Plant Protein Sources Research Articles

Dynamic in-vitro system indicates good digestibility characteristics for novel upcycled plant protein; correlation to techno-functional properties

An increasing global population demands the broadening of the plant-based protein portfolio. The high volume of by-products produced across the food industry presents the opportunity to reduce food waste while reclaiming valuable nutrition. The current study examines a novel protein, BRP, extracted from brewers spent grains regarding its techno-functionality and digestibility, in comparison to a variety of proteins including whey, soy, rice and two pea protein sources. Compositional, foaming, emulsifying, structural and rheological properties were examined, while digestion kinetics were determined using the dynamic tiny-TIM in vitro digestion model. BRP performed similarly to whey protein in many respects, demonstrating a high solubility, high nitrogen bioavailability (>90%) and comparable N digestion kinetics, however BRP exhibited no rheological changes over heating. The digestible Indispensable amino acid score for BRP was 67% with lysine as the sole limiting amino acid, a higher value than soy, rice and one of the pea proteins investigated. Industrial relevanceThe production of a protein ingredient from a plentiful and otherwise low-value food processing by-product presents an opportunity for an increased shift towards more sustainable protein sources for the food industry. This protein displays enhanced nutritional characteristics when compared to variety of plant protein sources, and promising functional properties such as a high solubility. This study offers an examination of a novel, upcycled protein ingredient as a potential tool for food manufacturers in the shift towards a more sustainable and secure food future.

Seeking the best alternatives: A systematic review and meta‐analysis on replacing fishmeal with plant protein sources in carnivorous fish species

AbstractThe price of fishmeal (FM) has been increasing continuously due to the expansion of the gap between its stable production and rising demand. Therefore, plant protein sources are widely applied in the aquaculture industry to accomplish the protein requirement of farmed fish species. However, the massive number of results produced under various experimental conditions appended challenges for comprehensive summarization and comparison of the effects of plant protein sources on carnivorous fish species. Thus, a systemic review and meta‐analysis were conducted to compare the impacts of various plant protein sources on growth, feed utilization efficiencies, blood lipid, and liver health of representative carnivorous species. Supported by the data from 256 articles, our results indicated that Atlantic salmon, African catfish, Black seabass, and Hybrid striped bass were better at utilizing plant protein sources than Grouper and Japanese seabass. Cottonseed and lupin proteins were promising protein alternatives, while rapeseed showed significant growth suppression effects for these carnivorous fish species. Besides, deep processing methods such as fermentation and enzymolysis alleviated undesirable consequences effectively when less than half of FM was replaced by plant protein sources. Moreover, the optimal plant protein sources are discussed for each fish species. Overall, this article depicts the impact patterns of major plant protein sources on carnivorous farmed fish species and lays a solid foundation for further investigation on mechanisms for improving plant protein utilization.

Effect of Dietary Supplementation with Fish Meal and Soybean Meal on Gastrointestinal Function in Carnivorous Companion Animals – Using Mink (Neovision vision) as a Model

Abstract Soybean meal (SBM) is fed to various livestock species worldwide. It is also present in dog food as a plant protein source, combined with animal-derived ingredients. The aim of this study was to compare the effect of dietary supplementation with fishmeal (FM, an animal protein source) and high amounts of SBM (a plant protein source) on nutrient digestibility, gastrointestinal function and enzyme activity in mink, a model carnivore. The experiment was performed on 14 female American mink of a standard strain. Diet FM was supplemented with 12% FM and 8% ground wheat grain with sugar beet pulp, and diet SBM contained 20% SBM. It was found that the dietary addition of 20% SBM to mink diets negatively affected the digestibility of protein, carbohydrates and energy. Enhanced colonic fermentation processes as a source of additional energy, observed in SBM group mink, were not sufficient to compensate for the loss of nutrients and energy in the upper gastrointestinal tract (GIT). Therefore, SBM should be applied with caution in diets for carnivorous species.

Pomegranate seed as a novel source of plant protein: optimization of protein extraction and evaluation of in vitro digestibility, functional, and thermal properties

Pomegranate seed as a novel source of plant protein: optimization of protein extraction and evaluation of in vitro digestibility, functional, and thermal properties

Does protein deamidation enhance rice protein concentrate’s ability to produce and stabilize high internal phase emulsions?

Rice is one of the most consumed grains in the world. Rice protein has great nutritional value as a hypoallergenic protein and due to its high lysine content, a limiting amino acid in several other plant protein sources. However, rice protein has low solubility, hampering its use in many applications in the food industry. In this context, alkaline deamidation (0.5 h, 343 K, and pH 11) was applied to modify the protein structure of rice protein concentrate (RPC). After deamidation, two protein powders were produced: (i) one containing the whole protein fraction recovered after RPC deamidation (DT) and (ii) another containing only the soluble fraction recovered after RPC deamidation (DS). Protein dispersions were characterized by SDS-PAGE, zeta potential, solubility, surface hydrophobicity, and capacity to hold water and oil. RPC could not structure canola oil into a high internal phase emulsion (HIPE) due to its low solubility. DT and DS dispersions displayed solubility much higher than RPC and enabled the structuration of HIPEs with 75 % (w/w) canola oil and 25 % of DT or DS dispersions (2, 4, and 6 % w/w). HIPEs were characterized regarding particle size, microstructure, Turbiscan and oil loss stabilities, and rheological behavior for 60 days. Turbiscan analysis and oil loss measurements showed high stability, and the thixotropy tests showed high recovery in all HIPEs. Higher protein concentrations and DS dispersions produced HIPEs with smaller particle sizes. However, rheological measurements indicate that HIPEs produced with DT dispersions had better results, maintaining their structure over the 60 days. Furthermore, DT is cheaper to produce; therefore, DT 4 and 6 % w/w were the most promising for producing HIPEs. The HIPEs produced in this study displayed great potential as fat replacers.

Effect of extrusion on energy and nutrient digestibility of lentil-based diets containing either supplemental plant or animal protein fed to growing pigs.

Non-food grade and excess lentil grain production may be included in swine feeds to provide starch and protein and reduce feed cost. Extrusion processing may increase energy and nutrient digestibility of lentil-based diets containing either supplemental plant or animal protein sources. Therefore, the apparent ileal digestibility (AID) of crude protein (CP) and amino acids (AA), apparent total tract digestibility (ATTD) of gross energy (GE), and digestible energy (DE) value of lentil-based diets were assessed in growing pigs. Two diets were formulated to provide 2.4 Mcal net energy (NE)/kg and 4.35g standardized ileal digestible lysine/Mcal NE: (1) soybean meal (SBM) diet, containing 50% lentil, 31% wheat, and 12.8% SBM; and (2) fish meal (FM) diet, containing 40% lentil, 45% wheat, and 10% FM. Following mixing, each diet batch was divided into two parts: one part remained as mash, whereas the other part was extruded using a single-screw extruder (400rpm, 250kg/h). Eight ileal-cannulated barrows (32.3 ± 1.5kg) were fed the four diets at 2.8 times maintenance DE requirement (110 kcal per kg of body weight0.75) for four 9-d periods in a double 4 × 4 Latin square to achieve 8 observations per diet. Data were analyzed as a 2 × 2 factorial arrangement including protein source, post-mixing processing, and their interaction as fixed effects. The lentil sample contained 32.3% starch, 24.4% CP, 9.3% total dietary fiber, and 1.7mg/g of trypsin inhibitor activity on as is-basis. Interactions between dietary protein source and post-mixing processing were not observed. Feeding FM diets resulted in greater (P < 0.05) AID of dry matter (DM), GE, and most AA, and ATTD of CP, but lower apparent hindgut fermentation of DM and GE than SBM diets. Extrusion increased (P < 0.05) the ATTD of GE and DE value of diets. The AID of CP and AA was 3.2 and 4.7%-units greater (P < 0.05), respectively, for the extruded than mash diets. In conclusion, feeding FM diets resulted in greater ileal digestibility of DM, GE, and AA than SBM diets. Extrusion increased the AID of CP and most AA, and DE value of lentil-based diets containing either supplemental plant protein or animal-protein, indicating that extrusion can increase the energy and protein value of plant-based diets fed to pigs.

Effect of Substituting Wheat Flour With Protein‐Rich Sources on Quality of Instant Noodles

There is a lack of dietary fiber and some essential amino acids in instant noodles. Enriching this popular food with protein‐ and fiber‐rich sources is important to improve the nutritional quality of noodles. The current study is aimed at enriching instant noodles by substituting wheat flour with lentil flour (7%–35%: L7%, L21%, and L35%), soy‐protein isolate (1%–5%: S1%, S3% and S5%), egg‐white protein (1–5: E1%, E3%, and E5%) and Spirulina platensis (1%–5%: S.p1%, S.p3% and S.p5%). The physicochemical, microbial, textural, and sensorial properties of noodle samples were investigated. The spatial relationship between parameters was also evaluated based on principal component analysis (PCA) to select the suitable noodle formulation. The highest protein (17.06%) and lowest carbohydrate contents (76.44%) were for L35%. The lowest (1.69%) and highest fat contents (2.04%) were for S5% and S.p5%m, respectively (p &gt; 0.05). Energy values varied from 394.83 (E5%) to 396.37 kcal/100 g (S.p5%). There was no significant difference between the microbial quality of noodle samples (p &gt; 0.05). The hardness of noodles with 1%–5% soy protein, 21% or more lentil flour, and 3% or more egg‐white/Spirulina was higher than the control/unenriched group (p &lt; 0.05). The color difference of E1 and E3% with the control sample was not obvious (ΔE∗ &lt; 3). Although all the ingredients improved the nutritional value of the noodles, the overall acceptance of samples with 3% or more of Spirulina was lower than the acceptable limit (a score of 3). According to PCA, when the nutritional value and sensory acceptance are important, the L35% may be a better choice. E1%, E3%, S1%, S5%, and L7% noodles received almost the same sensory score as the control sample, while they had more nutritional values. A combination of animal, plant, and microalgae protein sources may provide a noodle with high nutritional value, containing a wide range of essential amino acids and bioactive compounds. More research is needed to optimize such a formulation.

Hemp (Cannabis sativa L.) protein: Impact of extraction method and cultivar on structure, function, and nutritional quality

Hemp (Cannabis sativa L.) is increasingly gaining traction as a novel and sustainable source of plant protein. Accordingly, the aim of this study was to investigate the effectiveness of two protein extraction methods, alkaline extraction coupled with isoelectric precipitation (AE-IEP) and salt extraction coupled with ultrafiltration (SE-UF) in producing hemp protein isolates (pH-HPI and salt-HPI) with high purity and yield. Structural characterization as impacted by extraction method and cultivar was performed and related to functional performance and nutritional quality. Both extraction methods, with carefully selected parameters, resulted in HPI with high purity (86.6–88.1% protein) and protein extraction yields (81.6–87.3%). All HPI samples had poor solubility (∼9–20%) at neutral pH compared to commercial soy protein and pea protein isolates (cSPI, cPPI). A relatively high surface hydrophobicity and low surface charge contributed to such poor solubility of HPI. However, HPI demonstrated similar solubility at acidic pH (50–67%) and comparable gel strength (up to 24 N) to cSPI. Comparing experimental amino acid composition to the theoretical amino acid distribution in hemp protein provided insights to the functional performance of the protein isolates. While pH-HPI demonstrated better functionality than salt-HPI, minimal structural, functional, and nutritional differences were noted among the pH-HPI samples extracted from four different cultivars. Overall, results from this work could be used to guide future attempts to further develop successful protein extraction processes, and to provide valuable insights to propel breeding efforts that target enhanced hemp protein characteristics for food applications.

Creating saponin-free yellow pea seeds by CRISPR/Cas9-enabled mutagenesis on β-amyrin synthase.

Dry pea (Pisum sativum) seeds are valuable sources of plant protein, dietary fiber, and starch, but their uses in food products are restricted to some extent due to several off-flavor compounds. Saponins are glycosylated triterpenoids and are a major source of bitter, astringent, and metallic off-flavors in pea products. β-amyrin synthase (BAS) is the entry point enzyme for saponin biosynthesis in pea and therefore is an ideal target for knock-out using CRISPR/Cas9 genome editing to produce saponin deficient pea varieties. Here, in an elite yellow pea cultivar (CDC Inca), LC/MS analysis identified embryo tissue, not seed coat, as the main location of saponin storage in pea seeds. Differential expression analysis determined that PsBAS1 was preferentially expressed in embryo tissue relative to seed coat and was selected for CRISPR/Cas9 genome editing. The efficiency of CRISPR/Cas9 genome editing of PsBAS1 was systematically optimized in pea hairy roots. From these optimization procedures, the AtU6-26 promoter was found to be superior to the CaMV35S promoter for gRNA expression, and the use of 37°C was determined to increase the efficiency of CRISPR/Cas9 genome editing. These promoter and culture conditions were then applied to stable transformations. As a result, a bi-allelic mutation (deletion and inversion mutations) was generated in the PsBAS1 coding sequence in a T1 plant, and the segregated psbas1 plants from the T2 population showed a 99.8% reduction of saponins in their seeds. Interestingly, a small but statistically significant increase (~12%) in protein content with a slight decrease (~5%) in starch content was observed in the psbas1 mutants under phytotron growth conditions. This work demonstrated that flavor-improved traits can be readily introduced in any pea cultivar of interest using CRISPR/Cas9. Further field trials and sensory tests for improved flavor are necessary to assess the practical implications of the saponin-free pea seeds in food applications.

Bitki Bazlı Gıdalar ve Güncel Gelişmeler

In recent years, plant-based foods have been widely preferred due to their benefits to human health and economy, as well as their reduction of greenhouse gas emissions and their benefits to the environment. In order to meet the increasing need for plant protein, research has increased and different plant protein sources such as seaweed, spirulina, sugar beet leaves, alfalfa and hemp seeds have begun to be used in developed products. There are many studies on the benefits of an herbal diet, and many herbal products have been developed in recent years. However, most of the developed products have deficiencies in terms of appearance, texture, taste and nutritional value, and new methods need to be investigated to improve this situation. In addition, it would be wrong to say that all of the developed vegetable protein products are superior to animal sources in terms of nutritional value. In this review, plant protein sources were examined and studies on their health effects and bioavailability and the latest technological developments were evaluated.

Ultrasound-assisted macroporous resin treatment improves the color and functional properties of sunflower meal protein

Sunflower meal protein (SMP) has been considered as a high-quality source of plant protein. However, because the chlorogenic acid (CA) contained in sunflower seed meal was prone to oxidation reactions under traditional alkali extraction conditions, the extracted protein has a dark color and some poor functional properties. To this end, this study used ultrasound-assisted macroporous resin treatment to extract SMP. The improvement effects and potential mechanisms of ultrasonic-assisted macroporous resin treatment with different powers (100, 300, and 500 W) on the color and functional properties of SMP were studied. The results showed that compared with untreated sunflower meal protein (USMP), the lightness value (L*), solubility, emulsification, and gel elasticity were significantly enhanced when treated with 100 W and 300 W ultrasonic-assisted macroporous resin. However, when the ultrasonic power was increased to 500 W, the L* value, solubility, emulsification, and gel elasticity decreased instead, indicating that lower power (100 W and 300 W) ultrasonic-assisted macroporous resin treatment significantly improved the color and functional properties of SMP. Further research found that ultrasound-assisted macroporous resin treatment changed the secondary and tertiary structures of SMP, transformed β-sheet into α-helix and β-turn through rearrangement, and significantly improved surface hydrophobicity. It shows that ultrasonic-assisted macroporous resin treatment expands the SMP structure and exposes hydrophobic groups, thereby improving the color and functional properties of SMP. This study provides a potential strategy for extracting SMP with light color and good functional properties. It also provides a theoretical basis for the wide application of SMP in food processing.

Techno‐functional and rheological characterisation of protein isolates from two Australian lupin species as affected by processing conditions

SummaryLupin, a sustainable non‐starchy legume, holds promising potential as a novel plant protein source, yet its protein functionality has been underexplored, particularly in relation to drying and its interaction with starch and fibres. Here, protein from two Australian Lupin species (Lupinus angustifolius ‘Jurien’ and Lupinus albus ‘Murringo’) were extracted at pH 8.0, precipitated at pH 5.0, and subsequently dried via spray or freeze‐drying, with or without pasteurisation. Solubility at pH 8.0 was highest in the direct freeze‐dried albus and angustifolius isolates, reaching 85% and 88%, respectively, yet processing exerted a discernible influence, leading to reduced solubilities in spray‐dried (albus‐72% angustifolius‐55%) and pasteurised samples (albus‐67%, angustifolius‐44%). However, this effect was not consistently reflected in foaming and emulsification abilities, or water‐ and oil‐holding capacities. The albus species exhibited superior gelation characteristics compared to angustifolius species. Furthermore, interaction between spray‐dried albus isolates, potato starch and two types of fibres showed protein–starch–fibre interactions were dependent on the type of fibres present. In conclusion, varietal disparities, largely attributed to differences in legumin‐to‐vicilin ratios, had a significant impact on protein functionality, while the processing parameters employed demonstrated limited effects, primarily in terms of solubility and colour.

Physico-chemical and techno-functional characterization of quinoa bran protein concentrate

Quinoa is considered to be a superfood with enormous nutritional quality. Quinoa bran is an underutilized agro-processing by-product despite being a good source of high-quality proteins and nutritional properties. It contains 14% protein, which are poorly extractable as they are entrapped within the complex cell wall polysaccharide matrix. The current study attempts to improve the yield and recovery of quinoa bran proteins by enzymatic pre-treatment (cellulase and xylanase) and aqueous alkaline extraction. The physicochemical, techno-functional properties and bioactivity of the quinoa bran protein concentrate (QBPC) were studied to assess its potential as a good quality plant protein source. The yield of QBPC was enriched from 3.13 to 7.72% by enzymatic pre-treatment with a protein purity of 67.7%. The QBPC has 45.6% essential amino acids and showed 89.6% protein solubility, better foaming capacity (35 ± 5%), foam stability (76.4 ± 10.4%), emulsion ability (7.6 ± 2.8%) and stability (69 min). The nutritional parameters are as per FAO/WHO requirements. SDS-PAGE revealed the presence of 11S globulin chenopodin and 2S albumins. QBPC also showed 26.5% DPPH radical scavenging activity. These findings suggest that enzymatic pre-treatment improves protein extractability from quinoa bran, a low-cost, potential source of good-quality plant protein for supplementary food products.

Local Sources of Protein in Low- and Middle-Income Countries: How to Improve the Protein Quality?

Protein inadequacy is a major contributor to nutritional deficiencies and adverse health outcomes of populations in low- and middle-income countries (LMICs). People in LMICs often consume a diet predominantly based on staple crops, such as cereals or starches, and derive most of their daily protein intakes from these sources. However, plant-based sources of protein often contain low levels of indispensable amino acids (IAAs). Inadequate intake of IAA in comparison with daily requirements is a limiting factor that results in protein deficiency, consequently in the long-term stunting and wasting. In addition, plant-based sources contain factors such as antinutrients that can diminish protein digestion and absorption. This review describes factors that affect protein quality, reviews dietary patterns of populations in LMICs and discusses traditional and novel small- and large-scale techniques that can improve the quality of plant protein sources for enhanced protein bioavailability and digestibility as an approach to tackle malnutrition in LMICs. The more accessible small-scale food-processing techniques that can be implemented at home in LMICs include soaking, cooking, and germination, whereas many large-scale techniques must be implemented on an industrial level such as autoclaving and extrusion. Limitations and considerations to implement those techniques locally in LMICs are discussed. For instance, at-home processing techniques can cause loss of nutrients and contamination, whereas limitations with larger scale techniques include high energy requirements, costs, and safety considerations. This review suggests that combining these small- and large-scale approaches could improve the quality of local sources of proteins, and thereby address adverse health outcomes, particularly in vulnerable population groups such as children, adolescents, elderly, and pregnant and lactating women.

Nutrient Digestibility and Retention of Potential Feed Ingredients for Rainbow Trout (Oncorhynchus mykiss W.) Aquaculture in Iran

To overcome the aquafeed challenges for aquaculture in Iran, the world’s largest rainbow trout producer, the nutrient digestibility and retention of eight rendered poultry by-products, and two plant protein sources were investigated. The test ingredients were added to a casein-based semipurified reference diet as control diet and fed to juvenile rainbow trout in three runs. During the experimental runs, test ingredients were added to the control diet in a ratio of 30 : 70. The diets were then fed to the animals in four replicates. TiO2 was used as marker and feces were collected by settling method. The apparent protein digestibility coefficient for poultry by-product meals (PBM), feather meals (FeM), poultry protein concentrate (PPCon), blood meal (BM), canola meal (CM), and Iranian soybean meal (IRSBM) were 73%–93%, 73%–96%, 100%, 87%, 94%, and 97%, respectively. The nitrogen productive value for PBM ranged 27%–46%, both PPCon and IRSBM 37%, CM 24%, BM 23%, and FeM from −6% to 18%. Citric acid supplementation of the alkaline thermochemically hydrolyzed FeM improved the digestibility of crude lipid and organic matter from 6% and 88% to 55% and 92%, respectively. The assessment of digestibility as well as nutrient retention analysis for tested feed components indicated that refined PBM and PPCon, both CM and IRSBM could be used in rainbow trout diets as value-added and eco-friendly protein sources. The findings of this study can assist fish nutritionists and key players in the aquafeed industry in adopting a sustainable approach to aquaculture by selecting locally available raw materials that demonstrate high nutrient retention in rainbow trout.

Partial and total replacement of soybean meal with a corn‐fermented protein product in Rainbow Trout feeds

AbstractObjectiveCorn‐fermented protein products (CFP) from the bioethanol industry have strong potential as alternatives to traditional plant protein sources in finfish diets. This study examined the culture performance, apparent digestibility, intestinal histology, and expression of gut inflammation markers in juvenile Rainbow Trout Oncorhynchus mykiss fed experimental diets with graded levels of soybean meal and CFP.MethodsFour experimental diets were formulated to contain 40% protein and 20% lipids, and the diets incrementally replaced soybean meal with CFP (0% [Control], 25%, 50%, or 100% replacement). Juvenile Rainbow Trout (48.9 ± 1.3 g) were randomly distributed to 12 100‐L tanks within a recirculating aquaculture system (30 fish/tank). Fish were fed one of the four experimental diets on a restricted feeding regime (1–3% biomass/day), and tanks were weighed every 14 days for 70 days.ResultThe mean weight, specific growth rate, feed conversion ratio, survival, and proximate composition of fish were not significantly different (α = 0.05) between the diet groups after 70 days of feeding (139.6 ± 7.5 g final weight). Apparent protein digestibility was significantly higher in the 50% CFP diet group than the Control group (80.3 ± 1.2% and 77.6 ± 1.2%, respectively). Histological analysis of distal intestines showed significantly larger villi lengths and villi length‐to‐width ratios in fish fed the 100% CFP diet, relative to fish fed the Control and 25% CFP diets. The expression of gut inflammation markers tumor necrosis factor alpha (TNF‐α), interleukin (IL)10, and matrix metalloproteinase‐9 (MMP9) trended lower in the 50% and 100% CFP diet groups compared to the Control group. The expression of the nutrient absorption markers PepT1 and FABP2 trended higher in the 50% and 100% CFP diet groups relative to the Control group.ConclusionThe results of this study suggested that the replacement of soybean meal with CFP in Rainbow Trout grow‐out diets did not impair growth performance and improved overall protein digestibility and gut health.

Pulse Protein Isolates as Competitive Food Ingredients: Origin, Composition, Functionalities, and the State-of-the-Art Manufacturing.

The ever-increasing world population and environmental stress are leading to surging demand for nutrient-rich food products with cleaner labeling and improved sustainability. Plant proteins, accordingly, are gaining enormous popularity compared with counterpart animal proteins in the food industry. While conventional plant protein sources, such as wheat and soy, cause concerns about their allergenicity, peas, beans, chickpeas, lentils, and other pulses are becoming important staples owing to their agronomic and nutritional benefits. However, the utilization of pulse proteins is still limited due to unclear pulse protein characteristics and the challenges of characterizing them from extensively diverse varieties within pulse crops. To address these challenges, the origins and compositions of pulse crops were first introduced, while an overarching description of pulse protein physiochemical properties, e.g., interfacial properties, aggregation behavior, solubility, etc., are presented. For further enhanced functionalities, appropriate modifications (including chemical, physical, and enzymatic treatment) are necessary. Among them, non-covalent complexation and enzymatic strategies are especially preferable during the value-added processing of clean-label pulse proteins for specific focus. This comprehensive review aims to provide an in-depth understanding of the interrelationships between the composition, structure, functional characteristics, and advanced modification strategies of pulse proteins, which is a pillar of high-performance pulse protein in future food manufacturing.

Ultrasonic pretreatment and epigallocatechin gallate incorporation enhance the formation, apparent viscosity, and antioxidant activity of pea protein amyloid-like fibrils

Research on the application of plant protein-based carrier in the field of food is increasing in recent years. Pea protein, a critical plant protein source in food processing, has the advantages of high nutritional value, low price and low allergy. In this study, the effects of pre-ultrasonic treatment on the fibrillation behavior of pea protein, the microstructure, rheological property and antioxidant activity of pea protein amyloid-like fibrils as well as the interaction between epigallocatechin gallate and pea protein amyloid-like fibrils were examined. Thioflavin T fluorescence illuminated pre-ultrasonic treatment could dramatically facilitate the formation of β-sheet structure. Interaction between epigallocatechin gallate and pea protein fibrils was mainly through hydrophobic interaction, evidenced by intrinsic fluorescence spectroscopy, X-ray diffraction and surface hydrophobicity analysis. Antioxidant properties and apparent viscosity of pea protein fibrils were remarkably enhanced with both ultrasound and epigallocatechin gallate addition. The pre-ultrasound treated amyloid-like fibrils were more slender than those without treatment in terms of morphology. It was found that pre-ultrasound treated pea protein fibrils-epigallocatechin gallate composites exhibited the highest stability, viscosity and antioxidant activities, which showed great promising as excellent carriers of bioactive substances. The results obtained in this study could enable the utilization of pea protein fibrils-based hydrogel for stabilizing, encapsulating, and delivering bioactive compounds in food processing.

The Beneficial Effects of Inoculation with Selected Nodule-Associated PGPR on White Lupin Are Comparable to Those of Inoculation with Symbiotic Rhizobia.

Nodule endophytes and associated bacteria are non-symbiotic bacteria that colonize legume nodules. They accompany nodulating rhizobia and can form beneficial associations, as some of them are plant growth-promoting rhizobacteria (PGPR) that are able to promote germination and plant growth and increase tolerance to biotic and abiotic stress. White lupin (Lupinus albus) is a legume crop that is gaining relevance as a suitable alternative to soybean as a plant protein source. Eleven nodule-associated bacteria were isolated from white lupin nodules grown in a Tunisian soil. They belonged to the genera Rhizobium, Ensifer, Pseudomonas and Bacillus. Their plant growth-promoting (PGP) and enzymatic activities were tested in vitro. Strains Pseudomonas sp., L1 and L12, displayed most PGP activities tested, and were selected for in planta assays. Inoculation with strains L1 or L12 increased seed germination and had the same positive effects on all plant growth parameters as did inoculation with symbiotic Bradyrhizobium canariense, with no significant differences among treatments. Inoculation with efficient nitrogen-fixing rhizobia must compete with rhizobia present in the soil that sometimes nodulate efficiently but fix nitrogen poorly, leading to a low response to inoculation. In such cases, inoculation with highly effective PGPR might represent a feasible alternative to boost crop productivity.

Mung bean protein as an emerging source of plant protein: a review on production methods, functional properties, modifications and its potential applications.

Plant protein is rapidly becoming more of a prime interest to consumers for its nutritional and functional properties, as well as the potential to replace animal protein. In the frame of alternative protein new sources, mung bean is becoming another legume crop that could provide high quality plant protein after soybean and pea. In particular, the 8S globulins in mung bean protein have high structural similarity and homology with soybean β-conglycinin (7S globulin), with 68% sequence identity. Currently, mung bean protein has gained popularity in food industry because of its high nutritional value and peculiar functional properties. In that regard, various modification technologies have been applied to further broaden its application. Here, we provide a review of the composition, nutritional value, production methods, functional properties and modification technologies of mung bean protein. Furthermore, its potential applications in the new plant-based products, meat products, noodles, edible packaging films and bioactive compound carriers are highlighted to facilitate its utilization as an alternative plant protein, thus meeting consumer demands for high quality plant protein resources. © 2023 Society of Chemical Industry.