1. Introduction
Consumption of wheat-based products is associated with a reduced risk of developing chronic diseases [
1,
2]. Recent studies regarding the primary potential health benefits of wheat-based products show that an increased consumption of wheat fiber and cereal whole grains improves intestinal transit, reduces obesity risks and cardiovascular diseases, prevents type-II diabetes and decreases the chances of developing some forms of cancer [
3,
4,
5,
6]. Carbohydrate fermentation in the colon promotes the development of the intestinal flora and improves the production of beneficial compounds such as short-chain fatty acids [
7]. Additionally, wheat seeds contain polyphenols, carotenoids, ascorbic acid, vitamin E and phytosterols. These bioactive chemicals provide various biological activities, such as antioxidant, antidiabetic, antiinflammatory and antithrombotic properties [
8,
9]. Barley (
Hordeum vulgare L.) is one of the oldest crops cultivated in the world with a natural tolerance and a highly adapted capacity [
10]. Its use over time as a food source has also carried it through the malt, beer, and distillery manufacturing industries [
11]. Barley seeds contain little fat, carbohydrates (mainly starch), and enough protein to provide the body with the necessary amino acids, minerals, vitamin E, polyphenolic compounds and soluble or insoluble fiber [
12]. The endosperm is rich in B-glucans and plays an important role in the regulation of serum cholesterol and blood sugar, supporting the proper function of the cardiovascular system and controlling diabetes [
13]. The high fiber content gives the effect of satiety, having a positive impact on weight control, but also on the transit of food in the colon [
11]. In comparison with barley, wheat (
Triticum aestivum L.) is one of the most widespread and important cereal crops, being a major source of feed for livestock and industry, and for nutrition [
12].
In the last decade, great efforts have been made to find strategies that improve human public health. These have focused mainly on nutritional knowledge and information regarding dietary components [
14,
15,
16,
17,
18,
19]. In 2015, the most cultivated plants obtained by conventional plant breeding were soybeans (83% of crops), cotton (75% of crops), corn (29% of crops) and canola, a hybrid of rapeseed (24% of crops) [
20].
In Romania, the modification of plant crops by crossing and selection methods is an important process in which higher hybrid varieties can be obtained. For this study, five cultivars of wheat (Triticum aestivum L.) and five cultivars of barley (Hordeum vulgare L.) obtained by crossing and selection methods of improvement, were purchased from the National Agricultural Research and Development Institute Fundulea. The selection of these cultivars was preferred due to their high consumption and their large cultivated areas—with Romania occupying sixth place at for these at the European level. Simultaneously, quantitative changes in the content of some nutrients in cereals can be correlated with certain diets in order to correct deficiencies or adjuvants for treating certain pathologies.
Improving the nutritional quality of wheat varieties plays an important role in the bakery industry. The ability to make quality dough depends on both the gluten content (the majority protein component of the wheat grain) and also on the content of fermentable carbohydrates (small molecule carbohydrates). The nutritional value of wheat flour is also provided by the content of essential amino acids, minerals, vitamins and fibers. Increasing fiber content is important for the diets of diabetic, obese, or constipated people. Increasing the gluten content improves the baking properties [
21,
22], but restricts the consumption by people with gluten allergies or intolerance [
23].
Enhancing the nutritional qualities of barley varieties plays an important role in the beer industry because barley is the raw material for obtaining malt. In the technological process of obtaining beer, the quality of the raw materials is essential for obtaining a nutritious final product with special organoleptic characteristics [
24,
25].
Both types of cereal cultivars that are the subject of this study (wheat and barley cultivars) represent important raw materials for obtaining food products with a large market worldwide. Considering the current interest in finding ways to increase the nutritional value of food products, this work characterizes, from a qualitative viewpoint, some improved cereal cultivars that are provided from raw materials that are themselves rich in nutrients and that have special technological qualities for the food and beer industries. The novelty of the study consists in the characterization of new, improved cereal cultivars, especially in terms of the important nutrients designed for the quality of the final products derived from them—the bakery products obtained from the processing of wheat flour and the beer varieties obtained from malt. Both types of cereal cultivars represent important raw materials for food products with increased consumption among the population: bakery products and alcoholic beverages such as beer. These findings will help in filling the knowledge gap for the wheat and barley cultivars produced by crossing and selection methods.
2. Materials and Methods
2.1. Materials
Five wheat cultivars (Triticum aestivum L.) and five barley cultivars (Hordeum vulgare L.) obtained by crossing and selection methods were used in this study. The cereal cultivars were purchased from the National Agricultural Research and Development Institute Fundulea (Calarasi County, Romania). The Lugol’s reagent and bovine serum albumin (BSA lyophilized powder fraction V ≥ 98%) were purchased from Sigma Aldrich (Steinheim, Germany). The chemicals were used as received.
The characteristics of the analyzed cereals obtained from the National Agricultural Research and Development Institute [
26] are represented in
Table 1.
2.2. The Milling Process
The cereal seeds were ground using FOSS Cyclotec 1093 Mill laboratory equipment to achieve a fineness and uniform size of the particles. A Mettler Toledo XS205 DualRange analytical balance was used for the weighing of the sample.
2.3. Gluten Detection Method from Wheat
We moistened 10 g flour with 5 mL of purified water, it was kneaded to a non-sticky consistency and was then left to stand for 20 min. Then, it was washed for 30 min with purified water to remove the starch. The elimination of starch was complete when the residual water did not change the color of a drop of Lugol’s reagent. The gluten wet mass was weighed. The sample was then crushed and placed in a heat-resistant vessel in the oven at 105 °C and 760 mmHg, for two hours. After that, the dry mass of gluten was weighed.
2.4. Wheat Protein Content Using the Bradford Assay
The Bradford assay [
27] is based on an absorbance shift of the dye Coomassie Brilliant Blue (CBB) G-250, by the binding of protein molecules. The absorbance of the dye–protein complex and the efficiency depend on the amino acid composition of the protein, and it has a maximum absorption at a wavelength of 595 nm.
An amount of 0.010 g Coomassie Brilliant Blue G was dissolved in 5 mL ethanol and 10 mL phosphoric acid. Then, it was brought to a final volume of 100 mL with distilled water. Before use, it was refrigerated and filtered. Tris-glycine buffer at pH = 8.3 was obtained as follows: 0.600 g tris (hydroxymethyl) aminomethane and 2.88 g glycine is dissolved in purified water and then diluted to 100 mL with the same solvent. Before use, it was made a 1:10 dilution with distilled water as follows: 20 mL tris-glycine buffer prepared above is brought to a final volume of 200 mL with distilled water. Bovine serum albumin (BSA) stock solution (1 mg/mL) was prepared as follows: 0.025 g BSA was put into a 25 mL volumetric flask. An amount of 10 mL tris-glycine buffer diluted at pH = 8.3 (or any other solvent used to dissolve the unknown sample) was added. The solution was stirred until the substance was solubilized and it was brought to a level of 25 mL with Tris-glycine at pH = 8.3 buffer. The test solution was prepared by weighing 50 mg wheat and 50 g barley. The samples were prepared in duplicate. An amount of 3 mL tris-glycine buffer was added over the first row of samples, and 3 mL distilled water over the second row. For efficient dispersion, the samples are placed on the sonicate bath for 5 min at 4 °C. Then, the samples were centrifuged for 30 min on ice, at 4000 rpm. The samples were kept in a refrigerator. The calibration curves were obtained using the dilutions shown in
Table 2, which are made in ten Eppendorf vials of 1 mL volume.
The obtained calibration curves in tris-glycine and distilled water are given in
Figure 1a,b.
2.5. Total Nitrogen by the Kjeldahl Method [28]
The determination of total nitrogen (Nt) in a product of vegetable or animal origin can be done only after its mineralization by wetting. Wet mineralization, by boiling the product in concentrated sulfuric acid and in the presence of an oxidizing agent (perchloric acid, hydrogen peroxide or solid catalyst) releases nitrogen from the organic compounds present in the material under analysis and its fixation in the form of ammonium borate. Thus, transformed nitrogen can be determined either by a volumetric method (Kjeldahl method) or using a spectrophotometric method (the Nessler reaction). To determine Nt from ammonium borate (mineralization product), the ammonia presented in the solution is released by using sodium hydroxide and then it was distilled. In the obtained distillate, nitrogen was determined volumetrically using the titration method with a solution of hydrochloric acid of known concentration and a known factor in the presence of the Groack indicator (mixture of methyl red and methylene blue). The Nt from the sample is calculated from the amount of hydrochloric acid used in the titration.
0.5 g Glosa wheat and 0.5 g Amethyst barley cultivars were weighted. Also, 4 g disintegrant mixture consisting of 5 g of copper sulfate, 100 g potassium sulfate and 2.5 g selenium was weighted. The samples were placed in a Kjeldahl balloon. An amount of 10 mL concentrated sulfuric acid was added to the above mixture, and the beaker was connected to a digestion apparatus. The temperature was settled at 440 °C and it was kept in the flask for 30 min. At the end of the digestive stage, the contents of the Kjeldahl flask were quantitatively brought into the distillation flask by multiple washes with distilled water. By connecting the flask to the distillation plant, a 50 mL sodium hydroxide (30% wt.) was introduced into the solution. It was brought to half with distilled water. An amount of 50 mL 4% boric acid and 2–3 drops of Groack indicator solution (a mixture of methyl red and methylene blue indicator) were brought into the collection flask. The mixture was refluxed for 20–30 min or until the volume in the distillation flask reached 100 mL. Nitrogen was massively distilled in the first 5–6 min from the beginning of reflux. The contents of the distillation flask were titrated with a 0.1 N hydrochloric acid solution of known factor (0.9740), the volume of used acid was noted, and the Nt content of the sample and the total proteins using the conversion factor of 6.25 were calculated.
2.6. GC-MS/MS Analysis of Amino Acids Derived from Proteins
An amount of 100 mg wheat and 100 mg barley cultivars were weighed using the analytical balance into centrifuge tubes. The samples were made in duplicate. Half of the samples were brought to 5 mL with tris-glycine buffer and half with distilled water. The samples were centrifugated for 30 min, on ice, at 4000 rpm.
A 600 µL sample of 20 mg/mL was taken from each test tube and was then brought into derivatization vials and supplemented with 720 µL concentrated hydrochloric acid. The vials were stapled and were left in the oven for 8 h at 110 °C for protein hydrolysis process. Then, 250 µL was transferred to other vials and dried at 40–50 °C. After drying, the samples were brought with 250 µL acetonitrile, and were derivatized with 250 µL BSTFA and they were sealed.
The vials were introduced in the stirring module of the Gas Chromatograph coupled with the Quadrupol Triple Mass Spectrometer for one hour at a maximum temperature of 200 °C and a stationary one of 105 °C; afterward, the contents were transferred into injection vials and left for two hours. A standard solution of marine fish extract (Biotehnos S.A., Otopeni, Romania) in concentrations of 25 µL, 50 µL, 100 µL, 200 µL, and 400 µL was used to draw the calibration curve.
2.7. Protein Analysis by Polyacrylamide Gel Electrophoresis
The protein fingerprint of the samples is based on the separation of the polypeptide bands according to the molecular weight and after the migration into the polyacrylamide gel. The highlighting of the bands occurs by staining with reagents, which bind stoichiometrically, non-specifically, to the protein. The evaluation of their molecular weight was performed by comparison with a protein marker (20–220 kDa). The general principle of the method is described in the European Pharmacopoeia [
29].
Reagents used: (A)—Samples from Tris-glycine buffer and distilled water previously obtained; (B)—Sample solubilization solution: 2.5 mL concentration gel buffer, 2.0 mL glycerol, 4 mL 10% SDS, 0.5 mL Coomassie Brilliant Blue G-250 0.1%, 1 mL purified water. To 950 µL solution for solubilization was added 50 mL samples; (C)—Acrylamide-bisacrylamide solution: 29.2 g acrylamide and 0.8 g N′N′—bis-methylene—acrylamide dissolved in 100 mL purified water; (D)—10% SDS solution: 10 g SDS is dissolved in 90 mL purified water with stirring and brought to a final volume of 100 mL with the same solvent; (E)—Gel buffer for separation: 18.15 g 1.5 M Tris-Hcl, pH = 8.8 Trizma base® dissolved in 80 mL purified water. The pH was adjusted to 8.8 with 6 N HCl and it was brought to 100 mL with the same solvent; (F)—Concentration gel buffer: 6 g Tris-HCl (0.5 M), pH = 6.8 Trizma base® was dissolved in 60 mL purified water. The pH to 6.8 was adjusted with 6 N HCl and brought to 100 mL with the same solvent; (G)—10% ammonium persulfate (APS): 0.1 g APS was dissolved in 1 mL purified water; (H)—TEMED: Tetramethylenediamine; the migration buffer pH = 8.3: it was weighed exactly 3.03 g Trizma base®, 14.400 g Glycine, 10 mL 10% SDS and it was brought to a final volume of 1000 mL. The pH was not adjusted. (I)—Fixation solution: Trichloroacetic acid (TCA) 12%; (J)—Staining solution: This was dissolved 0.18 g Coomassie Brilliant Blue G-250® in 45 mL methanol, 45 mL purified water and 10 mL acetic acid; (K)—Discoloration solution: methanol: acetic acid: purified water in a ratio of 40:10:50 (v/v); (L)—Discoloration stop solution: 2% acetic acid in purified water; (M)—Tris-glycine buffer pH 8.3: This was a precisely weighed 0.6 g Trizma base® and 2.88 g Glycine which were dissolved in purified water. It was brought to 100 mL with the same solvent. Procedure: The test solution is prepared from 60 µL sample solution (A) and 60 µL sample solubilization solution (B). It was stirred and kept in the water bath at 95 °C for 5 min.
The presence of proteins was highlighted by the appearance of distinct blue horizontal bands, the size of the molecular masses was assessed by comparison with the marker bands. The migration distances for the constituent polypeptides from the marker (from the starting line of the separation gel to the center of the band) and the total migration distance (from the starting line of the separation gel to the marked level of the dye front) were measured using the software Chemidoc. The graph was obtained by plotting log (Mw) as a function of Rf, where: Mw is the molecular mass of each protein in the marker mixture and Rf is the individual protein band migration distance/total migration front distance. Due to the low intensity of the bands obtained by staining with Coomasie Brilliant Blue, it was opted for a double marking with Thermo Scientific Pierce Silver Stain® according to the following steps: The polyacrylamide gel was washed with water twice for 5 min and then the water was removed; A EtOH:Acetic Acid:Water = 3:1:6 was used twice for 15 min for the solution used for fixation; this was washed with 10% ethanol solution twice for 5 min, with water twice for 5 min and then the water was removed; the gel was immersed in a mixture of 25 mL water and 50 µL Silver Stain Sensitizer® for 1 min; it was then washed with water twice for 1 min and the water was then removed; 25 mL water and 250 µL Silver Stain Enhancer® were immersed in the mixture for 5 min; it was washed with water twice for 20 s and the water was removed; 25 mL Silver Stain Developer® and 250 µL Silver Stain Enhancer®, were mixed for 30 s until the strips became visible; the reaction was stopped with a solution of 5% acetic acid.
2.8. Dosing of Fructan Fibers Using the Seliwanoff Method
The Seliwanoff method is based on the differentiation between ketosis and aldoses. At high temperatures, ketoses are hydrolyzed faster than aldoses, with the breakdown of the carbohydrate cycle and with the formation of furfural. This reacts in an acidic medium with the resorcinol solution resulting in a red color that can be measured spectrophotometrically at a wavelength of 520 nm.
Fructose stock solution of 1 mg/mL, 1% resorcinol solution (1 g resorcinol, 0.25 g thiourea, 100 mL glacial acetic acid) and 5:1 hydrochloric acid solution was prepared. Nine successive dilutions were prepared from the stock solution for drawing the calibration line by taking 25 µL, 50 µL, 75 µL, 100 µL, 125 µL, 200 µL, 300 µL, 400 µL, 500 µL. The standard solutions and 500 µL sample were treated with 0.5 mL distilled water, 0.5 mL 1% resorcinol solution and 3.5 mL hydrochloric acid solution. The tubes were heated in a water bath at 80 °C for 10 min, then they were cooled. They were then read on the Perkin Elmer Life and Analytical Science LAMBDA 25 molecular absorption spectrophotometer at 520 nm in a maximum of 30 min. The calibration curve is presented in
Figure 2.
All analyses were effectuated in triplicate, and the data were registered as means values ± standard deviation (SD).
2.9. Measurements
The absorbances of the samples were obtained using a Perkin Elmer Life and Analytical Science Molecular Absorption Spectrophotometer LAMBDA 25, at a λ = 595 nm. For the total nitrogen determination by the Kjeldahl method, a Digesdahl 23130–21 digestion apparatus was used. A Thermo Scientific TSQ 8000 EVO gas chromatograph was used under the following conditions: Column, Thermo Scientific TraceGOLD TG-5SilMS, L = 30.00 m, D = 0.25 mm; The used carrier gas, He; Flow rate, 1 mL/min; Analysis time, 46.667 min; Detection with Total Ion Chromatogram (ICT), 40–600 M/z; Software, Chromeleon 7. Protein analysis by polyacrylamide gel electrophoresis was performed using the Bio-Rad PowerPac Basic Mini electrophoresis system. A Perkin Elmer Life and Analytical Science LAMBDA 25 molecular absorption spectrophotometer was used for dosing of fructan fibers at 520 nm.
4. Discussions
Gluten remains an essential protein for the food and bakery industry. Given that this quantitative analysis was performed on raw material, the impact of crossing and selection methods of improvement on the gluten content of the wheat samples was demonstrated. The literature supports the fact that the proteins (gluten) from wheat, which are associated with the elasticity and extensibility of the bakery and related products, play an important role in human nutrition [
32]. Gluten represents one of the major protein components of wheat (~80% from the total protein endosperm) in which gliadins and glutenins represent the most important parts. These two types of gluten determine its quality by their interaction and variation in composition [
33,
34,
35]. The highest increase in the gluten content (
Table 3) was observed in the case of Pitar wheat, where the amount of 19.60 ± 0.20% is 6.5% higher than in the case of commercial flour with a high gluten content. In the case of the other cultivars, the increase was not so pronounced. An increase of 3.4%in the maximum gluten content was observed in the case of the Dropia cultivars (16.46 ± 0.16%).
The literature data report that the quality of the final products is affected by the flour protein content. The protein is represented by the different proportions of low-molecular-weight glutenin subunit (LMW-GS), high-molecular-weight glutenin subunit (HMW-GS), albumins, α-, γ-, and ω-gliadins, and globulins [
36,
37,
38,
39]. According to the Department of Agriculture of the United States of America (USDA), the protein content in wheat flour is between 6.67 and 11.8%, and the protein content in barley is between 9 and 10% [
40]. The results obtained using the Bradford assay (
Table 4 and
Table 5) were below the lower limit. This is probably due to the inefficiency of protein extraction using a single solvent (tris-glycine buffer or distilled water) and the structural differences between plant and animal proteins used as standard Bovine Serum Albumin (BSA) in this dosage. Subsequently, for developing a future quantitative extraction method, the total nitrogen (N
t) was dosed using the Kjeldahl method.
The results of the GC-MS/MS analysis (
Table 8) showed quantitative and qualitative differences between different cultivars from the same species. For example, the amino acid L-proline was not identified in the Pajura and Dropia wheat cultivars, but occurs in the other three, and Tyrosine is absent only in the case of Dropia wheat. From a quantitative perspective, an increased content of L-Glutamic acid (0.68–1.94%) and DL-Phenylalanine (0.1–0.53%) can be observed in all wheat samples. In the case of other amino acids, no significant differences were observed between cultivars or important concentrations. However, the Glosa wheat cultivars proved to be clearly superior in terms of the concentration of each amino acid.
Qualitative differences in barley cultivars showed a lack of L-Isoleucine in Onix, L-Proline in Symbol and Onix and Tyrosine in Dana, Symbol and Onix. The glutamic acid content was increased compared with other amino acids present in the sample (0.14–1.04%). The concentrations of the other amino acids were compared, but there were no major differences. No quantitatively superior cereal cultivars were found. The plant-based proteins have relatively low essential amino acid contents when compared with animal-based and human proteins. This assumption was demonstrated by comparing the amino acids content of various plants and animal-based protein sources [
41,
42].
According to the literature, in the case of wheat, non-gluten proteins represent 20–25% of the total mass of proteins, most of which are monomeric [
43]. Albumins and globulins represent about 14% and 22%, respectively. Molecular weights are generally of 25 kDa, although there are significant proportions between 60 and 70 kDa. From the nutritional perspective, these proteins have a balanced intake of amino acids (high content of lysine, tryptophan, methionine). Wheat gluten can be separated into three broad groups: sulfur-rich proteins of about 50 kDa (α-, β-, γ-gliadins and B-, C-glutenins), low-sulfur proteins of the same mass (ω-gliadins and D-glutenins) and high mass proteins of about 100 kDa. Glutenins and gliadin make up 60–90% of all wheat proteins and tend to be rich in asparagine, glutamine, arginine or proline, but poor in nutritionally important amino acids such as lysine, tryptophan or methionine [
44].
Proteins separated from barley cultivars can be classified into several fractions: albumin, globulin, prolamine (hordein) and gluteline. These represent 8–15% of the seed mass, of which 3–5% are albumin and 10–20% globulin. The main components are hordein and glutelin, representing 40–45% of the total mass. According to the literature, three protein bands were highlighted: BPI-1 (albumin and globulin fraction with masses less than 20 and between 30 and 70 kDa), and BPI-2 and BPI-3 (C-, D-, B- hordein with masses between 29 and 55 kDa) [
45]. Previous studies have shown that fructans, soluble fiber, are good for human health [
46]. Fructans are non-reducing polysaccharides composed of fructose units and terminated with a glucose molecule, which have different degrees of polymerization [
46]. In wheat, fructans have a value of 0.7–2.9%, and in barley 0.9–4.5%. This concentration is high enough to regulate intestinal transit and acts as a probiotic in the intestine. However, in some cases it can cause symptoms such as abdominal pain, flatulence, diarrhea, constipation, and intestinal cramps, both in patients with irritable bowel syndrome and in non-celiac patients [
47]. Experimentally obtained concentrations ranged from 1.01 ± 0.04 to 2.27 ± 0.24% fructose for wheat cultivars and from 1.28 ± 0.22% to 1.75 ± 0.16% for barley cultivars. Comparing the results obtained after the fructose dosing process, it was observed that some cultivars of the same species have double saccharide concentrations compared to others, examples being wheat Dropia in the first case, and barley Onix cultivars in the second one.
All the above analyzed cultivars have concentrations consistent with the data found in the literature, but the differences that appear compared to them can be based on the used breeding techniques. Thus, future studies can be performed to improve or decrease the fructan content of the desired cultivars.
Bread and bakery products are food products that occupy a high percentage in the food preferences of Romanians, as evidenced by recent studies conducted both during the pandemic and before [
48,
49]. As a result, the development of cereal cultivars with good baking power is an important aspect of the bakery industry. This involves an increase in the amount of gluten and in fermentable carbohydrates. Moreover, the increase in the amount of protein and especially in the amino acid content improves the nutritional value of bakery products. Moreover, fructan enrichment can have positive effects on bakery products, due to the increase in prebiotic content, fructan behaving as a fiber with beneficial effects on the intestinal microbiome and at the same time affecting the stimulation of the intestinal transit, thus helping to detoxify the body [
50].
Several scientific studies have demonstrated the importance of using improved cultivars of wheat in obtaining bakery products with superior digestibility and special aroma [
51,
52,
53].
Nevertheless, we must also consider numerous restrictive aspects, the varieties that are enriched in gluten and fructan are not recommended for the manufacture of bakery products for people who have an intolerance to them or celiac disease.
If wheat cultivars obtained with improved characteristics for the bakery industry are a valuable raw material for obtaining quality products, then barley cultivars with higher concentrations of valuable nutrients are important raw materials for the beer industry. Numerous studies carried out on different varieties of beer have demonstrated that the organoleptic properties of beer and its nutritional value are strongly influenced by the quality of the raw materials and the characteristics of the technological process. In this sense, the use of improved cultivars of barley leads to the obtaining of quality malt that, through their content of carbohydrates, vitamins, mineral salts, fibers, and proteins with increased biological value, helps to create nutritional, aromatic drinks with optimal alcohol content [
54,
55,
56].
In addition to the process of obtaining improved cultivars, the qualities of the cultivation areas must be considered because environmental pollution or the practice of intensive agriculture can lead to the accumulation of toxic substances in the cereal grains, affecting the quality of the raw material and the safety of consumption [
57,
58,
59,
60].