Onion
The onion (Allium cepa) is a biennial bulbous vegetable belonging to the Amaryllidaceae family, widely cultivated for its layered, edible underground bulb and leafy greens, which are used in cooking for their pungent flavor and aroma.[1] Originating from central Asia, where its closest wild relative Allium oschaninii is found, the onion has been domesticated and grown globally since ancient times, with no definitive wild progenitor identified.[2] The plant features fibrous roots, hollow tubular leaves, and a spherical flower head on a leafless stalk in its second year, though it is typically harvested before flowering for bulb production.[3] One of the oldest cultivated vegetables, onions trace their history to the Fertile Crescent around 5,000 years ago, spreading through trade and migration to ancient Egypt, where they held religious significance and were placed in tombs as symbols of eternity.[4] By the 16th century, onions were among the most common vegetables in Europe and the Americas, valued for their versatility in diets and medicinal applications, such as treating colds and infections among early American settlers.[5] Today, onions are produced on every continent except Antarctica, with major exporters including China, India, and the United States, and global production exceeding 100 million metric tons annually as of 2022.[6] Onions are classified into horticultural groups like common bulb onions and aggregatum (including shallots), with varieties categorized by day length requirements: short-day (suited to southern latitudes, milder flavor), intermediate-day, and long-day (for northern areas, better storage).[7] Common types include yellow, white, and red bulb onions, as well as green bunching onions (scallions) and multiplier onions like Egyptian walking onions.[1] Cultivation prefers well-drained, loamy soils with a pH of 6.0–6.8 and full sun, typically from seeds, sets, or transplants in USDA zones 3–9, with harvest in 90–120 days depending on variety.[8] Nutritionally, raw onions consist of about 89% water, 9% carbohydrates (including 4% sugars and 2% dietary fiber), 1.1% protein, and negligible fat, providing essential vitamins like folate (19 μg/100g) and vitamin C (7.4 mg/100g), along with minerals such as potassium (146 mg/100g) and antioxidants including quercetin and organosulfur compounds.[4] These bioactive components contribute to health benefits, such as anti-inflammatory, antimicrobial, and cardiovascular protective effects, making onions a staple in functional foods worldwide.[9] In cuisine, onions are used raw, cooked, pickled, or dried, enhancing flavors in soups, salads, and stir-fries, while their by-products like peels offer potential in nutraceuticals due to high antioxidant content.[3]Taxonomy and Etymology
Taxonomy
The onion (Allium cepa L.) belongs to the genus Allium in the family Amaryllidaceae, order Asparagales, class Liliopsida, phylum Tracheophyta, and kingdom Plantae.[10] This classification places it among monocotyledonous flowering plants, closely aligned with other bulbous species in the Asparagales order.[11] Within Allium cepa, taxonomic distinctions sometimes recognize varieties based on morphological and horticultural traits, including A. cepa var. cepa (common onion group, characterized by single large bulbs) and A. cepa var. aggregatum G. Don (aggregatum group, including multiplier onions and shallots with clustered bulbs).[12] These varietal divisions reflect cultivated forms adapted for different uses, though authorities such as ITIS do not recognize formal varieties like var. aggregatum (treating it as a synonym) due to extensive hybridization and breeding.[13][12] The genus Allium encompasses approximately 900–1,000 species distributed primarily in the Northern Hemisphere, with A. cepa sharing evolutionary ties to other edible alliums such as garlic (Allium sativum L.) and leek (Allium ampeloprasum L.).[14] Phylogenomic analyses indicate that A. cepa diverged within section Cepa of the genus, with domestication likely occurring independently from central Asian wild relatives, highlighting complex speciation patterns driven by geographic isolation and human selection.[15] Recent genetic studies, including genome assemblies and cytogenetic analyses, support the view that cultivated A. cepa exhibits polyploidy (chromosome numbers 2n = 16, 32, or 54) and may have a hybrid origin, potentially involving ancient crosses among wild Allium progenitors that contributed to its bulb-forming traits and lack of a clear wild ancestor.[12] These findings underscore the role of hybridization in the evolutionary history of the species, facilitating its adaptation and widespread cultivation.[16]Etymology
The word "onion" in English derives from the Latin unio, meaning "unity" or "one," which alluded to the single bulb composed of unified layers, resembling a pearl or a string of pearls.[17] This Latin term, a colloquial rustic word for a type of onion, stems from unus ("one"), itself from the Proto-Indo-European root oi-no-, signifying "one" or "unique."[18] The term evolved through Old French oignon (from unionem, the accusative form of unio), entering Middle English as oynoun or unyun around the 12th century before standardizing as "onion" by the 14th century.[17] In other Romance languages, similar paths occurred, such as Spanish cebolla (influenced by Latin caepa for onion) and Italian cipolla, diverging from the unio lineage but sharing broader Indo-European vegetable nomenclature roots.[17] Across cultures, onion nomenclature reflects diverse linguistic traditions predating the Latin influence. In ancient Egypt, the onion was known as hedju (or ḥḏw in hieroglyphic transcription), a term cognate with hedj meaning "to destroy," symbolizing its ritual use in warding off evil during festivals like those of Osiris.[19] In Sanskrit, the primary term is palāṇḍu (पलाण्डु), denoting the bulbous plant and appearing in ancient texts such as Ayurvedic literature for its layered structure, with variants like ūlī (ऊली) used regionally for similar alliums.[20] These names highlight early symbolic associations with eternity and protection, tied to the onion's concentric form. Trade routes significantly shaped regional onion terminology, facilitating linguistic borrowing across Eurasia. The Persian word piyāz (پیاز), possibly from an unattested Middle Persian pyʾc with Sogdian influences like piyāk, spread via Silk Road commerce and Persian cultural expansion from the 9th century onward, influencing Turkic languages (e.g., Turkish piyaz for an onion-based dish), Mongolian, Manchu, and even Dungan (a Sinitic language) as pii͡azɨ.[21] This dissemination paralleled the crop's cultivation, linking Central Asian origins to widespread adoption in South and East Asia, where local adaptations like Hindi pyaaz emerged from the same Persian root.[21]Botany and Description
Botanical Features
The onion plant (Allium cepa) is a biennial herb characterized by its underground bulb, which serves as the primary storage organ. The bulb is globose to ovoid, typically measuring 3–10 cm in diameter, and consists of a short, flattened stem plate at the base from which roots emerge. It is formed by thickened, concentric leaf bases that develop into fleshy, layered scales; the inner scales are juicy and nutrient-rich, storing carbohydrates and water, while the outer 3–4 scales dry into protective, papery tunics that encase the bulb. The neck region, located at the top of the bulb, is where the leaves and flowering stem originate, providing a transitional zone between the storage organ and the aerial parts.[22][4] The leaves are basal, emerging directly from the bulb's neck in a rosette formation, with 4–10 per plant. They are linear, hollow, and cylindrical—often D-shaped in cross-section—with parallel venation and lengths ranging from 10–50 cm and widths of 4–20 mm. These leaves are bluish-green, waxy, and function photosynthetically, contributing to the plant's overall height, which typically reaches up to 1 meter in the vegetative stage. The root system is fibrous and adventitious, arising in rings from the basal plate of the bulb; these shallow roots, numbering in the dozens, anchor the plant and absorb water and nutrients from the upper soil layers.[22][23][4] In the flowering phase of its biennial cycle, the onion produces a single, leafless scape (flower stalk) that elongates to support an umbel inflorescence at its apex. This spherical umbel contains 200–600 small, bisexual flowers, each 3–7 mm long, arranged in a compact cluster. The flowers are actinomorphic with six similar tepals in two whorls—typically white or pink with greenish veins and valvate aestivation—surrounding a superior, trilocular ovary. Pollination leads to seed production, with the ovary developing into a loculicidal capsule containing 2–6 black, endospermous seeds per fruit.[22][23]Growth Cycle
The growth cycle of the onion (Allium cepa) begins with seed germination, which occurs optimally at soil temperatures of 20–25°C (68–77°F), though it can happen at temperatures as low as 2°C with much slower rates.[24] At optimal temperatures, seeds usually emerge in 7 to 10 days, provided the soil remains consistently moist to support radicle development and initial root establishment.[25] Following germination, the seedling develops into a small plant with true leaves, marking the start of vegetative growth where the focus is on expanding foliage and root systems to build photosynthetic capacity.[26] Vegetative growth continues until the bulbing phase, which is primarily triggered by photoperiodism—the plant's response to increasing day length. Short-day varieties initiate bulbing at 10 to 11 hours of daylight, while long-day varieties require more than 12 hours, often reaching a critical threshold around 13.75 hours to promote hormonal changes that redirect resources from leaf growth to underground bulb formation.[27] This phase typically follows the production of six to eight leaves, after which the plant swells the bulb base with stored carbohydrates and nutrients.[28] Bulb maturation occurs over an active growth period of approximately 2 to 3 months from planting, culminating in 90 to 120 days total for most cultivars, at which point the tops begin to wilt as the plant senesces.[29] Mature bulbs then enter a dormancy phase, a physiological rest period lasting from several weeks to months depending on variety and environmental conditions, during which metabolic activity slows to preserve viability for storage or replanting.[24] In biennial fashion, non-bolted bulbs remain dormant until the second year, when vernalization (a period of cold exposure) can induce flowering stems for seed production.[30] Seed production arises in bolted plants, where premature flowering—often due to stress or overwintering—produces umbels of flowers that develop into seeds after pollination, completing the reproductive cycle.[31] Certain varieties, such as multiplier onions (Allium cepa var. proliferum) and Egyptian walking onions, exhibit perennial tendencies by forming bulbils or offsets instead of or alongside seeds, allowing vegetative propagation and multi-year persistence without full senescence.[32]History
Origins and Domestication
The onion (Allium cepa) likely originated in Central Asia, with its closest wild relative being Allium vavilovii, a species native to the mountainous regions of present-day Iran, Afghanistan, and Pakistan.[33] This area, part of the broader Near East and Southwest Asian highlands, provided the environmental conditions for the evolution of wild Allium species, which exhibit bulbous growth and pungent compounds adapted to arid and semi-arid climates. Genetic studies, including phylogenetic analyses of chloroplast and nuclear DNA, confirm A. vavilovii as the closest relative to the domesticated onion, supporting a single domestication event in this region rather than multiple independent origins, though the exact progenitor remains debated, with species like A. oschanini also proposed.[33] Domestication of the onion began around 5000–3000 BCE, as early human societies in Central Asia transitioned from foraging wild Allium species to cultivating them for reliable food sources. Archaeological and genetic evidence suggests onions were among the earliest plants domesticated in the region around 5000–3000 BCE.[34] Further traces have been found in Egyptian contexts from 3500 BCE, where onions were incorporated into diets and rituals, suggesting early integration into settled agriculture.[34] Genetic evidence from modern landraces and ancient DNA reveals human selection pressures that favored larger, more uniform bulbs over the smaller, clustered forms of wild progenitors, enhancing storability and yield for early farmers.[33] From its Central Asian hearth, the onion spread rapidly through human migration and trade networks, reaching Mesopotamia by around 2500 BCE, where cuneiform records and botanical remains document its use in Sumerian cuisine and medicine.[35] By 2000 BCE, cultivation had likely extended eastward to the Indus Valley Civilization through trade and migration, alongside other staple crops like wheat and barley, indicating adaptation to diverse agroecological zones. This early dissemination underscores the onion's role as a versatile, transportable crop that supported expanding ancient societies.Historical Cultivation and Trade
Onions have been cultivated since ancient times, with evidence of their use in Egypt dating back to approximately 3500 BCE, where they were grown as a staple food crop.[34] In the Old Kingdom period around 2780 BCE, onions were supplied as part of the rations to workers building the pyramids at Giza, alongside garlic and radishes, to provide sustenance and believed strength during labor-intensive projects.[36] The Greek historian Herodotus, writing in the 5th century BCE, recorded that onions formed a key component of the pyramid builders' diet, highlighting their role in sustaining large-scale construction efforts.[37] By the classical period, onions gained prominence in Greek and Roman medicine. Hippocrates (c. 460–377 BCE), often regarded as the father of Western medicine, incorporated onions into his therapeutic practices as a standard medicinal herb, using them for various ailments including wound treatment and digestive issues.[38] In Rome, the physician Dioscorides (c. 40–90 CE) detailed onions' applications in his work De Materia Medica, prescribing them pounded with honey and rue for dog bites, with poultry grease for ear problems, and as a topical rub for baldness, while noting potential side effects like headaches from overuse.[38] Pliny the Elder (23–79 CE) further expanded on these uses in Natural History, listing onions for improving eyesight, inducing sleep, and healing mouth sores when chewed with bread.[38] During the medieval period in Europe, onions became a vital crop cultivated extensively in monastic gardens, where they served both dietary and medicinal purposes amid land reclamation efforts by religious communities.[39] Their value extended to trade, as expanding routes from the Middle East and Asia—facilitating the broader exchange of goods along paths like the Silk Road—introduced and disseminated onion varieties across the continent, making them a common staple by the 12th century.[40] So essential were onions that they functioned as a form of currency, with peasants paying rent or taxes in bulbs, underscoring their economic significance in feudal societies.[39] The Columbian Exchange, initiated after Christopher Columbus's voyages in 1492, marked the introduction of onions from Europe to the Americas, where Spanish and other settlers brought seeds and bulbs starting in the early 16th century.[41] This transfer adapted onions to New World climates, leading to local cultivation and the development of varieties suited to diverse regions, such as those in North and South America, enhancing agricultural diversity.[42] In the 19th and 20th centuries, selective breeding advanced onion cultivation in Europe and the United States, focusing on storage qualities to meet growing commercial demands. In the U.S., the Yellow Globe Danvers variety, developed in the late 19th century from Dutch imports, became foundational for Eastern storage onions, selected for longer shelf life and disease resistance.[43] By the mid-20th century, public breeding programs in both regions produced inbred lines through self-pollination, yielding uniform, high-yield storage types like those derived from Walla Walla sweets crossed with dry-matter varieties to balance flavor and durability.[44] These efforts, led by agricultural stations, supported expanded trade by enabling year-round availability and export.[7]Cultivation and Production
Growing Conditions and Methods
Onions thrive in well-drained, fertile soils such as sandy loams or silt loams with a pH range of 6.0 to 6.8, which supports optimal nutrient availability and root development.[5][29][45] These soils should be loose and rich in organic matter to prevent waterlogging, as onions are sensitive to excess moisture that can lead to rot.[5][29] For climate, onions require full sun exposure and moderate temperatures, with foliage growth favored by cool conditions of 15–25°C (59–77°F) to promote leafy development without stress.[46] Bulbing initiates under warmer temperatures around 24–30°C (75–86°F), though extremes above 30°C can inhibit bulb formation and quality.[46] Day length also influences bulbing, varying by cultivar type, but temperature management remains key during the growth stages.[47] Planting can be achieved through direct seeding, sets (small bulbs), or transplants, each suited to different timelines and regions. Seeds are sown 0.6–1.3 cm (¼–½ inch) deep in rows 20–40 cm (8–16 inches) apart, while sets and transplants are placed 2.5–5 cm (1–2 inches) deep and spaced 5–10 cm (2–4 inches) apart within rows 30–60 cm (12–24 inches) apart to allow for bulb expansion.[48][29][49] Thinning may be necessary for seeded or set-planted onions to achieve final spacing of 10–15 cm (4–6 inches) between plants, optimizing airflow and growth.[29][50] Irrigation is critical to maintain even soil moisture, with drip systems preferred for efficient water delivery directly to roots, reducing evaporation and disease risk while applying 150–200 mm (6–8 inches) of water over the season depending on climate.[47][5][51] Fertilization focuses on balanced nutrients, particularly nitrogen at rates of 100–150 kg/ha (90–130 lb/acre), applied in splits to match uptake during vegetative and bulbing phases, often via fertigation through drip lines for precise control.[45][52] Phosphorus and potassium are incorporated pre-planting based on soil tests to support root establishment and overall vigor.[53]Pests, Diseases, and Management
Onion crops are susceptible to several major pests that can significantly impact yield and quality. Onion thrips (Thrips tabaci) are among the most damaging, with a life cycle consisting of eggs inserted into leaf tissues, followed by two larval stages that feed on plant sap, and pupation in the soil; under warm conditions, they complete 7-10 generations per year.[54] Damage appears as silvery-white scarring, discoloration, and distortion of leaves, particularly during the early bulbing stage, leading to reduced photosynthesis and potential transmission of viruses like iris yellow spot virus.[55] Onion maggots (Delia antiqua) have a life cycle where females lay eggs at the plant base in spring, larvae burrow into seedlings or bulbs for 2-3 weeks before pupating in the soil, with 2-3 generations annually and overwintering as pupae.[54] Symptoms include stunted or wilting seedlings snapped at the soil line, deformed bulbs, and increased susceptibility to secondary rots.[55] Root-knot nematodes (Meloidogyne spp.) complete their life cycle in 3-4 weeks under optimal soil conditions, with juveniles hatching from eggs, penetrating roots, and inducing galls as females mature and lay new eggs.[56] They cause root galls, stunting, yellowing foliage, and uneven growth, potentially reducing yields by up to 70% in severe infestations.[55] Common fungal diseases pose additional threats to onion production. Downy mildew, caused by the oomycete pathogen Peronospora destructor, thrives in cool, humid conditions and spreads via airborne spores; it infects leaves, leading to pale green or yellow spots that develop into angular lesions with grayish-purple fuzzy sporulation on the undersides.[54] Affected leaves yellow, wither, and collapse, resulting in dwarfed plants and poor bulb development.[55] Fusarium basal rot, primarily caused by Fusarium oxysporum f. sp. cepae, is a soilborne fungus that persists as durable chlamydospores and infects roots, often remaining latent until maturity; it spreads through contaminated soil, tools, or irrigation water.[57] Early symptoms include curving and yellowing of leaf tips progressing downward, wilting, and stunted growth, followed by brown, watery rot at the bulb base and plate, which worsens in storage.[54] Effective management of these pests and diseases relies on integrated pest management (IPM) approaches combining cultural, biological, and chemical strategies. Cultural practices include crop rotation with non-host crops for 3-4 years to disrupt pathogen and nematode life cycles, timely planting to avoid peak pest activity, and field sanitation to remove crop debris and volunteer onions that harbor pests.[54] Biological controls involve conserving natural enemies such as predatory mites, pirate bugs, and lacewings for thrips, as well as introducing entomopathogenic nematodes for maggot control.[55] Chemical options include targeted insecticides like spinosad for thrips and maggots applied at economic thresholds, and fungicides such as mancozeb or chlorothalonil for downy mildew, with soil fumigants like metam sodium for nematodes and Fusarium; applications should follow scouting and resistance management guidelines to minimize environmental impact.[57] IPM protocols emphasize monitoring pest populations through regular scouting, using action thresholds (e.g., 5-10 thrips per leaf), and areawide coordination to reduce migration.[55] Recent advances in onion management include breeding efforts for varieties with partial resistance to Fusarium basal rot and downy mildew. Progress in IPM has incorporated precision tools like remote sensing for early disease detection and biofumigant cover crops to suppress soilborne pathogens, improving sustainability in commercial production.[57][55]Global Production Statistics
In 2023, global production of bulb onions, including shallots, totaled approximately 111 million metric tons, marking a steady increase from previous years driven by expanded cultivation in major producing regions (as of the latest FAO data available in 2025).[58] This output underscores onions' status as one of the most widely grown vegetables worldwide, with production concentrated in Asia, which accounts for over 70% of the total.[59] India and China dominate as the top producers, together contributing more than half of the global supply; India harvested about 26.6 million metric tons, while China produced 24.2 million metric tons in the same year.[59] Other significant contributors include Egypt at 3.8 million metric tons, the United States at 3.3 million metric tons, and Turkey at 2.6 million metric tons.[60] Yields vary widely by region, typically ranging from 20 to 40 tons per hectare, influenced by factors such as soil quality, irrigation systems, and mechanization levels.[61] The global average yield stands at around 19.7 tons per hectare, with higher efficiencies in mechanized operations in North America and Europe contrasting lower outputs in labor-intensive Asian farms.[61] For instance, advanced farming in the United States achieves yields closer to 40 tons per hectare through precision agriculture, while traditional methods in parts of India and China often fall toward the lower end of the spectrum due to variable climate conditions.[62] International trade in onions reached a value of approximately $8.8 billion in 2023, with key exporting nations including the Netherlands, China, India, Mexico, and the United States facilitating global distribution.[63] The Netherlands leads as a major trader, exporting over 1 million metric tons annually through efficient logistics and greenhouse production, while Egypt specializes in high-volume shipments to Europe and the Middle East.[64] Import dynamics are shaped by demand in deficit regions like Europe and North America, where seasonal shortages drive reliance on these suppliers. Recent trends from 2020 onward highlight resilience in production amid climate challenges, with steady increases observed despite increased variability from droughts and temperature fluctuations.[65] In response, sustainable farming practices have gained traction, including drought-resistant varieties and optimized water use, helping mitigate yield losses in vulnerable areas like South Asia.[66] These adaptations, supported by innovations in organic amendments and precision irrigation, aim to sustain growth rates while addressing environmental pressures.[67]Harvesting and Storage
Onions are typically harvested when 50 to 70 percent of the tops have naturally fallen over, indicating maturity and minimizing damage to the bulbs.[68][5] This timing ensures optimal size and flavor while reducing the risk of rot from prolonged field exposure.[69] For small-scale or home production, manual harvesting involves undercutting the soil with a spading fork or similar tool to lift the bulbs gently, followed by pulling them by hand.[68] In commercial operations, mechanical harvesters are commonly used to increase efficiency, though they require careful adjustment to avoid bruising the delicate skins, particularly for short-day varieties.[69][70] Following harvest, onions undergo a curing process to dry the necks and outer skins, enhancing storability and preventing moisture-related decay.[71] Bulbs are placed in a warm, dry, well-ventilated area at temperatures of 25 to 30°C (77 to 86°F) for 2 to 4 weeks, allowing the tops to dry completely while the necks seal.[68][71] This field or forced-air curing method is critical for long-day onions, as it promotes uniform drying and reduces weight loss during subsequent storage.[72] For long-term storage, cured onions should be kept at 0 to 5°C (32 to 41°F) with 65 to 70 percent relative humidity, conditions that can maintain quality for up to 8 months depending on variety and initial health.[73][74] Proper ventilation is essential to prevent condensation and fungal growth.[75] Key quality factors include sprout inhibition, achieved primarily through low temperatures that slow metabolic activity, and managing ethylene sensitivity, as onions are moderately sensitive to exogenous ethylene from nearby produce, which can accelerate sprouting or decay if not controlled.[71][76] Storing onions separately from ethylene-producing fruits like apples helps preserve firmness and extends shelf life.[71]Varieties and Breeding
Common Onion Group
The common onion group, classified under Allium cepa var. cepa, encompasses the primary bulb-forming onions cultivated worldwide for their versatile uses in cooking and storage. These onions typically produce a single large bulb per plant, distinguishing them from clustered varieties in other groups. Bulb varieties in this group vary by skin color, including yellow (the most common, with golden-brown outer layers), red (featuring purple-red skins and flesh), and white (with silvery-white outer skins). Sizes range from small pearl onions, about 1-2 cm in diameter, suitable for pickling, to large storage onions exceeding 10 cm, such as the sweet Vidalia onion, which is prized for its mild flavor and elongated shape. These color and size differences arise from selective cultivation adapted to regional preferences and markets. Flavor profiles within the common onion group span pungent to mild, primarily determined by the concentration of sulfur-containing compounds like allyl sulfides, which are higher in varieties grown in sulfur-rich soils and lower in those from low-sulfur environments. Pungent types, such as traditional yellow storage onions, release sharp volatiles when cut, contributing to their intense taste, while mild varieties like Walla Walla sweets offer a subtler, sweeter profile due to reduced pyruvic acid levels. Cultivation of common onions is heavily influenced by day-length requirements, which dictate bulb formation based on photoperiod sensitivity. Short-day varieties, requiring 10-12 hours of daylight, are ideal for southern latitudes and produce bulbs earlier in the season, such as the Texas Grano. Long-day types, needing 14-16 hours, suit northern regions and yield larger bulbs later, exemplified by the Copra onion. Intermediate or day-neutral varieties, like Candy, adapt to a broader range of latitudes with 12-14 hours, enabling more flexible growing zones. Prominent examples in this group include Spanish onions, known for their large size and mild flavor, often used in salads and grilling; Bermuda onions, which are short-day types with sweet, juicy bulbs popular in subtropical climates. These varieties dominate global production, accounting for the majority of commercial onion crops due to their adaptability and yield potential.Aggregatum Group
The Aggregatum Group encompasses shallot-like onions within Allium cepa var. aggregatum, distinguished by their tendency to form clustered bulbs rather than solitary large ones, a trait that aligns them taxonomically with multiplier varieties in the broader onion complex.[7] These plants typically produce aggregates of 2–15 smaller bulbs per cluster, exhibiting shapes from pear-like to broad oval, depending on the subtype.[77] This clustered growth supports their use in specialty culinary applications where compact, uniform bulbs are preferred over the larger yields of common onions. Regional adaptations in the Aggregatum Group include Asian subtypes, such as those cultivated in tropical and subtropical regions like India, which tolerate hot and humid conditions, and European types originating from areas like France and Croatia, which demonstrate hardiness in temperate climates.[77][78] These varieties often possess a milder flavor profile compared to the pungent common onion group, attributed to lower levels of sulfur compounds, making them suitable for raw or delicate preparations.[79] Propagation in the Aggregatum Group occurs primarily through vegetative means, with growers planting individual cloves or bulblets from the clusters to produce new plants, as seed production is irregular or absent in many lines.[78] Notable examples include French shallots (Allium cepa var. aggregatum 'French Red'), which form tight clusters of elongated, copper-skinned bulbs with a subtle garlicky nuance; potato onions, featuring broader, yellow- or red-skinned bulbs in larger clusters of up to 12 per plant; and multiplier onions, which reliably divide into nests of small, nesting bulbs ideal for perennial cultivation.[77][78]Hybrids and Genetic Improvements
Hybrid onion varieties, particularly F1 hybrids, have been developed to exploit hybrid vigor, resulting in improved uniformity, higher yields, and greater stability compared to open-pollinated or inbred lines. This heterosis is achieved through controlled crosses using cytoplasmic-genetic male sterility (CGMS) systems, where male-sterile female parents are pollinated by fertile male lines to produce uniform F1 seeds without self-pollination.[80] The discovery of stable male sterility in onions dates back to the early 20th century, but commercial exploitation began in the 1960s with the identification of effective sterile cytoplasm sources, enabling the rapid adoption of hybrids that increased bulb yields by 20-50% in field trials.[81] For instance, early hybrids like those tested in the 1960s demonstrated yield gains ranging from 71% to 158% over parental lines, establishing CGMS as the foundation for modern onion seed production. Genetic engineering techniques, particularly CRISPR/Cas9 genome editing, have emerged since the mid-2010s to enhance disease resistance in onions, addressing limitations of traditional breeding. Post-2015 developments include the establishment of efficient CRISPR protocols for Allium cepa, such as biolistic delivery of Cas9 ribonucleoproteins, which have successfully targeted genes like phytoene desaturase (PDS) to validate editing efficiency.[82] A notable application is the editing of the Allium cepa Downy Mildew Resistant 6 (AcDMR6) gene, producing mutant plants with enhanced tolerance to downy mildew, a major foliar disease, through loss-of-function mutations confirmed in regenerated plants.[83] While direct CRISPR edits for Fusarium basal rot resistance remain in early research stages, conventional breeding has identified quantitative trait loci (QTL) for partial resistance, with survival rates up to 78% in screened accessions, paving the way for integrated genetic approaches.[84] Breeding programs have focused on selecting for key agronomic traits to meet market demands, including extended storage life, reduced pungency, and colored bulb flesh. Longer storage life is achieved through selections for higher dry matter content and firmer bulbs, with hybrids maintaining quality for 6-8 months under controlled conditions, reducing post-harvest losses that can exceed 30% in susceptible varieties.[85] Reduced pungency, measured by pyruvic acid content below 5.5 μmol/g fresh weight, has been incorporated into long-day hybrids via marker-assisted selection, preserving low tear-inducing levels even after extended storage.[86] For colored flesh, breeders have developed lines with anthocyanin pigmentation extending to the bulb center, such as deep red varieties, enhancing visual appeal and nutritional profiles while maintaining yield.[87] In the 2020s, innovations emphasize GMO-free hybrids tailored for climate resilience, combining conventional breeding with genomic tools to address environmental stresses without transgenic modifications. Partnerships like Syngenta and Emerald Seed Company have produced non-GMO hybrids resistant to multiple diseases, including pink root rot and downy mildew, while exhibiting improved performance under temperature fluctuations, with yield stability increased by 15-25% in stress trials.[88] These efforts include developing varieties adapted to drought and heat, such as those tested for Fusarium basal rot tolerance alongside abiotic stress resilience, supporting sustainable production for global growers.[89]Culinary and Other Uses
Culinary Applications
Onions are a fundamental ingredient in cuisines worldwide, prized for their versatility in adding depth, sweetness, and pungency to dishes through various cooking methods.[90] They serve as a foundational aromatic, often forming the base of sauces, stews, and stocks by releasing sulfur compounds and sugars when heated, which mellow their sharpness and enhance umami flavors.[91] Common preparation techniques include consuming onions raw in salads for their crisp texture and sharp bite, sautéing them briefly to soften and aromatize other ingredients, caramelizing them slowly over low heat to develop rich sweetness, and pickling them in vinegar for tangy condiments.[92] These methods transform the vegetable's natural compounds, with caramelization involving the Maillard reaction to create complex, nutty notes suitable for toppings or fillings.[93] In many recipes, onions contribute essential flavor as the primary component of mirepoix, a French mixture of diced onions, carrots, and celery sautéed to form the base for soups, stocks, and braises, providing a balanced aromatic foundation.[91] This technique exemplifies onions' role in building layered tastes, as seen in classic French onion soup, where slowly caramelized onions are simmered in beef broth and topped with gruyère cheese for a hearty, savory dish originating in 18th-century Paris.[94] Onions feature prominently in global cuisines, such as Indian curries where finely chopped onions are fried until golden to form a thick, flavorful gravy that binds spices and proteins.[95] In Latin American cooking, they are essential to salsas, diced raw or lightly pickled with tomatoes, chiles, and lime for fresh, zesty accompaniments to grilled meats and tacos, as in traditional Mexican recipes.[96] Different onion varieties suit specific culinary applications based on their sulfur content and moisture levels; sweet varieties like Vidalia, with lower pungency, excel in grilling or raw uses to highlight mild flavors without overpowering dishes.[97] In contrast, pungent yellow onions are ideal for frying or long-cooked preparations, where their robust flavor intensifies and sweetens during cooking.[98]Non-Culinary Applications
Onion skins serve as a source of natural dyes, particularly red pigments derived from anthocyanins such as pelargonidin and flavonoids like quercetin, which have been extracted for textile and fabric coloring applications.[99] These pigments exhibit good adsorption properties on cellulose materials when mordants like chitosan are used, enabling their application in eco-friendly dyeing processes.[100] In traditional medicine, onions have been employed as remedies for respiratory ailments, with raw or cooked forms used to alleviate symptoms of colds, coughs, and bronchitis through mixtures like onion juice combined with honey.[101] For wound care, heated onions applied as poultices have historically promoted healing in regions such as the Balkans and Peninsula, leveraging their purported antiseptic qualities.[102] Cull onions and processing waste are utilized as animal feed for livestock, providing a digestible energy source due to their high sugar content and low fiber, with studies showing comparable weight gains in sheep to those fed whole sorghum when incorporated into balanced rations.[103] In dairy cattle, onion extracts supplemented in diets have demonstrated potential to inhibit methane production without adversely affecting milk sensory properties.[104] Onion extracts find application in cosmetics for anti-aging purposes, with formulations containing fermented onion rich in quercetin and isoquercetin inhibiting tyrosinase and collagenase-1 enzymes to reduce photoaging effects.[105] Proprietary gels incorporating onion extract have improved scar appearance and reduced neoangiogenesis after topical application, supporting their use in skin care products.[106] Onion processing waste, including peels and bulbs, is processed into biofuels through anaerobic digestion and enzymatic co-fermentation, yielding bioethanol and methane gas as sustainable energy sources from otherwise discarded biomass.[107] Industrial facilities have converted up to 300,000 pounds of daily onion waste into methane to power fuel cells, demonstrating viable biorefinery approaches for value-added energy production.[108] Historically, onions played a role in ancient Egyptian mummification, where they were placed in body cavities such as the pelvis, thorax, and eye sockets to symbolize eternity and aid preservation, as evidenced in examinations of pharaonic remains like those of Ramses IV.[109] Archaeological findings confirm onions among embalming materials, alongside resins and natron, highlighting their cultural significance in funerary practices dating back to around 3500 BCE.[110]Nutritional Composition
Macronutrients and Vitamins
Onions are a low-calorie vegetable, providing approximately 40 kcal per 100 grams of raw weight, with the majority of energy derived from carbohydrates.[111] This caloric content positions onions as a nutrient-dense food option suitable for calorie-conscious diets. The macronutrient composition is dominated by carbohydrates at about 9.3 grams per 100 grams, primarily in the form of simple sugars and dietary fiber, while protein contributes roughly 1.1 grams and total fat is negligible at 0.1 grams.[111] Dietary fiber, at 1.7 grams per 100 grams, supports digestive health through its soluble and insoluble components.[111]| Nutrient | Amount per 100g (raw) | % Daily Value* |
|---|---|---|
| Calories | 40 kcal | 2% |
| Carbohydrates | 9.3 g | 3% |
| Protein | 1.1 g | 2% |
| Total Fat | 0.1 g | 0% |
| Dietary Fiber | 1.7 g | 6% |
| Vitamin C | 7.4 mg | 8% |
| Vitamin B6 | 0.12 mg | 7% |
| Folate | 19 µg | 5% |
| Potassium | 146 mg | 3% |
| Sodium | 4 mg | 0% |