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Moringa is the sole genus in the family Moringaceae used for medicinal and nutrient purposes. Morphological features, phytochemical attributes, and molecular characterization were used for the genetic association and classification among Moringa oleifera , M. peregrina , and M. stenopetala . Moringa peregrina recorded a similarity of 84% lonely and placed M. stenopetala with M. oleifera into a cluster score with a similarity of 95.3%. M. peregrina is characterized by phenolic content (243 mg/100 g), flavonoids (7 mg/100 g), and antioxidant activity (1226.85 mg/100 g). GC-MS analysis revealed that M. oleifera contained twenty compounds with 2-decenal (E) (39.14%), 2-undecenal (15.51%), nonanal (3.60%), and 2-octenal, (E) (2.48%), while M. peregrina identified eighteen compounds with 2-decenal (Z) (25.42%), 2-docecen-1-al (9.35%), and 13-Docosenoic acid, methyl ester, (Z) (4.16%). M. stenopetala identified fifteen compounds containing 2-decenal (E) (26.67%), 2-undecenal (24.10%), and nonanal (4.40%). A broad sense of similarity has been scored between M. oleifera and M. stenopetala by the phytochemical compositions, especially the similarity in the main compounds such as 2-decenal (E), 2-undecenal, and nonanal. It can be concluded that efforts need to be expanded to pay attention to study Moringa taxa, due to the rarity of Moringa peregrina , and the focus should be on sustainable utilization and conservation. The potential of these taxa would greatly benefit indigenous species in terms of their maintenance, and there is a need for more comprehensive bio-prospecting studies. Therefore, this study evaluates the variability among Moringa and highlights the significance of leaf and seed ultrastructure to provide more information and evaluate potential approaches.

Glucosinolates (GS) are metabolized to isothiocyanates that may enhance human healthspan by protecting against a variety of chronic diseases. Moringa oleifera , the drumstick tree, produces unique GS but little is known about GS variation within M . oleifera , and even less in the 12 other Moringa species, some of which are very rare. We assess leaf, seed, stem, and leaf gland exudate GS content of 12 of the 13 known Moringa species. We describe 2 previously unidentified GS as major components of 6 species, reporting on the presence of simple alkyl GS in 4 species, which are dominant in M . longituba . We document potent chemoprotective potential in 11 of 12 species, and measure the cytoprotective activity of 6 purified GS in several cell lines. Some of the unique GS rank with the most powerful known inducers of the phase 2 cytoprotective response. Although extracts of most species induced a robust phase 2 cytoprotective response in cultured cells, one was very low ( M . longituba ), and by far the highest was M . arborea , a very rare and poorly known species. Our results underscore the importance of Moringa as a chemoprotective resource and the need to survey and conserve its interspecific diversity.

Taste drives consumption of foods. The tropical tree Moringa oleifera is grown worldwide as a protein-rich leafy vegetable and for the medicinal value of its phytochemicals, in particular its glucosinolates, which can lead to a pronounced harsh taste. All studies to date have examined only cultivated, domestic variants, meaning that potentially useful variation in wild type plants has been overlooked. We examine whether domesticated and wild type M . oleifera differ in myrosinase or glucosinolate levels, and whether these different levels impact taste in ways that could affect consumption. We assessed taste and measured levels of protein, glucosinolate, myrosinase content, and direct antioxidant activity of the leaves of 36 M . oleifera accessions grown in a common garden. Taste tests readily highlighted differences between wild type and domesticated M . oleifera . There were differences in direct antioxidant potential, but not in myrosinase activity or protein quantity. However, these two populations were readily separated based solely upon their proportions of the two predominant glucosinolates (glucomoringin and glucosoonjnain). This study demonstrates substantial variation in glucosinolate composition within M . oleifera . The domestication of M . oleifera appears to have involved increases in levels of glucomoringin and substantial reduction of glucosoonjnain, with marked changes in taste.

Moringa oleifera (MO) and M. stenopetala (MS) (family Moringaceae; order Brassicales) are multipurpose tree/shrub species. They thrive under marginal environmental conditions and produce nutritious edible parts. The aim of this study was to determine the mineral composition of different parts of MO and MS growing in their natural environments and their potential role in alleviating human mineral micronutrient deficiencies (MND) in sub-Saharan Africa. Edible parts of MO (n = 146) and MS (n = 50), co-occurring cereals/vegetables and soils (n = 95) underneath their canopy were sampled from localities in southern Ethiopia and Kenya. The concentrations of seven mineral elements, namely, calcium (Ca), copper (Cu), iodine (I), iron (Fe), magnesium (Mg), selenium (Se), and zinc (Zn) in edible parts and soils were determined using inductively coupled plasma-mass spectrometry. In Ethiopian crops, MS leaves contained the highest median concentrations of all elements except Cu and Zn, which were greater in Enset (a.k.a., false banana). In Kenya, Mo flowers and MS leaves had the highest median Se concentration of 1.56 mg kg-1 and 3.96 mg kg-1, respectively. The median concentration of Se in MS leaves was 7-fold, 10-fold, 23-fold, 117-fold and 147-fold more than that in brassica leaves, amaranth leaves, baobab fruits, sorghum grain and maize grain, respectively. The median Se concentration was 78-fold and 98-fold greater in MO seeds than in sorghum and maize grain, respectively. There was a strong relationship between soil total Se and potassium dihydrogen phosphate (KH2PO4)-extractable Se, and Se concentration in the leaves of MO and MS. This study confirms previous studies that Moringa is a good source of several of the measured mineral nutrients, and it includes the first wide assessment of Se and I concentrations in edible parts of MO and MS grown in various localities. Increasing the consumption of MO and MS, especially the leaves as a fresh vegetable or in powdered form, could reduce the prevalence of MNDs, most notably Se deficiency.

The drumstick tree ( Moringa oleifera Lam.) is a perennial crop that has gained popularity in certain developing countries for its high-nutrition content and adaptability to arid and semi-arid environments. Here we report a high-quality draft genome sequence of M. oleifera . This assembly represents 91.78% of the estimated genome size and contains 19,465 protein-coding genes. Comparative genomic analysis between M. oleifera and related woody plant genomes helps clarify the general evolution of this species, while the identification of several species-specific gene families and positively selected genes in M. oleifera may help identify genes related to M. oleifera ’s high protein content, fast-growth, heat and stress tolerance. This reference genome greatly extends the basic research on M. oleifera , and may further promote applying genomics to enhanced breeding and improvement of M. oleifera .

Background Embryogenic callus (EC) has strong regenerative potential, useful for propagation and genetic transformation. miRNAs have been confirmed to play key regulatory roles in EC regeneration across various plants. However, challenges in EC induction have hindered the breeding of drumstick ( Moringa oleifera Lam.), a tree with significant commercial potential. Understanding the regulatory networks of miRNAs-lncRNAs during EC formation in drumstick is crucial for overcoming these barriers. Results In this study, three drumstick EC small RNA libraries were sequenced using an Illumina Nova 6000 system. We identified 50 known miRNAs and 233 novel miRNAs. Target prediction and functional analysis showed that these miRNAs are involved in plant hormone signal transduction. Notably, miR319a and miR319b were upregulated throughout the entire process, while miR171 and miR160 were downregulated in the earlier stage but upregulated in the later stage. The expression patterns of 6 miRNAs detected by qRT-PCR were consistent with those observed in RNA-seq. The regulatory relationships between 6 selected highly expressed miRNAs and their target genes generally conformed to a negative regulatory pattern. Furthermore, miR156 and MolncRNA2275 were identified as key regulators in miRNA-mRNA-lncRNA network. Conclusions In summary, our study provides valuable insights into the molecular mechanisms underlying EC formation and enhances the understanding of the miRNA networks involved in this process.

The moringa tree Moringa oleifera is a fast-growing, drought-resistant tree cultivated across the lowland dry tropics worldwide for its nutritious leaves. Despite its nutritious reputation, there has been no systematic survey of the variation in leaf nutritional quality across M. oleifera grown worldwide, or of the other species of the genus. To guide informed use of moringa, we surveyed protein, macro-, and micro- nutrients across 67 common garden samples of 12 Moringa taxa, including 23 samples of M. oleifera. Moringa oleifera, M. concanensis, M. stenopetala, an M. concanensis X oleifera hybrid, and M. longituba were highest in protein, with M. ruspoliana having the highest calcium levels. A protein-dry leaf mass tradeoff may preclude certain breeding possibilities, e.g. maximally high protein with large leaflets. These findings identify clear priorities and limitations for improved moringa varieties with traits such as high protein, calcium, or ease of preparation.

This study investigated the impact of feeding 17% moringa leaf meal (MLM) on the ruminal and fecal microbial composition and body weight gain (BWG) performance of lambs ( Ovis aries ) and kids ( Capra hircus ). A total of n  = 28 lambs ( n  = 14, no-moringa, n  = 14, 17% moringa) and 24 kids ( n  = 12, no-moringa, n  = 12, 17% moringa) were involved in the experiment and body weight was recorded fortnightly. Metagenomic shotgun sequencing was performed on 28, 22, and 26 ruminal solid, liquid fraction, and fecal samples from lambs, and 23, 22, and 23 samples from kids. Moringa supplementation significantly increased BWG in lambs (21.09 ± 0.78 to 26.12 ± 0.81 kg) and kids (14.60 ± 1.29 to 18.28 ± 1.09 kg) ( p -value ≤ 0.01). Microbiome analysis revealed an elevated Firmicutes:Bacteroidetes ratio in the moringa diet group. Moringa-fed animals exhibited increased microbial genera associated with volatile fatty acids (VFAs) production ( Prevotella, Anaerovibrio, Lachnospiraceae, Butyrivibrio, Christensenella ) and starch and fiber digesters ( Proteobacteria, Ruminococcus ). The increase in the bacterial genus Sharpea suggested possible methane reduction and decreased proportion of pathogens, Aliarcobacter _ ID28198 , Campylobacter _ ID194 and Campylobacter _ ID1660076 suggest health benefits. Kyoto Encyclopedia of Genes and Genomes (KEGG) analysis demonstrated significant alterations in microbial gene pool and metabolic pathways related to carbohydrate, protein, lipid and energy metabolism, indicating potential improvements in animal health. Overall, moringa feeding showed higher energy recovery, improved growth, and potential benefits in methane reduction and reduced pathogenic bacteria. Key points • Study assessed the effects of Moringa olifera diet on lambs and kids. • Improved growth performance noted with moringa diet. • Moringa feed increased Firmicutes:Bacteroidetes ratio in rumen.

Moringa oleifera ’s rich phytochemical profile positions it as a promising natural alternative for sustainable pest management. This study characterizes the phytochemical composition and antioxidant activity of M. oleifera extracts and, for the first time, evaluates their insecticidal potential against Tribolium castaneum (red flour beetle). Extracts from leaves, stems, roots, and seeds were prepared using ethanol, methanol, acetone, and distilled water. Phytochemical analysis identified high levels of total phenolics (7.18 µg GAE/mg DW, ethanol leaf extract), flavonoids (23.52 µg QE/mg DW, ethanol leaf extract), tannins (245.4 mg CE/g DW, acetone seed extract), saponins (13.7%, methanol leaf extract), and alkaloids (30.06 mg atropine/100 mL, water stem extract). HPLC quantification revealed abundant bioactive compounds, including phenolic acids (gallic, caffeic, chlorogenic, and ferulic acids), flavonoids (apigenin, quercetin, kaempferol), flavanols (catechin, epicatechin, procyanidin dimers), and iridoids (oleuroside), with gallic acid, quercetin-3-O-rhamnoside, and kaempferol as dominant constituents. Antioxidant assays demonstrated significant activity, with methanol root extract showing 71% DPPH inhibition and methanol stem extract exhibiting the highest total antioxidant capacity (36.12 mg GAE/g DW). Insecticidal bioassays revealed ethanol root extracts induced 90% mortality in T. castaneum within 24 h at 30% concentration, outperforming other extracts. These findings underscore M. oleifera ’s dual functionality as a potent bioinsecticide and antioxidant, advocating for its integration into sustainable pest management. Further research should optimize extraction protocols and field-scale formulations to enhance practical applications.

The aqueous leaf extract of Moringa oleifera Lam. (LM-A) is reported to have many health beneficial bioactivities and no obvious toxicity, but have mild adverse effects. Little is known about the mechanism of these reported adverse effects. Notably, there has been no report about the influence of LM-A on intestinal microecology. In this study, animal experiments were performed to explore the relationships between metabolic adaptation to an LM-A-supplemented diet and gut microbiota changes. After 8-week feeding with normal chow diet, the body weight of mice entered a stable period, and one of the group received daily doses of 750-mg/kg body weight LM-A by gavage for 4 weeks (assigned as LM); the other group received the vehicle (assigned as NCD). The liver weight to body weight ratio was enhanced, and the ceca were enlarged in the LM group compared with the NCD group. LM-A-supplemented-diet mice elicited a uniform metabolic adaptation, including slightly influenced fasting glucose and blood lipid profiles, significantly reduced liver triglycerides content, enhanced serum lipopolysaccharide level, activated inflammatory responses in the intestine and liver, compromised gut barrier function, and broken intestinal homeostasis. Many metabolic changes in mice were significantly correlated with altered specific gut bacteria. Changes in Firmicutes , Eubacterium rectale / Clostridium coccoides group, Faecalibacterium prausnitzii , Akkermansia muciniphila , segmented filamentous bacteria, Enterococcus spp., and Sutterella spp. may play an important role in the process of host metabolic adaptation to LM-A administration. Our research provides an explanation of the adverse effects of LM-A administration on normal adult individuals in the perspective of microecology.