Search Results (837)

A field trial was conducted at two locations in northern Ghana over two successive years to determine the optimal insecticide application timings for mitigating non-lepidopteran pest infestations in a cowpea (Vigna unguiculata (L.) Walp.) variety, Songotra-T. This variety was genetically engineered to resist damage by the Maruca pod borer (MPB) (Maruca vitrata Fab.; Lepidoptera: Crambidae). A split-plot design, with cowpea variety as the main plot factor (Songotra-T vs. Songotra) and insecticide spraying regimes as the sub-plot, was used. Spraying treatments ranged from no spray to three applications at key growth stages (50% flowering, pod initiation, and 50% podding). Data were collected on pest infestation, pod damage, and grain yield. An economic analysis of the spraying regimes tested was performed using yield data. Significant spraying regime effects were observed for non-lepidopteran pests such as whiteflies (p = 0.034), thrips (p = 0.006) and the pod-sucking bugs complex (p < 0.05). Variety effects were mainly significant for MPB infestation and damage to pods. Songotra-T consistently produced approximately 2-fold higher yields than Songotra. Among spraying regimes, two applications at pod initiation and 50% podding resulted in the highest yields, while additional sprays offered no significant advantage. This spraying regime also resulted in a higher return on investment. These findings demonstrate that the adoption of Songotra-T mitigates excessive insecticide use in cowpea production. Full article

Yellow Mosaic Disease (YMD) caused by mungbean yellow mosaic virus (MYMV, begomovirus) is one of the main causes of low mungbean (Vigna radiata L.) productivity, primarily in South Asia. Agroinoculation screening for MYMV resistance in mungbean cultivar VGGRU 1, an interspecific derivative of mungbean × rice bean and VRM (Gg)1 across replications, revealed VGGRU1 as highly resistant to MYMV infection. Gas chromatography mass spectrometry analysis was performed on the methanolic leaf extracts of susceptible and resistant genotypes, along with necessary controls. The metabolite profiling of the susceptible and resistant genotypes, along with controls, identified 121 discriminant metabolites belonging to 24 different classes of metabolites. A maximum number of 27 metabolites were accumulated in agroinoculated VGGRU1 alone. Metabolite profiles of VGGRU1 and VRM1 were clustered hierarchically and revealed substantial variations between the genotypes. Fold change revealed the upregulation of amino acids and phenol in the resistant genotype. The resistant genotype, VGGRU1, showed significantly higher levels of key defense-related metabolites, such as amino acids and phenolics. In this study, 18 significant VIP metabolites were identified, differentiating the resistant VGGRU1 and susceptible VRM (Gg)1 genotypes. Full article

Plant-parasitic nematodes (PPNs) cause yield losses in various crops worldwide. Damage due to PPNs can be severe, causing billions of dollars of crop losses across the globe annually. Information about PPNs occurrence in Mozambique is limited. Based on the literature, twenty-five genera of PPNs have been reported to affect several economically important crops, including root-knot nematodes (RKNs, Meloidogyne spp.), Scutellonema spp., root-lesion nematodes (RLNs, Pratylenchus spp.), spiral nematodes (Helicotylenchus spp.), and the dagger nematode (Xiphinema spp.), which are commonly associated with crops such as banana (Musa spp.), cassava (Manihot esculenta), cowpea (Vigna unguiculata), maize (Zea mays), sugarcane (Saccharum officinarum), and sunflower (Helianthus annuus). Dissemination of these nematodes is not yet fully understood, but the importation of plants, roots, rhizomes, and/or seeds likely contributes to the introduction and spread of PPNs. Although the implementation of PPN-mitigation strategies is crucial to crop production, their application is still limited in Mozambique, with quite a few reported uses of nematicides in the Manica and Maputo provinces. Therefore, adopting integrated management strategies that combine two or more practices, such as biological control, crop rotation, organic amendments, soil solarization, and, as a last resort, chemical nematicides, may be an option to effectively reduce the population of PPNs. This review gathers information on the occurrence and management of PPNs, as reported to date in Mozambique. Full article

Background: Phosphorus is an essential nutrient for plant growth and development, playing a multifaceted and vital role in plants. Phosphate Transporter 1 (PHO1) is a class of important functional genes involved in plant phosphorus uptake and transport. We identify PHOSPHATE 1 (PHO1) members in mung beans and investigate their response to low phosphorus stress, thereby aiding in the development of stress-tolerant, high-yielding mung bean varieties. Methods: A bioinformatic analysis was performed, which led to the identification of the PHO1 homologue sequence in mung beans. This analysis also elucidated its gene and protein structural characteristics alongside its phylogenetic relationships. qRT-PCR was used to analyze the expression patterns of genes in roots and leaves in response to conditions of prolonged low-phosphorus and phosphorus-deprivation stress. Results: Total PHO1 homologues were identified in mung beans, which can be grouped into 3 groups (Group I-III). Phylogenetic analysis indicates that VrPHO1s shares closer evolutionary relationships with PHO1 in legumes, and exhibits 6 collinear gene pairs with Glycine max (soybean), all with Ka/Ks ratios below 1, suggesting they have undergone purifying selection. The gene promoter region contains multiple cis-acting elements capable of participating in plant growth and development, stress responses, and plant hormone responses. Expression analysis revealed that more VrPHO1 genes responded to phosphorus stress in roots than in leaves; of these, the expression of VrPHO1; H2, VrPHO1; H3, and VrPHO1; H5 genes was significantly induced by continuous phosphorus-deficient stress. Conclusions: This study provides a comprehensive genome-wide identification of the PHO1 family in mung bean and provides valuable candidate gene resources for the future study of their biological functions and regulatory roles in phosphate-deficient stress. Full article

Inflammatory bowel disease (IBD) involves chronic inflammation and disruption of the intestinal barrier, often accompanied by alterations in gut microbiota composition. This study examined the protective potential of a prebiotic mixture extract (PME) prepared from Vigna radiata (mung bean), Vigna angularis (red bean), and Foeniculum vulgare (fennel) using the HT-29 cell and colitis animal model. PME exhibited concentration-dependent antioxidant activity, with greater radical-scavenging capacity in the ABTS assay than in the DPPH assay. In LPS-stimulated HT-29 epithelial cells, PME reduced the mRNA expression of inflammation-associated genes (TNF-α, IL-1β, NF-κB) and upregulated tight junction markers (CLDN1 and OCLN), demonstrating its anti-inflammatory and supportive effects on the intestinal barrier. Vitexin, a C-glycosylated flavonoid, was detected in PME and is expected to mediate these protective effects. In a DSS-induced colitis mouse model, PME administration alleviated disease severity by increasing colon length, reducing serum levels of inflammatory cytokines and COX-2/PGE2, and restoring intestinal permeability. Furthermore, PME modulated the gut microbiota by enhancing beneficial bacteria such as Bifidobacterium and Faecalibaculum while suppressing inflammation-associated taxa, including Escherichia, Bacteroides, and Mucispirillum. These improvements collectively suggest that PME reinforces epithelial barrier integrity and promotes intestinal homeostasis through both anti-inflammatory and microbiota-regulating actions. Full article

Bradyrhizobium is a genetically diverse genus that forms symbioses with numerous legumes, including major crops such as cowpea (Vigna unguiculata) and soybean (Glycine max). Understanding the genetic and symbiotic diversity of native strains is essential for improving inoculant technologies and enhancing biological nitrogen fixation in tropical agricultural systems. This study investigated Bradyrhizobium strains associated with these two legumes grown in adjacent tropical soils in Brazil to elucidate their genetic relationships, taxonomic placement, and host compatibility. A total of 34 Bradyrhizobium strains isolated from cowpea and soybean nodules were characterized using multilocus phylogenetic analyses (16S rRNA, gyrB, recA, and nodC). Selected strains underwent whole-genome sequencing for comparative analyses based on average nucleotide identity (ANI) and digital DNA–DNA hybridization (dDDH). Cross-inoculation assays were performed to evaluate nodulation capacity and symbiotic efficiency on both hosts. The strains displayed high genetic diversity, forming multiple phylogenetic clusters. Most grouped within the B. elkanii superclade, whereas several occupied divergent lineages, some potentially representing new taxa. Genome-based analyses supported these findings, showing intracluster ANI values above 95–96% and intercluster values below 94%. A distinct group of cowpea-derived strains exhibited high symbiotic efficiency but low genomic similarity to known type strains, suggesting the presence of a novel species with potential use in inoculants. In contrast, some soybean-derived strains were genetically identical to commercial inoculants, indicating persistence or re-isolation from previously inoculated soils. Notably, strain BR 13971, isolated from soybean, nodulated both hosts efficiently, demonstrating a broad host range and suggesting a unique symbiovar. Cross-inoculation assays showed that soybean-derived strains effectively nodulated cowpea, whereas cowpea-derived strains did not nodulate soybean, indicating asymmetrical host compatibility. Particularly for cowpea, strains BR 10926 and BR 10750 demonstrated higher symbiotic efficiency than the strains currently recommended for this crop. Overall, these findings enhance the understanding of Bradyrhizobium diversity in tropical soils and highlight promising native strains for future inoculant development. Full article

Drought significantly reduces global crop yields and agricultural productivity. This study aims to isolate drought-tolerant PGPR strains and evaluate their effects, both individually and in combination with salicylic acid (SA), on cowpea plants growth, physiological traits, antioxidant enzymes, and mineral content under both drought stress and non-stress conditions. Among fifteen bacterial isolates, AO7, identified as Streptomyces diastaticus subsp. ardesiacus PX459854 through 16S rRNA sequencing, demonstrated significant plant growth promotion in cowpea under gnotobiotic conditions. On the other hand, varying salicylic acid concentrations (0.5, 1.0, and 2.0 mM) was exposed to assess the plant growth of cowpea plants in a gnotobiotic system. A pot experiment in 2023 used a split-plot design with treatments for irrigation (unstressed and stressed) and different soaking treatments (control, S. diastaticus, salicylic acid (2 mM), and a combination). After 60 days, the combination treatment enhanced growth metrics, outpacing the control under stress. The microbial community in the T4 treatment exhibited the highest counts, while T8 (combination, stressed) showed lower counts but the highest chlorophyll content at 6.32 mg g⁻¹ FW. Notable increases in proline and significant changes in enzyme activities (PO, PPO, CAT, and APX) were observed, particularly in treatment T8 under stress, indicating a positive response to both treatments. Mineral content of cowpea leaves varied with soaking treatments of S. diastaticus and SA (2.0%) especially under drought stress which the highest values were 1.72% N, 0.16% P, and 2.66% K with treatment T8. Therefore, T8 (combination, stressed) > T6 (S. diastaticus, stressed) > T7 (salicylic acid, stressed) > T5 (control, stressed) for different applications under stressed conditions and T4 (combination, unstressed) > T2 (S. diastaticus, unstressed) > T3 (salicylic acid, unstressed) > T1 (control, unstressed) for the other applications under normal conditions. Thus, using S. diastaticus and SA (2.0%) in combination greatly enhanced the growth dynamics of cowpea plants under drought stress conditions. Full article

Megalurothrips usitatus (Bagrall 1913) (MTU) is a major pest of cowpea (Vigna unguiculata (L.) Walp.) and shows a strong preference for floral tissues. To clarify the spatiotemporal distribution of thrips, we conducted a detailed survey of their abundance in flowers of different developmental stages—sampled in the morning (preanthesis flowers, PAF; open flowers, OPF; postanthesis flowers, PoAF) and at dusk (preanthesis flowers scheduled to open the next morning, PAF-D; closed flowers, CF). Behavioral responses of MTU to floral volatiles from these stages were evaluated using a Y-tube olfactometer, followed by chemical analysis via gas chromatography–mass spectrometry (GC-MS). The results indicate that 58.3% of adults sheltered in keel petals, while 76.7% of nymphs aggregated inside the diadelphous stamens. Thrips abundance on OPF in the morning was significantly higher than on PAF or PoAF, but did not differ significantly from that on CF. Olfactometric assays demonstrated a clear preference of MTU for OPF, which emitted a greater number and higher concentrations of volatile compounds compared to PAF, PAF-D, CF, and PoAF. Together, these findings reveal distinct spatiotemporal dynamics of thrips in relation to cowpea flower development, underscoring the role of floral age in driving host-switching behavior. Full article

Bambara groundnut is an underutilized legume with significant potential for enhancing nutrition and food security. However, limited knowledge of its seed systems hinders the development of targeted interventions. This study assessed the Bambara groundnut seed systems and seed quality in Ghana. A semi-structured questionnaire was used to examine seed production, conditioning, and saving practices, while 150 farmer-saved seed samples were evaluated for quality. The findings revealed that the seed system is predominantly informal, with 99% of farmers relying on their own saved seeds, which showed poor germination and emergence. About 54.4% sourced seeds from local markets, and 60.7% recycled seeds for five years or more. Seeds were stored unshelled in polypropylene bags in Tolon and shelled in the Kintampo South and Talensi Districts. Seed selection was primarily based on size (in Tolon) and visible absence of disease symptoms (in Kintampo South and Talensi). An incidence (7.6%) of seed-borne pathogens was recorded, with Aspergillus flavus (38.8%) and A. niger (16.6%) being most prevalent. Other pathogens included Macrophomina phaseolina (11.5%), Rhizopus spp. (6.5%), Curvularia lunata (5.3%), and A. fumigatus (1.9%). This study highlights the need to support community-based seed systems to improve farmers’ access to quality Bambara groundnut seed. Full article

The Fabaceae family plays a vital role in tropical ecosystems and human livelihoods due to its ecological, nutritional, and medicinal significance. This study provides a comprehensive ethnobotanical assessment of Fabaceae in Maha Sarakham Province, Northeastern Thailand. A total of 83 taxa representing 52 genera were recorded, reflecting the family’s high species richness and cultural importance in local communities. Field surveys and semi-structured interviews were conducted across diverse habitats, including homegardens, community forests, markets, and agricultural areas. Quantitative ethnobotanical indices—Species Use Value (SUV), Relative Frequency of Citation (RFC), Fidelity Level (FL), and Informant Consensus Factor (F_ic)—were used to evaluate species importance and cultural consensus. The highest SUV and RFC values were observed for Arachis hypogaea L., Glycine max (L.) Merr., Sesbania grandiflora (L.) Poir., and Vigna unguiculata subsp. sesquipedalis (L.) Verdc., indicating their central roles in local diets and livelihoods. Medicinally significant taxa, including Abrus precatorius and Albizia lebbeck, exhibited high FL and Fic values, reflecting strong community agreement on their therapeutic uses. Diverse applications—spanning food, medicine, fodder, fuelwood, dye, ornamental, and construction materials—highlight the multifunctionality of Fabaceae in rural livelihoods. The documentation of 44 new provincial records further emphasizes the value of integrating Indigenous and local knowledge into biodiversity assessments. These findings provide essential insights for sustainable utilization, conservation planning, and the integration of traditional knowledge with modern scientific approaches. Full article

Adzuki bean (Vigna angularis), a major grain legume in Asia, is susceptible to infection by cucumber mosaic virus (CMV), which threatens crop productivity. Here, we characterized the CMV-Pa3 isolate from adzuki bean and investigated the role of specific amino acid residues in the viral 2a protein influencing systemic infection of legumes. Phylogenetic analysis demonstrated that CMV-Pa3 is genetically distinct from other legume-infecting isolates. Inoculation assays revealed that CMV-Pa3 causes systemic infection in adzuki bean, cowpea, soybean, and pea, whereas the control isolate CMV-Rs1 is restricted to inducing local necrotic lesions in cowpea and adzuki bean. Site-directed mutagenesis targeted two conserved amino acid positions (631 and 641) in the 2a protein of CMV-Rs1. Functional analysis showed that residue 631 (Tyr) facilitates systemic infection across all tested legumes, while alteration at position 641 (Ser) alone enables systemic infection in cowpea and pea. These findings identify amino acid determinants in the CMV 2a protein critical for overcoming host restrictions and mediating systemic infection in various leguminous species. This work offers new insights into the molecular mechanisms underlying CMV pathogenicity and host specificity. Full article

As a pulse crop, mung beans are associated with nitrogen-fixing bacteria, which can improve soil fertility, lower the need for nitrogen fertilizers, and increase yield and soil quality for subsequent harvests. This study aimed to identify effective rhizobial inoculants for mung beans (Vigna radiata L.) by evaluating selected strains for cowpea (Vigna unguiculata L.), soybean (Glycine max L.), and common bean (Phaseolus vulgaris L.) under controlled (axenic) conditions. Cowpea, soybean, and common bean strains were tested as mung beans inoculants under axenic conditions. Promising strains were then tested in the field to assess grain yield and to quantify nitrogen fixation using the ¹⁵N natural abundance method. The cowpea strain BR 3302 (Bradyrhizobium viridifuturi) increased mung bean yield by 18%, achieving results similar to a 240 kg N ha⁻¹ fertilizer application. The soybean strain BR 96 (B. elkanii) facilitated the highest nitrogen fixation (35.3 kg N ha⁻¹), significantly surpassing the contribution of indigenous diazotrophic bacteria (18.5 kg N ha⁻¹). Interestingly, BR 3302 appeared to primarily enhance nitrogen uptake from the soil (65% of plant N), indicating the presence of other potential plant growth-promoting mechanisms beyond nitrogen fixation. This research demonstrates that Bradyrhizobium strains can benefit mung beans through both enhanced nitrogen fixation and additional growth-promoting mechanisms, offering a sustainable approach to improve mung beans production. Full article

Anthocyanins pigment plant tissues, mitigate biotic and abiotic stresses, and deliver human health benefits; raising their content in mung bean (Vigna radiata) sprouts is a long-standing research target. Transcriptome analysis identified VrNAC25, a NAC transcription factor whose expression closely parallels anthocyanin accumulation; functional validation in mung bean confirmed that VrNAC25 acts as a positive regulator of the pathway. Although VrNAC25 does not bind to the promoters of the key structural genes VrDFR or VrLDOX, it indirectly controls anthocyanin synthesis by interacting with the core R2R3-MYB activator VrMYB90, previously established as the central regulator of anthocyanin production in mung beans. This interaction operates at both transcriptional and protein levels, thereby amplifying the expression of downstream structural genes and boosting pigment accumulation. Our findings refine the molecular network governing anthocyanin biosynthesis in sprouts and provide a clear theoretical basis for breeding or biotechnological strategies aimed at enhancing the nutritional quality and commercial value of mung bean products through light treatment or by selecting an anthocyanin-rich mung bean variety. Full article

The Salt Overly Sensitive 1 (SOS1) gene family encodes plasma membrane Na⁺/H⁺ antiporters essential for ionic homeostasis and salt tolerance in plants. Here, we performed a comprehensive genome-wide characterization of SOS1 genes in allotetraploid cotton (Gossypium hirsutum L.). Fifteen GhSOS1 genes were identified and found unevenly distributed across the A and D subgenomes, indicating that segmental duplication, rather than tandem duplication, was the major driver of family expansion. Phylogenetic analysis resolved four well-supported clades, revealing deep conservation with dicot homologs from Arabidopsis thaliana, Solanum species, and Vigna trilobata, alongside cotton-specific diversification. Ka/Ks ratios indicated strong purifying selection with limited adaptive divergence. Conserved Na⁺/H⁺ exchanger domains and membrane-spanning architectures were maintained, whereas motif and promoter variation suggested functional specialization. Structural modeling confirmed typical multi-helical antiporter topology but revealed the absence of a cytoplasmic regulatory domain, implying alternative modes of regulation, possibly via oxidative stress–response components such as RCD1. Promoter analysis uncovered multiple stress- and hormone-responsive cis-elements, and expression profiling identified GhSOS1-5 and GhSOS1-11 as strongly induced by salt and drought stress. Collectively, these findings highlight the evolutionary retention, structural conservation, and regulatory diversification of GhSOS1 genes, establishing a foundation for improving abiotic stress resilience in cotton. Full article

Salinization is one of the main environmental challenges affecting agriculture in semi-arid regions. We evaluated the feasibility of foliar magnesium and its effects at different doses on the acclimation of cowpea varieties under salt stress. The experiment occurred in a greenhouse using a randomized block design in a 2 × 3 × 4 factorial scheme, with five replicates. Two cowpea varieties—‘Pingo de Ouro’ and ‘Costela de Vaca’—were subjected to three salinity levels in irrigation water (0.54, 3.50, and 5.00 dS m⁻¹) and four foliar magnesium (Mg) doses (0, 1, 2, and 3 mL L⁻¹). Under 3.50 dS m⁻¹ salinity, the 1 mL L⁻¹ dose resulted in the highest yield per plant (18.29 g). CO₂ assimilation was highest with 2 mL L⁻¹ Mg at 3.50 dS m⁻¹ for ‘Costela de Vaca’, and with 1 mL L⁻¹ Mg at 5.00 dS m⁻¹ for ‘Pingo de Ouro’. The ‘Pingo de Ouro’ variety was more tolerant to ‘Costela de Vaca’. Foliar Mg fertilization proved to be a promising strategy to mitigate the effects of salt stress in cowpea, especially for ‘Pingo de Ouro’. Magnesium effectively reduces salt stress, but its effect varies by plant variety and irrigation salinity, necessitating customized dose adjustments. Full article