Search Results (248)

The utilisation of edible insects for human nutrition is a long-standing practice in many parts of the globe, and is being gradually introduced into countries without an entomophagic tradition as well. These unconventional sources of protein of animal origin have arisen as a sustainable alternative to other animal protein sources, such as meat. This review intends to present the compilation of data in the scientific literature on the chemical composition and nutritional value of the bee brood of A. mellifera species and subspecies as edible foods. For this, a comprehensive search of the scientific literature was carried out using the databases ScienceDirect, Scopus, Pub-Med, BOn, and SciELO. Appropriate keywords were used for the search to reach the research works that addressed the topics of the review. The results showed that bee brood has considerable quantities of protein, fat and carbohydrates. The most abundant amino acids are leucine and lysine (these two being essential amino acids) and aspartic acid, glutamic acid, and proline (these three being non-essential amino acids). As for the fatty acids, bee broods contain approximately equal fractions of saturated and monounsaturated fatty acids, while the polyunsaturated fatty acids are negligible. The dietary minerals present in higher quantities are potassium, phosphorus, and magnesium, and the most abundant vitamins are vitamin C and niacin; choline is also present, although it is not a true vitamin. Although bee brood from A. mellifera has potential for human consumption as a nutrient-rich food, there are still many aspects that need to be further studied in the future, such as safety and hazards linked to possible regular consumption. Full article

Micronutrient deficiencies adversely affect human health and pose a significant global threat. Enhancing the accumulation of micronutrients in the edible parts of crops through genetic breeding is a promising strategy to mitigate micronutrient deficiencies in humans. FW2.2-like (FWL) genes play crucial roles in regulating heavy metal homeostasis in plants. We previously obtained two allelic mutants for each of the rice OsFWL1 (osfwl1a and osfwl1b) and OsFWL2 (osfwl2a and osfwl2b) genes. In this study, we showed that disruption of either OsFWL1 or OsFWL2 significantly enhanced the accumulation of metallic micronutrients in brown rice. Compared with that in the wild type, the iron (Fe) concentration in brown rice was higher in the osfwl1a (+166.7%), osfwl1b (+24.3%), and osfwl2a (+99.2%) mutants; the manganese (Mn) concentration was elevated in all four mutants (+25.1% to 35.6%); the copper (Cu) concentration increased in osfwl2a (+31.0%) and osfwl2b (+29.0%); and the zinc (Zn) concentration increased in osfwl2a (+10.2%). Additionally, disruption of OsFWL1 or OsFWL2 affected the homeostasis of metallic micronutrients in seedlings. Transcriptome analysis suggested that OsFWL1 and OsFWL2 might regulate cell wall polysaccharide metabolism and the expression of heavy metal transporter genes. Protein interaction analysis revealed that OsFWL1 interacted with OsFWL2 on the cell membrane. These findings suggest that OsFWL1 and OsFWL2 can serve as genetic biofortification tools to increase the concentrations of metallic micronutrients in rice grains. Full article

Eggs are a great source of protein in the human diet. They are consumed in tens of millions of tons globally per year. In addition, egg proteins, which are known food allergens, are included in many food products due to their excellent techno-functional properties. Hen’s eggs are the most consumed, but other edible avian eggs are occasionally used as gourmet ingredients or delicacies. With a high presence in the food market, the risk of accidental exposure to egg allergens is high. Hen egg allergy ranks among the top three food allergens in infants and young children. The complex structure and similar physicochemical properties of egg proteins limit their separation and purification, making further research challenging. Egg composition is influenced by age, disease, medicine, and environmental stress, and the target protein is often present in negligible amounts or polymorphic forms. To investigate the immunoreactivity of proteins from eggs of different bird species, it is necessary to consistently and quantitatively extract and purify proteins while avoiding harsh conditions. The conformational shape of allergens is impacted by denaturation, which can remove or expose IgE-binding epitopes and change the allergenic potential of proteins. This review presents findings from a literature survey on the isolation and purification strategies utilized for egg allergens from culinary-relevant bird eggs. Full article

As a globally important leguminous crop, soybean (Glycine max L.) serves as a vital source of edible oils and proteins for humans and livestock. Oils in leaves can help crops combat fungal infections, adapt to temperature changes via fatty acid modulation, and support resource recycling during leaf senescence. However, accumulating oils in leaves is a fundamental challenge due to the need to balance the inherently competing photosynthesis and fatty acid biosynthesis processes within chloroplasts. RETICULATA-RELATED (RER), known to regulate chloroplast function and plastid metabolism in Arabidopsis, plays an essential role in leaf development. Here, 14 non-redundant GmRER genes were identified in soybean and phylogenetically classified into four subclades. Most Arabidopsis RER genes were evolutionarily preserved as gene duplicates in soybean, except for GmRER5 and GmRER6. RNA secondary structures spanning the coding sequences (CDSs), the 5′- and 3′- untranslated regions (UTRs) of GmRERs, displayed exceptional structural plasticity in CDSs, while exhibiting limited conservation in UTRs. In contrast, protein structures retained conserved folds, underscoring evolutionary constraints on functional domains despite transcriptional plasticity. Notably, GmRER4a and GmRER4b represented an exceptional case of high similarity in both protein and RNA structures. Expression profiling across fourteen tissues and three abiotic stress conditions revealed a dynamic shift in expression levels between leaf-predominant and root-enriched GmRER paralogs after stress treatments. A comparative transcriptome analysis of six soybean landraces further revealed transcriptional polymorphism in the GmRER family, which was associated with the expression patterns of lipid biosynthesis regulators. Our comprehensive characterization of GmRERs may offer potential targets for soybean breeding optimization in overall plant oil production. Full article

Population growth and the depletion of natural resources have driven the incorporation of edible insects into the human food matrix. Despite their high nutritional value and the environmental benefits of insect farming compared to conventional protein sources, their consumption poses potential risks, including food allergies. Sensitization to insect allergens can occur through various exposure routes, with cross-reactions involving other foods and environmental allergens being well-documented. Vulnerable groups such as children and the elderly may have increased susceptibility not only because of genetic predisposition but also because of age-related physiological factors. This review explores the emerging risks of edible insect consumption, with a focus on children and the elderly. Age-related alterations in the gut microbiota, digestion, immune function, and overall physiology can facilitate the absorption of intact allergenic proteins and impair immune responses. Furthermore, the allergenic potential of insect proteins and their associated microbiota remains poorly characterized. Limited research exists on the effects of processing methods on these proteins. Consequently, incorporating edible insects into food products could present an additional allergenic risk, particularly for these vulnerable populations. Understanding these risks is essential for ensuring the safety and acceptance of edible insects as sustainable food ingredients. Full article

This study was the first report regarding the application of barley malt (BM) for diets of aquaculture species. Triplicate groups of grass carp Ctenopharyngodon idellus with an initial size of about 1.2 kg were selected and fed with either BM or commercial feed (CF) to apparent satiation for 8 weeks in outdoor ponds connected with a flow-through aquaculture system. The results showed that the final body weight (1651 g) was lower in the BM fish than in the CF fish (1791 g). The edible part was lower in the BM fish than in the CF fish as indicated by the viscerosomatic index. Except for ash levels, which were lower in the fillet of the BM fish than for that of the CF fish, moisture, protein, and lipid levels were not impacted by the application of BM. Water-holding capacity indicators (drop loss, frozen exudation rate, and cooking loss) of grass carp muscle were not relevant to dietary modifications. Hematoxylin-eosin (HE) staining showed that the diameter of the myofibers was decreased while density was increased in response to the application of BM, which contributed to the improvement in textural properties (hardness, gumminess, and chewiness) in the muscle of the BM fish as compared to the CF fish. Glutamic acid level was highest, followed by aspartic acid, lysine, leucine, alanine, and arginine in grass carp muscle. Except three amino acids (proline, phenylalanine, and histidine), the amounts of the other 15 amino acids, essential amino acids, semi-essential amino acids, nonessential amino acids, and delicious amino acids were not impacted by different treatments, suggesting that the application of BM had a minor effect on the amino acid composition of grass carp muscle. Oleic acid (C18:1n-9), linoleic acid (C18:2n-6), and palmitic acid (C16:0) were the most abundant fatty acids in grass carp muscle. The amounts of poly-unsaturated fatty acid (PUFA) in the muscle decreased in response to the application of BM as the diet of grass carp, and n-6 PUFAs (C18:2n-6 and C20:2n-6) rather than n-3 PUFAs accounted for this change, which is beneficial for human health. In conclusion, the application of BM had minor impacts on the proximate composition and amino acid composition but improved textural properties and decreased n-6 PUFAs in the fillet of grass carp. Full article

The scientific interest in edible insects as an alternative source of high-value protein for the human diet has increased drastically over the last decade. Edible insects harbour enormous potential in terms of planetary health. Their lower water and land use, lower feed conversion ratios, and overall lower global warming potential paired with a high nutritional value compared with conventional livestock are key drivers towards an environmentally sustainable diet. However, low consumer acceptance, as well as regulatory challenges, have slowed down the success of edible insects in Western countries, despite edible insects being consumed regularly all over the world. To date, four edible insect species have been approved as novel foods in the European Union—namely yellow mealworm (Tenebrio molitor), migratory locust (Locusta migratoria), house cricket (Acheta domesticus), and lesser mealworm (Alphitobius diaperinus). Depending on the species, they have a high protein content (48–67%), with a beneficial indispensable amino acid profile, high fat content (21–39%), with a high content of unsaturated fatty acids based on the dry matter, and contain reasonable amounts of minerals and vitamins. Unlike other animal-based foods, edible insects contain dietary fibre. Data on the bioavailability of nutrients in humans are scarce. Although numerous publications have investigated the nutritional profiles, environmental impacts, and future perspectives of edible insects, here, those findings are reviewed critically, as some publications were partially contradictory or related to selected species only. In this narrative review, we emphasise that edible insects could play a key role in a changing world with a steadily increasing demand for nutritionally valuable food and the depletion of natural resources. Full article

Using plants as bioreactors, molecular farming has emerged as a versatile and sustainable platform for producing recombinant vaccines, therapeutic proteins, industrial enzymes, and nutraceuticals. This innovative approach leverages the unique advantages of plants, including scalability, cost-effectiveness, and reduced risk of contamination with human pathogens. Recent advancements in gene editing, transient expression systems, and nanoparticle-based delivery technologies have significantly enhanced the efficiency and versatility of plant-based systems. Particularly in vaccine development, molecular farming has demonstrated its potential with notable successes such as Medicago’s Covifenz for COVID-19, illustrating the capacity of plant-based platforms to address global health emergencies rapidly. Furthermore, edible vaccines have opened new avenues in the delivery of vaccines, mainly in settings with low resources where the cold chain used for conventional logistics is a challenge. However, optimization of protein yield and stability, the complexity of purification processes, and regulatory hurdles are some of the challenges that still remain. This review discusses the current status of vaccine development using plant-based expression systems, operational mechanisms for plant expression platforms, major applications in the prevention of infectious diseases, and new developments, such as nanoparticle-mediated delivery and cancer vaccines. The discussion will also touch on ethical considerations, the regulatory framework, and future trends with respect to the transformative capacity of plant-derived vaccines in ensuring greater global accessibility and cost-effectiveness of the vaccination. This field holds great promise for the infectious disease area and, indeed, for applications in personalized medicine and biopharmaceuticals in the near future. Full article

In recent years, the consumption of wild mushrooms in Central Europe has significantly increased. These mushrooms are increasingly recognized as a nutritious, low-calorie, and environmentally friendly food option. They are a valuable source of protein and are rich in vitamins and minerals; however, they can also accumulate toxic elements that may pose risks to human health. This study examined the mercury concentrations in the fruiting bodies of two edible forest mushroom species: Aureoboletus projectellus and Imleria badia. This study took into account the distribution of Hg in the two morphological parts of mushroom fruiting bodies—the caps and the stipes. The total mercury content of the mushroom samples was analyzed using an AMA-254 analyzer. Both mushroom species exhibited higher mercury concentrations in their caps than in their stipes, with levels measuring 0.048 mg·kg⁻¹ dry matter (DM) for Aureoboletus projectellus and 0.055 mg·kg⁻¹ DM for Imleria badia. The mercury content in the stipes was 0.032 mg·kg⁻¹ DM for Aureoboletus projectellus and 0.025 mg·kg⁻¹ DM for Imleria badia. The results obtained indicate that these species do not pose a health risk to consumers in terms of Hg content and can be a valuable addition to the human diet. They are also an indicator of the quality of the forest environment of the central coast of Poland, which should be considered free of mercury pollution. Full article

Soybean (Glycine max) is a vital crop that is rich in high-quality protein and edible oil for human nutrition and agriculture. Saline–alkali stress, a severe environmental challenge, significantly limits soybean productivity. In this study, we found that the nodule receptor kinase GmNARK enhances soybean tolerance to alkali stress besides nodulation. GmNARK could be induced by alkali stress in soybean roots. Ectopic overexpression of the GmNARK gene in Arabidopsis could significantly improve plant tolerance to alkaline stress. Moreover, overexpression or silencing of the GmNARK gene in soybean hairy roots also enhanced composite soybean plant tolerance to alkaline stress on plates and in soils. Additionally, overexpression of the GmNARK gene upregulated expression levels of the genes that are involved in the reactive oxygen species (ROS) signaling pathways. These findings provide a critical theoretical basis for further elucidating the role of GmNARK kinase in salt–alkali resistance and lay a foundation for improving soybean productivity under salt–alkali stress. Full article

The increasing global population and the environmental consequences of meat consumption have led to the exploration of alternative sources of protein. Edible insects have gained attention as a sustainable and nutritionally rich meat alternative. We investigated the effects of two commonly consumed insects, Protaetia brevitarsis seulensis larva and Bombyx mori pupa, on beneficial gut microbiota growth, using whole 16s metagenome sequencing to assess diet-associated changes. Seven-week-old female C57BL/6J mice were administered the edible insects, along with fracto-oligosaccharide (FOS) as a positive control and sham (phosphate buffer saline (PBS)) as a negative control, to assess the relative abundance of insect-diet-associated gut microbes. In total, 567 genera and 470 species were observed, and among these, 15 bacterial genera were differentially abundant in all three groups. These results show that among the two insects, Bombyx mori pupa polysaccharides have a greater ability to regulate beneficial probiotics and next-generation probiotics. In particular, Lactococcus garvieae, which has promising effects on the gastrointestinal tracts of humans and animals, was significantly enriched in both Protaetia brevitarsis seulensis larva and Bombyx mori pupa polysaccharides, similar to fracto-oligosaccharide. The results suggest that the consumption of these insects, particularly polysaccharides, can enhance the growth of beneficial gut microbes, potentially leading to improved overall health in healthy populations. Full article

Background/Objectives: Baobab (Adansonia digitate L.) is an underutilized species and edible parts (fruits, leaves and seeds) contribute to food security and human health in tropical areas. Although the fruits have attracted greater research interest and have recently been approved for consumption in EU countries, the leaves are traditionally consumed but they have yet to be studied from an interventional perspective. The aim of this study was to propose a protocol for a dietary intervention using baobab leaves (BLs) to achieve the recommended reference values for proteins and minerals (K, Ca, Mg, Na, Fe, Mn) for different target groups of the Sudanese population. Methods: Dry matter, crude fat, protein and ash content, mineral content (Na, Mg, K, Ca, Fe, Mn), total phenolic, and flavonoid compounds were determined in BLs from six different areas. To assess the health and nutrition status in Sudan, time-series data (2013–2023) from the DataBank Health Nutrition and Population Statistics database were used. The reference values for nutrients recommended by the European Food Safety Authority were used to estimate the amount of baobab leaf intake (BLI, g/day). Results: For each nutrient, the study area with the lowest amount of BLs to be consumed is recommended. Leaves from the area of El Gari (BN3) 18.312 g/day and 30.712 g/day are recommended for K and Ca, which are particularly beneficial for children aged 1–3 years and lactating women. Leaves from Kor Tagat (KR1) are suitable for sodium intake, requiring approximately 13–23 g/day across all age groups. Leaves from Kazgil (KR2) (46–81 g/day), (35–66 g/day), (0.48–0.68 g/day), and (4–6 g/day) are optimal for fulfilling the daily requirements of magnesium, iron, manganese, and protein in this order. Conclusions: The systematic inclusion of BLs in the diet can positively support the nutritional status of various demographics. Moreover, the findings of this study demonstrated the foundation for public health and nutritional policy-makers on how they will tackle malnutrition and food insecurity worldwide by incorporating naturally available diets and nutritious alternatives. Recommendation: Further research should focus on assessing the nutritional composition factors that could affect the absorption of nutrients such as phytates and oxalates and investigating the in vitro bioavailability of the elements. Full article

The intake of mushrooms provides numerous beneficial properties for the correct functioning of the human body due to their rich content in carbohydrates, proteins, fibers, vitamins, and minerals. However, most of the reports are focused on the determination of bioactive compounds and only a few regarding the essential mineral content and the evaluation of the RDI. Thus, the aim of this study was to determine the mineral composition of different cultivated (A. bisporus and P. ostreatus) and wild edible mushrooms (A. crocodilinus, A. arvensis, A. silvicola, A. impudicus, M. mastoidea, M. rhacodes, and P. ostreatus) collected in the south of Spain and north of Morocco. First, the optimization of a microwave-assisted digestion method was carried out using a Box–Behnken design with a response surface methodology to quantify the total content of five metals: Fe, Mg, Na, K, and Ca in mushrooms. The samples were analyzed by FAAS and ICP-OES. The percentage of the RDI of each mineral covered by the intake of mushrooms was calculated. It was observed that a high percentage of RDI levels are covered and just exceeded for Fe. Thence, due to their beneficial properties and high content of essential minerals, mushrooms would be proposed as a valuable source of nutrients to manufacture some food supplements. Full article

Flammulina filiformis is one of the widely produced edible fungi worldwide. It is rich in γ-aminobutyric acid (GABA), a non-protein amino acid with important physiological functions in humans. To investigate the functions of key genes in the GABA metabolic pathway of F. filiformis, we isolated the monokaryon Fv-HL23-1 from the factory-cultivated F. filiformis strain Fv-HL23 and then sequenced and assembled the genome using the PacBio Sequel and Illumina NovaSeq sequencing platforms. The results showed that the genome comprised 140 scaffolds with a total length of 40.96 Mb, a GC content of 49.62%, an N50 of 917,125 bp, and 14,256 protein-coding genes. Phylogenetic analysis based on the whole genome revealed a close evolutionary relationship of Fv-HL23-1 with Armillaria mellea, Lentinula edodes, and Schizophyllum commune. A total of 589 carbohydrate-active enzymes were identified in the genome of Fv-HL23-1, suggesting its strong lignocellulose degradation ability, and 108 CYP450 gene family members were identified, suggesting important functions such as resistance to stress, secondary metabolite synthesis, and growth and development. The F. filiformis proteins glutamate decarboxylase 1 (Ff-GAD1) and glutamate decarboxylase 2 (Ff-GAD2), which may be responsible for GABA synthesis, were identified by protein alignment. Molecular docking analysis showed that Ff-GAD2 may have better catalytic activity than Ff-GAD1. To verify the function of Ff-gad2, its heterologous expression in the mycelia of the mononuclear Hypsizigus marmoreus was analyzed. Compared with wild type, the GABA content of mycelia was increased by 85.40–283.90%, the growth rate was increased by 9.39 ± 2.35%, and the fresh weight was increased by 18.44 ± 7.57%. Ff-GAD2 may play a catalytic role in GABA synthesis. In addition, the expression of the full-length Ff-gad2 gene was increased by 7.96 ± 1.39 times compared with the exon expression level in H. marmoreus mycelia, suggesting that the intron may contribute to the heterologous expression of Ff-GAD2. Based on whole-genome sequencing, we analyzed the enzyme system related to the important life activities of F. filiformis, focusing on the function of Ff-GAD, a key enzyme in the GABA synthesis pathway. The results lay a foundation for elucidating the GABA metabolism pathway of edible fungi and developing targeted breeding strategies for GABA-producing edible fungi. Full article

Plant small molecules, such as nitric oxide (NO) and melatonin (MN) as natural and human health-friendly compounds, play important roles in the mitigation of abiotic stresses in plants. Heavy metals such as chromium (Cr) are hazardous for the survival of ornamentals, especially edible flowers. This study evaluated the effects of NO (50 µM; sourced as sodium nitroprusside) and MN (50 µM) applied two times through foliar spraying at 1-week intervals on alleviating Cr (120 µM; K₂Cr₂O₇)-induced oxidative stress in edible flowers of Calendula officinalis cv. Orange King. Cr stress decreased plant dry mass, leaf SPAD values, net photosynthetic rates, and the maximum photochemical quantum yield (F_v/F_m), and increased the oxidative stress markers. The individual application of NO or MN significantly mitigated the adverse effects, and the combined application of NO and MN synergistically enhanced plant tolerance to Cr stress, including increased activities of antioxidant enzymes in plants and concentrations of carbohydrate, ascorbic acid, sugar, total protein, as well as ash contents of edible flowers. The co-application also significantly elevated the concentrations of total phenolics, flavonoids, free reducing power, antioxidant capacity DPPH, and total carotenoids in Cr-treated plants compared with those in Cr-stressed plants. Additionally, the essential oil contents in flowers increased in response to the signaling molecule treatment under Cr stress. Compared with individual applications, the co-application of NO and MN had more significant effects. Our results indicate that the combination of signaling molecules, such as MN and NO, can not only increase the biomass of edible calendula plants but also improve flower quality for use as a novel food. Full article