cross-react with the antiserum, indicating that there are two distinct groups of aspartic proteases in germinating barley.     

Purification and partial characterization of a second cysteine proteinase inhibitor from ungerminated barley (Hordeum vulgare L.)

It was previously shown that ungerminated barley contains inhibitors that suppress the activities of green malt cysteine proteinases. This paper reports the purification and partial characterization of a second barley cysteine endoproteinase inhibitor, a protein called lipid transfer protein 2 (LTP2). The chromatographically purified inhibitor had a molecular mass of 7112. The amino acid composition and sequence data of the purified inhibitor indicated that it was a protein whose gene, but not the protein itself, was isolated earlier from barley aleurone tissue. The purified protein inhibited the activities of electrophoretically separated green malt cysteine proteinases but not the activities of the serine- or metalloproteinases. The purified LTP2 inhibited the same proteases as the LTP1 that was characterized previously but was present in the mature seed in much smaller amounts. Neither LTP1 nor LTP2 has been proven to transport lipids in vivo, and it seems possible that both serve to keep cysteine endoproteinases that are synthesized during barley seed development inactive until the plant needs them. The small amount of LTP2 in the seed made it impossible to determine whether it, like LTP1, is involved in beer foam formation. Because of its proteinase-inhibiting ability and its resistance to heat inactivation, some of the LTP2 may persist in beer.     

Characterization of Oat Endoproteinases that Hydrolyze Oat Avenins

During oat seed germination, the insoluble storage proteins must be solubilized and transported to the embryo for use by the developing plantlet. We showed earlier that pH 6.2 active serine and metalloproteinases were the predominant gelatin‐hydrolyzing enzymes of oats, while the oat globulins were degraded by pH 3.8 active cysteine proteases. The pH of the endosperms of germinating oats is 6.2. We have continued our characterization of the germinated oat proteinases by determining which hydrolyze avenins, the oat storage prolamins. Avenins of resting seeds were purified and hydrolyzed with proteinases that were extracted from oat seeds that were germinated for various periods. The peptides released were analyzed using SDS‐PAGE. The α‐avenins were hydrolyzed at pH 3.8 by cysteine proteinases from four‐day germinated seeds and the β‐avenins were hydrolyzed by similar enzymes from eight‐day germinated seeds. At pH 6.2 or pH 5.0, the avenins were not degraded by any of the germinated oats endoproteinases. It is probable that some kind of pH compartmentalization occurs within germinating oat seed. After four days of germination, either new proteinases form or some preexisting proteinases are activated. The cysteine proteinases are apparently responsible for the majority of the storage protein hydrolysis that occurs during oat germination.     

The influence of barley malt protein modification on beer foam stability and their relationship to the barley dimeric alpha-amylase inhibitor-I (BDAI-I) as a possible foam-promoting protein

The foam stability of beer is one of the important key factors in evaluating the quality of beer. The purpose of this study was to investigate the relationship between the level of malt modification (degradation of protein, starch, and so on) and the beer foam stability. This was achieved by examining foam-promoting proteins using two-dimensional gel electrophoresis (2DE). We found that the foam stability of beer samples brewed from the barley malts of cultivars B and C decreased as the level of malt modification increased; however, the foam stability of cultivar A did not change. To identify the property providing the increased foam stability of cultivar A, we analyzed beer proteins using 2DE. We analyzed three fractions that could contain beer foam-promoting proteins, namely, beer whole proteins, salt-precipitated proteins, and the proteins concentrated from beer foam. As a result, we found that in cultivar A, some protein spots did not change in any of these three protein fractions even when the level of malt modification increased, although the corresponding protein spots in cultivars B and C decreased. We analyzed these protein spots by peptide mass finger printing using matrix-assisted laser desorption/ionization time-of-flight mass spectrometry. As a result, all of these spots were identified as barley dimeric alpha-amylase inhibitor-I (BDAI-I). These results suggest that BDAI-I is an important contributor to beer foam stability.     

Characterization of Oat Endoproteinases that Hydrolyze Oat Globulins

During the germination of oats, the major seed storage proteins (globulins) are hydrolyzed by endoproteinases. We have used two methods to characterize these endoproteinases. A qualitative PAGE method that used oat globulins as gel‐incorporated substrates was used to determine which enzymes hydrolyzed the globulins. The proteolytic hydrolysis products were studied by hydrolyzing the globulins in vitro with the endoproteinases and analyzing the products by SDS‐PAGE. Class‐specific proteinase inhibitors were used to show that the globulin hydrolyzing enzymes were cysteine‐class proteinases. The proteinases were active at pH 3.8. Using the gel analysis method, a little activity was present at the beginning of seed germination, but the major activity only appeared on the sixth day of germination. Extracts from four‐day germinated oats contained cysteine proteinases that hydrolyzed the globulins in vitro to form a polypeptide of intermediate size (MW ≈34,500). Cysteine proteases from an eight‐day germinated sample totally hydrolyzed the globulins in <1 hr. Very little hydrolysis occurred at pH 6.2, the pH of germinated oats endosperm tissue. The fact that hydrolysis occurred quickly at pH 3.8 implies that there is probably pH compartmentalization within the endosperm, with some areas of the seed having a low pH value where the globulins can be degraded.     

Study of metallopeptidase isozymes from malted barley (Hordeum vulgare cv. Morex)

It has been reported that germinated barley contains peptidases that are sensitive to metal-chelating agents; however, none of these enzymes have been isolated, nor have their roles in germinated barley been investigated. Anion-exchange chromatography and chromatofocusing have been used to isolate a group of peptidases from barley (Hordeum vulgare cv. Morex) green malt that are sensitive to metal-chelating agents. Their activities were studied using one- and two-dimensional polyacrylamide gel electrophoresis. When analyzed on two-dimensional PAGE gels that contained gelatin as substrate, the enzymes separated into three major and approximately six minor activity spots with acidic pI values. The enzymes were optimally active against the gelatin substrate at pH 8.0 and were completely inhibited by 1,10-phenanthroline and EDTA, indicating that they belonged to the metallopeptidase class (EC 3.4.24.x). After the enzymes were inhibited with EDTA, the activities were recovered in the presence of low concentrations of metal ions. The hydrolysis of gelatin substrate was also impaired by the presence of reducing agents. The metallopeptidases readily digested, in vitro, the barley prolamine D hordein, indicating that they may be involved in degrading storage proteins during barley germination.     

Purification and Characterization of a New Class of Insect α-Amylase Inhibitors from Barley

Barley seeds contain proteins that apparently protect them against attack by microorganisms and insects. Studies of these barley defensive proteins may lead to the development of barleys with improved natural resistance to pests. We have purified two low molecular weight proteins, designated BIα1 and BIα2, from barley grain, using ion-exchange chromatography and reversed-phase and gel-permeation high-performance liquid chromatography (HPLC). Both BIα1 and BIα2 inhibited insect (yellow meal worm, Tenebrio molitor) α-amylase activities. For the T. molitor α-amylase, the IC50 values of BIα1 and BIα2 were 80 μg/mL (12.5 μM) and 34 μg/mL (6.8 μM), respectively. Neither protein inhibited either human salivary α-amylase, barley α-amylase, or trypsin activities. N-terminal amino acid sequences of the inhibitors were highly homologous with those of the plant proteins called defensins. The first 20 N-terminal amino acids of BIα2 were identical to those of γ-hordothionin, but neither BIα1 nor BIα2 protein showed any homology with the chloroform-methanol (CM) soluble protein amino acid consensus sequence. The two inhibitors therefore apparently comprise another group of low molecular weight barley proteins that inhibit the α-amylase activities of some insects that attack cereal grains.     

Comparison of Endoproteinases of Various Grains

Two‐dimensional isoelectric focusing (IEF) × PAGE gels were used to compare the endoproteolytic (gelatinase) activities of germinated barley with those of bread and durum wheat, rye, triticale, oat, rice, buckwheat, and sorghum. Barley was used as the standard of comparison because its endoproteinase complement has been studied previously in the greatest detail. The characteristics of the grain proteases were appraised from their migration patterns and by how they were affected by pH levels. All of the germinated grains contained multiple enzyme activities and their separation patterns and pH levels were at least similar to those of barley. The proteinases of the bread and durum wheats, rye, oat, and sorghum were most similar to those of barley, whereas the other grains provided more varied patterns. The rice and buckwheat proteinases developed much more slowly than those of the other grains. The activity patterns of the triticale resembled those of the parents, wheat and rye, but the triticale contained many more activities and higher overall proteolytic activities than any of the other species. These results should be applied to scientific or commercial procedures with caution because grains contain potent endogenous proteinase inhibitors that could inactivate some of these enzymes in various tissues or germination stages.     

Improved Methods for High-Throughput Extraction and Assay of Green Barley Malt Proteinase Activity Facilitating Examination of Proteinase Activity Across Large-Scale Barley Populations

We report efficient sample extraction and assay methods allowing quantitative determinations of proteinase activities from barley malt. The improved methods are used to assay >2,200 developmental lines of malting barley for two subsets of proteinase activity. The distributions of the resulting activities suggest differences in population structures between the two types of proteinases. Comparison of the activities of the green malt proteinases with standard malting quality measurements show highly significant correlations that differ between the proteinase subsets. The pH 4.5 hydrolysis of the artificial substrate Z-Phe-Arg-AMC correlates well with the traditional malting quality measurements, supporting the role of cysteine-class proteinases in mobilization of grain reserves during malting and mashing. Results from assays of gelatin hydrolysis at pH 6.0 suggest that these proteolytic activities may be involved in other aspects of seed C and N dynamics also linked to malting quality measurements. The differences between the pH 4.5 and 6.0 activities assayed here and their association with malting quality measurements suggest different physiological roles for the two proteinase activities in several aspects of seed germination. Either assay could be useful for population surveys, depending on the particular facet of seed metabolism under study.     

Qualitative Zymographic Studies of Major Proteinases from Malted Sorghum (Sorghum bicolor L.) and Effects of Cultivar

Proteolysis during cereal germination is vital both to seedling growth and the success of commercial malting and brewing. In this study, proteinases in proteolytic extracts from seeds and germinated grains of 11 Botswana sorghum cultivars were analyzed and partially characterized by one‐dimensional electrophoresis on SDS‐PAGE gels containing incorporated gelatin. Proteinase polymorphism was detected in both germinated and ungerminated sorghum grains. Fifteen distinct proteinase bands, with M_r values of 27,000–100,000 were detected in sorghum malt extract, while ungerminated sorghum displayed a maximum of four bands (M_r ≈ 78,000–100,000). Band numbers and identity varied markedly according to cultivar. More proteinase bands were detected at pH 4.6, than at pH 6.2 and 7.0, suggesting pH optima considerably below neutrality. Cysteine‐proteinases constituted a higher proportion (9 of 15) of the detected sorghum malt proteinases and were most detectable at pH 4.6. Multiple representatives were also detected for both serine‐ and metallo‐proteinases, although these were more active at pH 6.2 and 7.0. 1‐10 Phenanthroline inhibited malt metallo‐proteinase more strongly than EDTA, suggesting that these enzymes were most probably zinc‐dependent. Aspartyl‐proteinases were not detected, probably because of the substrate employed. Results indicate that the sorghum proteinase system is complex.     

Trypsin-like proteinase produced by Fusarium culmorum grown on grain proteins

The fungal disease Fusarium head blight occurs on wheat (Triticum spp.) and barley (Hordeum vulgare L.) and is one of the worldwide problems of agriculture. It can be caused by various Fusarium species. We are characterizing the proteinases of F. culmorum to investigate how they may help the fungus to attack the grain. A trypsin-like proteinase has been purified from a gluten-containing culture medium of F. culmorum. The enzyme was maximally active at about pH 9 and 45 degrees C, but was not stable under those conditions. It was stabilized by calcium ions and by the presence of other proteins. The proteinase was most stable at pH 6-7 at ambient temperatures, but was quickly inactivated at 50 degrees C. It was strongly inhibited by p-amidino phenylmethylsulfonyl fluoride (p-APMSF), and soybean trypsin and Bowman-Birk inhibitors, and it preferentially hydrolyzed the peptide bonds of the protein substrate beta-purothionin on the C-terminal side of Arg (mainly) and Lys residues. These characteristics show that it is a trypsin-like proteinase. In addition, its N-terminal amino acid sequence was 88% identical to that of the F. oxysporum trypsin-like enzyme. The proteinase hydrolyzed the D hordein and some of the C hordeins (the barley storage proteins). This enzyme, and a subtilisin-like proteinase that we recently purified from the same organism, possibly play roles in helping the fungus to colonize grains.     

Activity and Inhibition of Polyphenol Oxidase in Extracts of Bran and Other Milling Fractions from a Variety of Wheat Cultivars

Studies were conducted to compare polyphenol oxidase (PPO) specific activities in various milling fractions of a variety of wheat cultivars and determine the levels of activities in a number of cultivars from different localities and harvesting seasons. Substrate specificities were also investigated. Bran was singled out as the richest source of PPO activity, which may also influence the activity in the other milling fractions that are known to have some proportion of bran content. We showed by gel electrophoresis and spectrophotometrically that the protein responsible for PPO activity apparently exists as a single isoform in bran and that the observed enzyme activity is likely to be a tyrosinase type, not a laccase or peroxidase. The specific activity was not significantly different between the reduction shorts and break shorts from the same cultivar, indicating a similar level of bran contamination in these fractions. Very low levels of PPO activity were recorded in the flour of all cultivars studied. Bran was used, therefore, to determine the varietal differences in the PPO activities in a number of cultivars from different localities and seasons of harvest. Results showed that the most significant determinant of PPO activity was the genotype, and this may be influenced by seasonality. We also determined that, apart from substrate preferences by the PPO enzyme, some phenolic acids actually inhibit PPO. Furthermore, we found that bran of some cultivars extracted with acidified methanol inhibited PPO activity substantially, whereas other extracts had less inhibitory properties. Thus, these unknown compounds in wheat may inhibit endogenous PPO activity.     

Influence of corn size distribution on the diastatic power of malted barley and its impact on other malt quality parameters

Detailed studies were carried out on the influence of corn size distribution on the values obtained for diastatic power (DP) of commercially malted barley. Malted barley was screened using a screening box, and the DP activities of the different corns retained on the different compartments of the screening box were determined. The malt samples retained on the 2.8 mm screen had the highest DP activity, whereas the small corns (相似文献   

Impact of α‐Amylases on Quality Characteristics of Asian White Salted Noodles Made From Australian White Wheat Flour

The consumer acceptance of white salted Asian noodles depends on starch characteristics, and the purpose of this study has been to investigate the potential of exogenous α‐amylases to enhance textural characteristics of this product. Noodles were prepared from commercial flours with low α‐amylase activity, and the endogenous enzyme remained relatively stable during various processing and storage treatments. α‐Amylase preparations of bacterial origin and from barley malt were incorporated, and the products were assessed by texture analysis and electron microscopy, as well as for color characteristics. On addition of the amylase preparations, noodles were softer when texture was assessed using either a flat cylinder probe or an axial blade. Some discoloration occurred in treated noodle sheets, although this was minimal in final products that had been cooked immediately after preparation or following drying. Scanning electron microscopy confirmed that the α‐amylase of bacterial origin had greater impact upon starch than that from barley malt. The results have implications for understanding of the adverse impact of preharvest sprouting on product characteristics. The results show that softer noodles have been obtained at these levels of enzyme additions. This was true for both enzyme preparations used. Differences in hardness (as measured using the flat cylinder probe) were greater than those for firmness (as measured using the axial blade).     

Correlation of malt quality parameters and beer flavor stability: multivariate analysis

Malt is known to have an impact on beer flavor stability mainly due to the presence of antioxidants. In this study, five barley varieties were malted at industrial and micro scale, and quality parameters of the resulting malts were measured (diastatic power, friability, beta-glucan content, antiradical power, reducing power, lipoxygenase activity, and nonenal potential) and correlated with the sensory data obtained for the corresponding fresh and forced aged beers. A statistical strategy using multiple linear regressions was applied to explore relationships between the malt chemical parameters and beer sensory data, showing antiradical power as the major contribution of malt to beer flavor stability. Additionally, the measured antiradical power, which is well correlated with the polyphenolic content, was found to be very similar for malt and barley, emphasizing the key role of barley endogenous polyphenols.     

Stability of barley and malt lipid transfer protein 1 (LTP1) toward heating and reducing agents: relationships with the brewing process

Barley lipid transfer protein (LTP1) is a heat-stable and protease-resistant albumin that concentrates in beer, where it participates in the formation and stability of beer foam. Whereas the barley LTP1 does not display any foaming properties, the corresponding beer protein is surface-active. Such an improvement is related to glycation by Maillard reactions on malting, acylation on mashing, and structural unfolding on brewing. The structural stability of purified barley and glycated malt LTP1 toward heating has been analyzed. Whatever the modification, lipid adduction or glycation, barley LTP1s are highly stable proteins that resisted temperatures up to 100 degrees C. Unfolding of LTP1 occurred only when heating was conducted in the presence of a reducing agent. In the presence of sodium sulfite, the lipid-adducted barley and malt LTP1 displayed higher heat stability than the nonadducted protein. Glycation had no or weak effect on heat-induced unfolding. Finally, it was shown that unfolding occurred on wort boiling before fermentation and that the reducing conditions are provided by malt extract.