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Vigna

Vigna is a of flowering plants in the legume family , consisting of 107 accepted primarily distributed across tropical and subtropical regions worldwide. These are mostly herbaceous, including annuals and perennials, and are characterized by their ability to fix nitrogen through symbiotic relationships with , enhancing . The , first described by Savi in , plays a crucial role in due to its domesticated members, which provide essential protein-rich foods in regions with challenging environmental conditions. Vigna encompasses more than 100 wild species alongside about 10 domesticated ones, with centers of diversity in and . Taxonomically, it is divided into five subgenera: Ceratotropis, Haydonia, Lasiospron, Plectrotropis, and Vigna, with domesticated species mainly in the subgenera Ceratotropis, Plectrotropis, and Vigna. Prominent cultivated species include the cowpea (V. unguiculata), a drought-tolerant native to and grown on over 15 million hectares producing around 9 million metric tons annually as of 2023; the mung bean (V. radiata), widely cultivated in for its edible seeds and sprouts; the adzuki bean (V. angularis), used in traditional Asian sweets; the black gram (V. mungo), a key in ; and the rice bean (V. umbellata), valued for its resilience in marginal lands. Economically, Vigna species are vital for , nutrition, and livelihoods in tropical underdeveloped countries, where they are consumed as dry grains, fresh pods, or processed into products like noodles and pastes, while also serving as and . Collectively, they occupy more than 25 million hectares of farmland each year as of , with , , and black gram accounting for the majority of production. Their small sizes (416–1,394 Mbp) and fast growth facilitate genomic and for improved , underscoring their potential in addressing climate challenges and . Conservation efforts focus on genebanks holding over 129,000 accessions as of to preserve relatives essential for crop improvement.

Taxonomy and classification

Etymology and history

The genus Vigna was established in 1824 by Italian naturalist Gaetano Savi in his publication Nuovo Giornale dei Letterati, honoring the 17th-century Italian botanist Domenico Vigna (ca. 1577–1647), who served as professor of and director of the Orto Botanico di . This naming reflected the era's practice of commemorating prominent figures in , though early descriptions focused primarily on morphological traits shared with related . Historically, the genus faced taxonomic confusion, particularly with , due to overlapping pod and seed characteristics; many Old World species were initially placed under by Alphonse de Candolle in 1825. Synonyms such as Azukia, Dolichos, and Rudua were applied to various taxa now recognized within Vigna, especially in Asian and African groups, as documented in early 20th-century classifications. Key milestones include Robert Wilczek's 1954 transfer of mung bean (V. radiata) from to Vigna in the Flore du Congo Belge et du Ruanda-Urundi, based on floral and seed differences. Twentieth-century revisions solidified the separation of Vigna from Phaseolus, emphasizing biochemical profiles, pollen structure, and geographic origins—Phaseolus restricted to New World species—following Bernard Verdcourt's 1970 comprehensive treatment in Kew Bulletin, which expanded Vigna to include about 80 species. A seminal 1978 study by Roland Maréchal and colleagues in Taxon analyzed morphological and palynological data across 200+ specimens, proposing five subgenera for Vigna and confirming distinctions via seed protein electrophoresis and other traits. More recently, molecular approaches have refined these boundaries; for instance, a 2011 phylogenetic analysis in the American Journal of Botany using chloroplast trnK and nuclear ITS sequences supported revisions to subgenus Ceratotropis, resolving longstanding ambiguities in Asian Vigna species.

Phylogenetic relationships

The genus Vigna is classified within the family Fabaceae, subfamily Faboideae, tribe Phaseoleae, and subtribe Phaseolinae. This placement is supported by both morphological traits, such as papilionoid flowers and legume fruits, and molecular data from chloroplast and nuclear loci that align Vigna with other phaseoloid legumes. Vigna is phylogenetically close to Phaseolus, with which it forms a sister group relationship within subtribe Phaseolinae, though some analyses resolve Physostigma as the immediate sister to Vigna sensu stricto. Distinctions from Phaseolus are evident in pollen structure, where Vigna species typically exhibit triporate, coarsely reticulate pollen grains (except in subgenus Haydonia, which has smooth exine), compared to the psilate or finely reticulate pollen in Phaseolus. Style morphology also differs, with Vigna styles often beaked beyond the stigma, varying by subgenus, while Phaseolus styles are typically glabrous or differently pubescent along their length. Biochemical markers, including seed protein profiles, further separate the genera; for instance, Vigna species show distinct electrophoretic patterns of phaseolin and other storage proteins not matching those in Phaseolus. A 2024 phylogenetic study in the American Journal of Botany reconstructed the of Vigna sensu stricto using matK-trnK and nuclear ITS/5.8S sequences, resolving five main s corresponding to subgenera (Lasiospron, Vigna, Haydonia, Ceratotropis, and an expanded Plectrotropis) plus an additional V. kirkii/V. stenophylla . This analysis, incorporating 90 species, dated the diversification of Vigna sensu stricto to approximately 6.3–6.73 million years ago and highlighted an African-Asian divergence within the lineages, reflecting biogeographic patterns driven by climate shifts. The study confirmed the exclusion of species (now in segregate genera like Ortholobium and Ramirezella), reducing the total species count in Vigna sensu stricto to about 90.

Subgenera and sections

In recent phylogenetic treatments of Vigna sensu stricto ( species), the genus is divided into five subgenera: Ceratotropis, Haydonia, Lasiospron, Plectrotropis, and Vigna. Some classifications include two additional subgenera, Macrorhyncha and Sigmoidotropis, primarily for species, though these are frequently recognized as separate genera in contemporary phylogenies. This infrageneric classification, originally proposed by Verdcourt in 1970 and refined by Maréchal et al. in 1978, has been supported and updated through molecular phylogenetic analyses using markers such as nuclear rDNA-ITS and chloroplast atpB-rbcL sequences. Subgenus Ceratotropis (Piper) Verdc. encompasses approximately 27 Asian species, including major crops such as (V. radiata) and black gram (V. mungo). It is distinguished by a beaked petal with a conspicuous supporting the style, small seeds with , and a primary center of diversity in South and . Subgenus Haydonia (Wilczek) Verdc. comprises African wild adapted to savannas and woodlands, characterized by trailing or erect habits and seeds with . Subgenus Lasiospron (Benth.) Verdc. includes climbing vines primarily from the Neotropics, with some amphi-tropical , featuring long peduncles, pubescent pods, and wide-ranging ecological tolerance from forests to disturbed areas. Subgenus Plectrotropis (Piper) Verdc. consists of prostrate or twining herbs, often tuberous-rooted, native to , with diagnostic traits including a declined pod beak and rough seed surfaces. Subgenus Vigna Savi includes the (V. unguiculata) and related African , marked by straight or slightly curved pod beaks, arillate seeds, and adaptation to arid and semi-arid environments. The primary criteria for these divisions emphasize floral (e.g., pocket size and shape), pod orientation and surface texture, seed size, shape, and development, alongside geographic and ecological patterns. Revisions in 2012, detailed in a Rheedea , focused on subgenus Ceratotropis, elevating V. silvestris from varietal status to and describing new taxa like V. sahyadriana, based on pod count, seed , and shape. These updates increased the recognized in section Ceratotropis to eight, enhancing resolution within the Asian . Certain species remain due to morphological variability and evidence of hybridization complicating placement. For instance, V. luteola exhibits traits overlapping subgenera Vigna and Lasiospron, with phylogenetic studies indicating hybrid origins involving V. unguiculata , leading to unresolved taxonomic status.

Description

Morphology

Vigna species exhibit a range of growth habits, typically as annual or perennial herbs or subshrubs that are erect, climbing, or prostrate, with stems often twining and reaching lengths of up to 5 m in climbing forms. The stems are herbaceous, sometimes woody at the base, and support trifoliolate leaves arranged alternately along their length. These leaves consist of three ovate to lanceolate leaflets, each 2–15 cm long and 1–10 cm wide, with conspicuous caducous stipules at the base. The reproductive structures feature papilionaceous flowers, characteristic of the family, arranged in axillary racemes. Individual flowers measure 0.5–3 cm long, displaying colors such as yellow, purple, or white, with the standard petal typically 1–3 cm in length. The is campanulate, 2–6 mm long, and divided into four shorter lobes, while the includes a that varies by —for instance, a beaked keel in subgenus Ceratotropis. Fruits develop as linear, cylindrical pods, 3–30 cm long and 0.5–1.5 cm wide, which are dehiscent and contain 5–20 seeds per pod. The seeds are variable but often reniform or oblong, measuring 2–10 mm long, with a prominent hilum and, in many species, an aril or strophiole.

Reproduction and life cycle

Vigna species exhibit diverse reproductive strategies, primarily involving self-pollination, though some facilitate outcrossing through insect vectors. Flowering occurs on axillary inflorescences, typically racemose structures bearing 2–10 flowers per node, with anthesis often synchronized within a short daily window to optimize pollination efficiency. Most cultivated species, such as V. unguiculata (cowpea) and V. radiata (mung bean), are predominantly autogamous, with pollen transfer occurring within the flower via mechanical tripping by the flower's own structures or small insects; however, larger bees like Bombus spp. and Xylocopa spp. can promote limited outcrossing (up to 5–10% in some populations) by accessing nectar rewards. Pollination is aided by nectar guides—contrasting yellow or pale markings on the inner petal surfaces—that direct pollinators to the reproductive organs, enhancing contact with anthers and . Following successful , fertilization proceeds rapidly, with pollen tubes growing through the to reach ovules within hours; Vigna are diploid, with numbers ranging from 2n=20 (e.g., V. lasiocarpa) to 2n=22 (most , including V. unguiculata and V. radiata). Self-compatibility is widespread, but pollinator dependence in certain like V. caracalla results in higher fruit set (up to 51%) under cross- compared to autonomous selfing (20–27%). The of Vigna varies by habit and environment, with most cultivated being warm-season annuals that complete their cycle in 60–120 days from to maturity, influenced by photoperiod and . For instance, V. radiata typically matures in 60–90 days, while V. unguiculata requires 50–160 days depending on and conditions. , such as V. vexillata, overwinter via underground tubers that store nutrients, enabling regrowth in subsequent seasons and extending longevity beyond one year. , often physical due to impermeable seed coats, delays in wild relatives, providing to unpredictable rainfall; mechanisms include hardseededness, broken by or alternating wet-dry cycles. Propagation in Vigna is predominantly sexual via , which are sown directly after to overcome and achieve 80–95% rates under optimal conditions (25–35°C). Vegetative is feasible in select like V. unguiculata, where cuttings (2–3 nodes) in 7–14 days without hormones, flowering within 14 days and producing genetically uniform plants for or rapid multiplication. This method bypasses the juvenile phase, shortening timelines for production compared to seed-raised plants (30–40 days to flowering).

Distribution and ecology

Geographic distribution

The genus Vigna exhibits a native distribution, encompassing tropical and subtropical regions across , , , and the . This broad range reflects the adaptability of its approximately 107 accepted to diverse warm climates. The highest species diversity is concentrated in , where around 73 occur natively in tropical zones, representing roughly 70% of the genus. hosts about 20% of the , primarily within the subgenus Ceratotropis, which comprises approximately 23 endemic to the region. In the , native diversity is lower, with fewer than ten wild documented, mainly in tropical areas. Through human-mediated dispersal, Vigna species have been introduced widely beyond their native ranges, particularly into subtropical and temperate agricultural zones globally. For instance, the African native cowpea (V. unguiculata) was introduced to the Americas as early as the mid-16th century via Portuguese trade routes to Brazil, subsequently spreading northward. Similarly, Asian species like mung bean (V. radiata) have been established in African and American cultivation systems, enhancing the genus's presence in non-native subtropics. These introductions have contributed to the cosmopolitan footprint of cultivated Vigna taxa while preserving the core native pantropical pattern.

Habitat and environmental adaptations

Species of the genus Vigna primarily inhabit tropical and subtropical climate zones, thriving in diverse environments such as savannas, open forests, and coastal dunes across , , and . These plants demonstrate remarkable tolerance to marginal conditions, including nutrient-poor soils, prolonged drought, and high temperatures, with optimal growth occurring between 20°C and 35°C. Many species can occupy elevations ranging from sea level up to 2000 m, allowing adaptation to varied topographies from lowland grasslands to montane regions. A key physiological enabling Vigna to persist in nutrient-deficient soils is their ability to form symbiotic -fixing root nodules with rhizobial bacteria, primarily from the genera and . This facilitates the conversion of atmospheric into usable forms, enhancing and vigor in low-nitrogen environments. Additionally, varies across the genus, with mechanisms such as deep systems, reduced , and modifications (e.g., smaller, hairy leaves) that minimize water loss and improve heat dissipation during terminal periods. Certain wild species exhibit specialized tolerances to extreme conditions; for instance, V. marina demonstrates high salt tolerance, enabling it to colonize coastal and saline habitats like sandy beaches and dunes. Cultivated Vigna crops, such as (V. unguiculata), often display photoperiod sensitivity, where flowering is delayed under long day lengths, aiding adaptation to seasonal variations in tropical latitudes.

Ecological interactions

Vigna species, as members of the legume family, form mutualistic with soil bacteria and fungi that enhance nutrient acquisition and contribute to and cycling. These plants primarily associate with , such as Bradyrhizobium japonicum and Sinorhizobium fredii, which form root nodules to fix atmospheric into plant-usable forms, reducing reliance on external fertilizers and improving in nitrogen-poor environments. In Vigna radiata (), this increases plant , content, and accumulation, with wild accessions showing greater responsiveness than cultivated ones. Concurrently, Vigna engages in arbuscular mycorrhizal (AM) associations with fungi like Rhizophagus irregularis, which extend root hyphae to improve uptake from soil, particularly in phosphorus-limited habitats; however, this can sometimes compete with rhizobial nodulation, leading to variable tripartite outcomes depending on and soil conditions. Vigna species are susceptible to various pests and pathogens that influence their ecological dynamics and interactions within plant communities. Insect pests such as the cowpea aphid (Aphis craccivora) feed on sap, causing direct damage and vectoring viruses like cowpea aphid-borne mosaic virus (CABMV), which induces mosaic symptoms and yield losses up to 60% in affected plants. Pod borers, notably Maruca vitrata (legume pod borer), infest flowers and pods of species like cowpea (Vigna unguiculata), webbing them together and boring into seeds, which disrupts reproduction and serves as a food source for predatory insects. Viral diseases, including cowpea mosaic virus (CPMV), cause chlorosis, necrosis, and stunted growth, with transmission often facilitated by beetles or aphids. Wild Vigna species, such as those in subsection Catiang, can act as reservoirs for these viruses and begomoviruses like mungbean yellow mosaic India virus (MYMIV), potentially spilling over to cultivated crops in shared habitats. In ecosystems, Vigna species play roles as cover crops and wildlife resources, though some exhibit invasive tendencies in non-native ranges. As cover crops, species like and (V. radiata) provide ground cover that suppresses weeds, reduces by stabilizing soil particles during rainfall, and enhances through root systems and addition. Seeds of Vigna serve as a food source for granivorous birds and small mammals, contributing to in agricultural and natural landscapes; for instance, wild Vigna luteola seeds are included in mixes attracting species like finches. Certain species, such as Vigna marina, demonstrate invasive potential by forming dense stands that outcompete native vegetation and interfere with crop establishment in coastal and tropical regions, altering local composition.

Cultivation and economic importance

Domestication history

The domestication of Vigna species occurred independently in multiple regions, primarily between approximately 4000 and 2000 BCE, transforming wild progenitors into key crops adapted for agriculture. (V. unguiculata), one of the earliest domesticated , originated in , with archaeological evidence from central indicating cultivation by around 2000 BCE. (V. radiata) was domesticated in the , with genetic and archaeobotanical records supporting an origin around 3500–3000 BCE in regions like the Indus Valley and southern . (V. angularis) underwent domestication in , likely in based on recent genomic analyses of over 700 accessions, with initial cultivation estimated between 3000 and 5000 years ago, though earlier consumption evidence exists in dating to 9000 years ago. These events reflect selection for traits such as non-shattering pods and larger seeds, distinguishing cultivars from wild forms across the genus. Following initial , Vigna crops spread through and , often accompanied by genetic bottlenecks that reduced compared to wild progenitors. , for instance, reached by around 3000 BCE and the in the 16th–17th centuries via slave routes, where it integrated into farming systems by the late 1600s. dispersed from to Southeast and along ancient networks like the , while expanded across , , and , with genomic patterns indicating from wild Chinese varieties into Japanese cultivars. These migrations frequently involved founder effects, leading to narrower genetic bases in cultivated populations; for example, cultivars exhibit lower heterozygosity due to and pressures. Archaeobotanical finds and genomic studies provide robust evidence for these processes, highlighting the transition from to domesticated forms. Carbonized from sites in , , and East Asian contexts confirm early human management, while whole-genome sequencing reveals domestication-related quantitative trait loci (QTLs) for seed size and pod dehiscence across . A 2022 review of Vigna underscores severe bottlenecks in cultivars, with domesticated and showing 20–50% reduced diversity relative to wild relatives, underscoring the role of human selection in shaping modern varieties.

Major cultivated species

The genus Vigna includes several that are major crops, contributing significantly to global , particularly in tropical and subtropical regions. These cultivated are valued for their , nitrogen-fixing ability, and nutritional profile, with total annual production across key Vigna crops approximately 19 million metric tons (as of 2024), predominantly in and . Breeding efforts have focused on enhancing yield potentials, typically ranging from 1 to 3 tons per hectare under optimal conditions, and incorporating resistance to diseases such as anthracnose, , and viral pathogens like mungbean yellow mosaic virus. Recent 2025 studies emphasize genomic selection for improved and . Vigna unguiculata (), also known as , is the most widely cultivated Vigna , with global dry grain production reaching approximately 9 million metric tons from over 15 million hectares (as of 2024). accounts for about 95% of this output, led by , , and , where it serves as a staple for smallholder farmers. Varietal improvements have boosted disease resistance to and , alongside yield gains through genomic selection, enabling potentials up to 2-3 tons per hectare in improved lines. Vigna radiata (mung bean) is a key pulse in Asia, with production estimated at 6 million metric tons from 7.3 million hectares (as of 2023-2024), primarily in India, China, and Myanmar. It thrives in short-season environments and has seen breeding advances for resistance to yellow mosaic virus and bruchid pests, supporting yield potentials of 1-2 tons per hectare. Vigna angularis () is predominantly grown in , especially and , with global production around 500,000 metric tons annually (as of 2024), showing steady increases due to demand for its use in traditional foods. programs emphasize pod shattering resistance and tolerance to , achieving potentials of 1.5-2.5 tons per hectare in modern cultivars. Vigna mungo (black gram or urd bean) production is concentrated in , particularly , which accounts for over 70% of the global total of about 2.5 million metric tons from 3 million (as of 2023-2024). Improvements in resistance to and yellow mosaic disease have been pivotal, with high-yielding varieties reaching 1.5-2 tons per . Vigna subterranea (bambara ) is an underutilized crop mainly in , yielding approximately 240,000 metric tons from 400,000 hectares globally (as of 2023), with leading producers including , , and . Its underground pods confer , and recent breeding has targeted resistance to groundnut rosette virus and , with yield potentials up to 1-2 tons per hectare.

Agricultural practices

Vigna crops, including major cultivated species such as cowpea (V. unguiculata), mung bean (V. radiata), and black gram (V. mungo), are typically established through direct seeding in prepared fields. Seeds are sown at depths of 3-5 cm to ensure uniform emergence, with row spacings ranging from 20-50 cm to optimize plant density and facilitate mechanical operations or intercropping. Within rows, plants are spaced 10-30 cm apart, aiming for populations of 200,000-300,000 plants per hectare to balance yield and resource use. Crop rotation with cereals like maize or sorghum is a standard practice, leveraging the legumes' ability to fix 20-100 kg of nitrogen per hectare through symbiotic rhizobia, thereby improving soil fertility for subsequent non-legume crops without synthetic inputs. These crops thrive in well-drained sandy loam or loamy soils with a pH of 5.5-6.5, tolerating low fertility due to their nitrogen-fixing capacity but requiring phosphorus supplementation (20-60 kg P₂O₅/ha) in deficient areas to enhance nodulation and growth. They demand 400-600 mm of annual rainfall, distributed during vegetative and reproductive stages, with cowpea showing particular drought tolerance once established. In rainfed systems, sowing aligns with monsoon onset to capture early moisture, while supplemental irrigation (2-3 applications at 10-15 day intervals) is essential in semi-arid or dry-season cultivation to meet critical needs at flowering and podding, avoiding waterlogging that can reduce yields by promoting root rot. Key challenges in Vigna cultivation include weed competition during early growth, which can suppress yields by 30-50% if unmanaged, and pest pressures from insects like pod borers, aphids, and bruchids. Integrated weed management combines pre-emergence herbicides (e.g., pendimethalin at 0.75-1.0 L/ha) with one or two hand weedings at 20-30 days after sowing, or crop rotation to disrupt weed cycles. Pest control relies on integrated pest management (IPM) strategies, including host plant resistance, timely insecticide applications (e.g., 2-3 sprays at flowering for cowpea), and cultural practices like seed treatment to achieve 50-200% yield gains over untreated fields. Ongoing breeding efforts target climate resilience, developing varieties with improved drought tolerance and reduced canopy density to adapt to erratic rainfall and rising temperatures in tropical regions.

Uses

Culinary and nutritional value

Species of the genus Vigna, particularly V. radiata () and V. unguiculata (), are widely utilized in culinary applications across various cuisines, often prepared as beans, sprouts, or flour. Mung beans are commonly sprouted for use in Asian stir-fries, salads, and soups due to their crisp texture and mild flavor, while whole or split seeds feature in both savory dishes like curries and sweet preparations such as desserts. Cowpeas, known as black-eyed peas in some regions, are frequently cooked into stews, porridges, or fritters in and cuisines, with fresh pods also consumed as . Black gram (V. mungo) seeds are boiled or ground into flour for dal soups and fermented batters in dishes like and dosa. Nutritionally, Vigna species are valued for their high protein content, typically ranging from 20-25% on a dry weight basis, making them a key plant-based protein source for vegetarian diets. They are also rich in (around 11% in cowpeas), which supports digestive health, and provide essential vitamins such as and minerals like iron, with cowpeas containing approximately 1112 mg per 100 g. Low in fat (less than 2%), these offer antioxidants, including in the seeds, which contribute to effects and overall health benefits. Mung beans, for instance, supply significant amounts of B-vitamins, magnesium, and , enhancing their role in addressing deficiencies. Processing methods for Vigna seeds include drying to extend and milling into for or thickening agents, which preserves much of the nutritional profile while improving digestibility. and other techniques, such as , further reduce like phytates, enhancing mineral . efforts have developed biofortified varieties, such as iron- and zinc-enriched mung beans, which can increase levels up to twofold compared to traditional types, supporting nutritional security in staple diets.

Other uses

Species of the genus Vigna have applications beyond culinary uses, particularly in agriculture, medicine, and industry. In agricultural systems, (V. unguiculata) serves as a valuable for , providing high-quality hay and when harvested at appropriate stages. Forage cowpeas can be lightly grazed after flowering to allow regeneration, yielding nutritious feed that supports animal productivity in regions with limited grazing options. Additionally, cowpea residues contribute to as , fixing atmospheric through root nodules and adding 100–200 lb N/ to the , which enhances fertility in nutrient-poor or sandy soils without requiring external nitrogen inputs. This practice produces 2,500–4,500 lb per annually and improves soil structure when incorporated 60–90 days after planting. Medicinal applications of Vigna species draw from traditional practices and emerging pharmacological research. Extracts from mung bean (V. radiata) demonstrate anti-diabetic effects by reducing blood glucose levels and improving insulin sensitivity in diabetic models, attributed to bioactive polyphenols that inhibit starch-hydrolyzing enzymes. Similarly, Bambara groundnut (V. subterranea) tubers have been used in African folk medicine to alleviate inflammatory conditions, such as swollen jaws and , due to their like and that exhibit and activities. In industrial contexts, starches extracted from Vigna species offer versatile applications in food processing and beyond. Cowpea starch, isolated through wet milling, forms firm gels suitable for thickening agents and edible coatings, with properties like high amylose content enabling uses in product formulation for enhanced texture and stability. Furthermore, certain species like snail vine (V. caracalla) are cultivated ornamentally for their rapid growth and fragrant, spirally twisted flowers, reaching 12–30 feet as twining vines in full sun and well-drained soils, adding aesthetic value to gardens in frost-free climates.

Conservation

Status of wild species

The genus Vigna encompasses over 100 wild species, of which approximately 41 have been assessed by the , with many remaining due to limited ecological and distributional data. Among the assessed wild species, six are classified as threatened, primarily those native to , including four Endangered and two Vulnerable taxa. For instance, V. aridicola is Endangered owing to ongoing habitat loss in its restricted arid environments in , while V. owahuensis, a endemic, faces severe declines from agricultural expansion and , leading to its listing as Endangered under U.S. protections. Wild Vigna species confront multiple and environmental threats that exacerbate their vulnerability. through and is a primary driver, fragmenting populations in tropical grasslands and woodlands where many species occur. further compounds these risks, with models projecting that 16–22% of Vigna crop wild relatives could face by 2055 due to shifting suitable s and increased stress, potentially causing up to 50% habitat loss for affected taxa. Additionally, arises from hybridization between wild species and cultivated relatives, such as (V. unguiculata), which introduces that can dilute adaptive traits in wild populations, particularly in agricultural frontiers. Diversity hotspots for wild Vigna species, where risks are concentrated, include —such as , , and the —and the Indo-Malayan area of Asia, notably , which harbors around 34 wild species across diverse ecosystems. These regions support high but are increasingly imperiled, with roughly 16–22% of the genus's wild taxa (out of over 100) broadly at risk from combined pressures, underscoring the need for targeted monitoring.

Conservation efforts

Conservation efforts for Vigna species primarily focus on ex situ and strategies to safeguard genetic diversity, particularly for crop wild relatives (CWR) that support breeding programs. Globally, genebanks hold approximately 130,000 Vigna accessions as of 2022. Ex situ conservation is led by international gene banks under the consortium, with the in maintaining the world's largest and most diverse collection of (V. unguiculata) and other Vigna species, encompassing over 20,000 accessions of cultivated varieties and wild relatives from 88 countries. In 2023, the published an updated Global Strategy for the Conservation and Use of Vigna, which provides a framework for efficient ex situ conservation by prioritizing core collections, standardizing characterization, and enhancing distribution of to breeders while addressing gaps in underrepresented wild taxa. In situ conservation complements these efforts by protecting natural habitats of Vigna CWR in hotspots across and , where over 100 species are distributed, many in protected areas such as those around in and coastal regions of . Initiatives include establishing genetic reserves within existing protected areas in and other African countries to preserve endemic Vigna diversity, alongside on-farm conservation practices that encourage wild relative farming by local communities to maintain adaptive traits under changing climates. Research supports these conservation activities through genomic tools that enhance the characterization and utilization of Vigna . For instance, a 2016 study using morphological and molecular markers identified novel genetic resources among unidentified accessions, revealing untapped for traits like stress tolerance across Vigna subgenera. programs increasingly incorporate wild accessions via to improve cultivated Vigna for resistance and , as demonstrated in where wild relatives have provided genes for yellow mosaic virus resistance, thereby linking with .

Selected species

Subgenus Ceratotropis

The subgenus Ceratotropis (Piper) Verdc., commonly known as the Asian Vigna, comprises 21 species primarily distributed from the Himalayan highlands through South, Southeast, and East Asia. These species are adapted to diverse habitats including coastal sandy soils, limestone hills, forest margins, and open fields. Defining morphological traits include a distinctive keel with a horn-like pocket and a linear to slightly flattened stigma beak, which vary in size across species (e.g., keel pocket 1–7 mm long, beak 0.2–0.8 mm long), aiding in taxonomic differentiation. Seeds are typically small, measuring 2–4.5 mm in length, often rectangular or oblongoid, with surface patterns ranging from shiny and smooth to rough and reticulate, and many wild forms exhibit arillate seeds while cultivated ones are generally non-arillate. Among the cultivated species in this subgenus, Vigna radiata (L.) R. Wilczek, the mung bean, is a staple pulse domesticated around 4,000–6,000 years ago in South Asia, valued for its quick-maturing habit and use in sprouts, soups, and noodles. Vigna angularis (Willd.) Münchh., the adzuki bean, was domesticated in East Asia, particularly in regions like Japan and China, where it is grown for its sweet beans used in desserts and confections. Vigna mungo (L.) Hepper, known as black gram, originated through domestication approximately 4,500 years ago in India and serves as a key ingredient in dal and fermented products like idli. Vigna umbellata (Thunb.) Ohwi & H. Ohashi, the rice bean, was domesticated in Southeast Asia and is often intercropped with rice for its drought tolerance and nutritional content. Wild relatives, such as Vigna trilobata (L.) Verdc., play a crucial role in programs; this , native to southeastern , is closely related to the moth bean (V. aconitifolia) and contributes for traits like pest resistance. These Asian Vigna species were independently domesticated in the and surrounding regions during the period, with archaeological evidence from sites in , , and confirming their ancient cultivation. Economically, they are vital pulses providing high protein and essential nutrients, supporting in ; global mung production alone reached 5.3 million tons in , reflecting their growing international demand.

Subgenus Haydonia

The subgenus Haydonia (Verdc.) Verdc. comprises a small group of primarily wild Vigna , distinguished by morphological traits such as smooth exine and curved beaks, which differentiate it from other with reticulate patterns. in this subgenus typically exhibit a twining growth habit and produce elongated, linear , contributing to their in tropical environments. It encompasses approximately 9 , organized into sections such as Haydonia and Glossostylus, reflecting a monophyletic estimated to have diverged 3–5 million years ago. Most species in subgenus Haydonia are wild and underutilized, with significant concentrated in West and , where they occupy diverse habitats from savannas to forest edges. Notable examples include V. reticulata Hook. f., a twining herb with distinctive reticulate stipules and yellow flowers, distributed across tropical and valued for its in wild relatives. Other key species are V. nigritia Hook. f., featuring small yellow flowers and slender pods, and V. triphylla Benth., known for its trifoliolate leaves and potential as a genetic resource; these contribute to regional and ecological roles in . V. nyangensis Verdc. further exemplifies the subgenus's narrow distributions, often in moist lowland areas. The wild nature of Haydonia species underscores their importance for and , particularly in enhancing traits for cultivated Vigna crops like (V. unguiculata), through of resilient alleles from these African wild relatives. Their supports efforts to address climate challenges in across .

Subgenus Lasiospron

Subgenus Lasiospron comprises six primarily Neotropical species of climbing or scrambling vines, distinguished by their scandent stems up to several meters long, pseudoracemose inflorescences, yellow flowers with left-hand curvature (unlike the right-hand curvature in most Old World Vigna species), deeply emarginate standards, wing petals that embrace the , and resupinate fruits resulting from pedicel torsion. The pods are typically linear, straight or slightly curved, and often pubescent, contributing to the subgenus name derived from terms for "hairy " or pod. These traits reflect a monophyletic that branches early within Vigna sensu stricto, showing close phylogenetic ties to species but with distinct New World floral asymmetry. The species are wild and non-cultivated, occupying diverse habitats across tropical America, with three exhibiting amphi-Atlantic distributions likely due to long-distance dispersal to African coasts. They contribute to understory vegetation in wet tropical forests, aiding in nitrogen fixation and supporting local biodiversity through their climbing habit on shrubs and trees. Key species include:
  • Vigna diffusa (Scott-Elliot) A. Delgado & Verdc.: A widespread vine with pubescent stems and pods, found in disturbed areas and forest edges from Central to South America.
  • Vigna juruana (Harms) Verdc.: Characterized by longer leaves and inflorescences, occurring in Amazonian lowlands with slightly curved, hairy fruits up to 10 cm long.
  • Vigna lasiocarpa (Benth.) Verdc.: Notable for densely woolly pods (lasiocarpa meaning "woolly fruit"), this species climbs in humid forests of Brazil and neighboring regions.
  • Vigna longifolia (Benth.) A. Delgado & Verdc.: Features elongated leaflets and fruits, distributed in Central American woodlands and showing potential for forage in mixed pastures.
  • Vigna schottii (Spreng.) A. Delgado & Verdc.: A robust climber with resupinate, pubescent pods, common in coastal and inland Neotropical habitats.
  • Vigna trichocarpa (Benth.) A. Delgado & Verdc.: Distinguished by hairy fruits and stems, it inhabits riverine forests and has been noted for minor use as livestock fodder in South America.
This is classified within Vigna sensu stricto, alongside Ceratotropis, Haydonia, , and Vigna, based on molecular and morphological evidence.

Subgenus Plectrotropis

The subgenus Plectrotropis within the genus Vigna is distinguished by its exhibiting a prostrate or trailing growth habit, often with stems rooting at the nodes, and inflorescences featuring multiflowered racemes that are typically contracted with extrafloral nectaries. Floral includes purple to white flowers and a slightly curved petal with a pocket-like structure. This subgenus encompasses approximately seven , divided into two sections: Plectrotropis (four ) and Pseudoliebrechtsia (three ), though some classifications expand it to include up to 13 or more based on phylogenetic revisions. Key species in Plectrotropis are predominantly endemics of African s, adapted to arid and seasonally dry tropical environments. Vigna oblongifolia, an to short-lived , grows as a in damp grasslands, riverbanks, and disturbed areas, reaching heights of up to 1 m with climbing tendencies in some varieties, though it maintains a trailing form in open s. It features rose-red corollas and hispid pods, contributing to its resilience in marginal soils across tropical and , including . Vigna parkeri, a mat-forming , displays a distinctly prostrate habit with main stems rooting at nodes and axillary stems that can climb to over 1 m, forming dense covers in grasslands and woodlands from West to . Its pale yellow flowers and small, cylindrical pods support its persistence under heavy grazing and moderate shade. Species in this subgenus play roles in soil conservation through their rooting stolons and mat-forming growth, which stabilize soils in erosion-prone savannas and respond well to and fertilization. Additionally, they serve as valuable wild sources for improvement, particularly for traits like and quality in related cultivated Vigna species such as .

Subgenus Vigna

The Vigna within the Vigna () is distinguished by its exhibiting typical papilionoid flowers, often yellow and pea-like, with variable growth habits that include erect, trailing, climbing, or prostrate forms, encompassing both annuals and perennials. This comprises approximately 38 , organized into six sections (Vigna, Catiang, Comosae, Macrodontae, Reticulatae, and Liebrechtsia), and is predominantly native to , where it shows the highest diversity. Among the key species in subgenus Vigna, V. unguiculata () stands out as a widely cultivated annual herb with trailing or erect stems up to 80 cm tall, producing linear pods containing protein-rich seeds; it is a grown on over 15 million hectares globally, yielding about 8 million metric tons annually as of and serving as a vital source of and in arid regions. V. subterranea (bambara ), another domesticated species, is a prostrate annual with underground pods that develop tuber-like, nutty seeds high in protein (up to 19%) and carbohydrates, originating from and valued for its drought tolerance and soil fertility enhancement in subsistence farming. V. marina (beach bean), a coastal with scrambling stems and salt-tolerant yellow flowers, grows in sandy habitats across tropical shores, its seeds and pods used locally for and . Wild species in the subgenus include V. friesiorum, a perennial herb native to eastern and central tropical , featuring trifoliolate leaves and small yellow flowers, which serves as a potential genetic for breeding traits like pest resistance in related crops. Overall, subgenus Vigna holds the greatest economic significance within the genus due to its domesticated members, particularly , which supports for millions in and beyond through resilient, nitrogen-fixing .