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Humulus

Humulus is a small of dioecious, herbaceous climbing in the family , comprising three recognized native to the temperate regions of the . These vines (with one annual ) feature twining stems that can reach heights of up to 8 meters, opposite or alternate palmately lobed leaves, and separate male and female , with female inflorescences forming distinctive cone-like strobili rich in glandular trichomes. The genus originated in and has been utilized by humans for millennia, with pollen evidence dating back to 3000 B.C. in . The most prominent species, L. (common hop), is widely cultivated globally for its strobili, which provide essential bitterness, flavor, and preservation properties in production due to compounds like α-acids and essential oils. Siebold & Zucc. (Japanese hop), an annual species synonymous with H. scandens, is native to and often grown as an ornamental but has become invasive in parts of . Humulus yunnanensis Hu, endemic to Province in , shares similarities with H. lupulus and shows potential for brewing and pharmaceutical applications owing to its bioactive compounds. Beyond brewing, species of Humulus are valued for their phytochemicals, including prenylflavonoids like and , which exhibit , , , and potential anticancer properties, supporting traditional and modern medicinal uses such as for sleep disorders and menopausal symptoms. Taxonomically, the genus is classified under the order , with Humulus closely related to the genus Cannabis within .

Description

Morphology

Humulus species are dioecious, herbaceous bines (specialized climbing vines lacking tendrils) characterized by their clockwise-twining growth habit. The stems are robust, often four-angled in cross-section, and can reach lengths of up to 8 meters in a single , supported by numerous hooked hairs that facilitate adhesion to vertical structures. These stems exhibit a rough, pubescent , particularly at the nodes, with downward-pointing hairs aiding in climbing. The is extensive and rhizomatous, enabling vegetative propagation and perennial regrowth from underground stems, though H. japonicus is typically . Leaves are arranged oppositely (decussate) on the lower portions of the stems and often alternately on the upper portions, and are palmately lobed, typically with a cordate base and serrated margins. In H. lupulus, leaves are usually 3-5 lobed, 7-12 in and width, with a glabrous upper surface and soft pubescence on the lower axils. Humulus japonicus features larger leaves, often 5-7 lobed and more deeply incised, while H. yunnanensis has 3-5 lobed or occasionally leaves, 5-14 long, with rigid spinulose hairs on the abaxial s. The inflorescences reflect the dioecious nature of the genus, with distinct male and female structures. Male plants produce panicles of small, yellowish-green flowers, each with five sepals and five stamens, clustered in elongated panicles up to several centimeters long. Female inflorescences form cone-like strobiles (commonly called hops in H. lupulus), consisting of overlapping, modified leaves (bracts) that enclose the developing ovaries and seeds; these strobiles are 1-5 cm long in H. lupulus, smaller and less glandular in H. japonicus and H. yunnanensis.

Reproduction and Life Cycle

Humulus species are dioecious, with separate plants required for and seed production. Sex determination follows an system, where females possess chromosomes and males carry chromosomes, enabling early identification through molecular markers in breeding programs. Male plants produce panicle-like inflorescences that release wind-dispersed , while female plants develop cone-like strobiles containing the ovaries. Flowering typically occurs in late summer as a short-day response, triggered when photoperiods fall below 15–16 hours, initiating the transition from vegetative to reproductive growth. flowers shed over several weeks, facilitating cross-pollination, after which strobiles mature over approximately 6-8 weeks. Species of Humulus (except H. japonicus) have a herbaceous , with entering in autumn as temperatures cool and days shorten, surviving winter via underground rhizomes. H. yunnanensis is , similar to H. lupulus. New shoots emerge from these rhizomes in , followed by rapid vegetative growth during summer, reaching rates of up to 30 cm per day under optimal conditions and climbing 7–10 meters in a single season. By late autumn, growth senesces, with aboveground parts dying back, completing cycle while the persists for 25–30 years. In natural populations, sexual reproduction produces small, hard achenes (nutlets) enclosed in female strobiles, which are primarily wind-dispersed but exhibit low natural viability due to dormancy. Germination rates remain below 25% without cold stratification for 15–90 days at 4°C, though treatments like gibberellic acid can enhance success to over 50%. However, vegetative propagation via rhizome division or cuttings dominates in cultivation to preserve female clones, avoiding seed set that would reduce cone quality. This approach ensures uniform, seedless plants, as male presence is minimized to prevent pollination.

Taxonomy and Phylogeny

Accepted Species

The genus Humulus comprises seven accepted species according to the database (POWO, ). These are Humulus americanus Nutt., Humulus cordifolius Miq., L., Humulus neomexicanus (A. Nelson & Cockerell) Rydb., Humulus pubescens E.E. Sherff, Humulus scandens (Lour.) Merr. (syn. Siebold & Zucc.), and Humulus yunnanensis Hu. Humulus lupulus, the common hop, is a dioecious climber native to temperate regions of Europe to and North . It is distinguished by its palmately lobed leaves typically with 3–5 lobes, rough stems with downward-pointing hairs, and inflorescences forming papery, glandular cones rich in bitter resins (lupulin) that impart and properties. Historical taxonomic debates have resolved several Eurasian variants as or varieties under this . North American populations previously included under H. lupulus are now recognized as separate , such as H. americanus Nutt. (native to southern to northern and eastern central U.S.A.) and H. neomexicanus (native to western and central to ). Humulus americanus and H. neomexicanus share morphological similarities with H. lupulus but differ in subtle traits like leaf pubescence and cone structure. Humulus cordifolius Miq. is native to to northern and central , while Humulus pubescens E.E. Sherff is known from limited Asian localities. Humulus scandens (syn. ), the Japanese hop, is an annual dioecious climber native to (Russian Far East to northern Vietnam and temperate eastern Asia, including , , and parts of ). It differs from H. lupulus in its larger leaves with 5–9 shallow lobes, less pubescent stems, and non-glandular, non-bitter inflorescences lacking significant resin production; it often exhibits faster growth and coarser texture overall. Humulus yunnanensis, a perennial dioecious climber restricted to Province in , is characterized by its smaller stature compared to H. lupulus, with 3–5-lobed leaves similar to the common hop but distinguished by unique flavonoid compositions in its tissues, including higher concentrations of certain prenylated not prominent in other . It features glandular cones analogous to those of H. lupulus but adapted to high-altitude montane habitats.

Evolutionary Relationships

The genus Humulus occupies a basal position within the Cannabaceae family, forming a sister clade to Cannabis alongside other genera such as Celtis and Trema. This phylogenetic placement is supported by analyses of chloroplast DNA (cpDNA) and nuclear markers, which confirm the monophyly of Cannabaceae and highlight shared morphological traits like stinging hairs and unisexual flowers. Recent molecular clock estimates, calibrated using fossil records and genomic data, suggest that Humulus and Cannabis diverged from a common ancestor approximately 16–23 million years ago during the early to mid-Miocene epoch. This divergence likely occurred in Eurasia, with subsequent radiation influenced by climatic shifts in the Tertiary period. Earlier classifications had grouped Humulus with Urticaceae due to superficial similarities in inflorescence structure, but 19th-century botanists, including Martynov who formalized Cannabaceae in 1820, recognized distinct affinities based on fruit and stipule characteristics, solidifying the modern family circumscription. Within Humulus, phylogenetic reconstructions using internal transcribed spacer (ITS) regions of nuclear ribosomal DNA and complete cpDNA genomes indicate an origin in temperate , with westward dispersal to . However, recent taxonomic revisions recognizing seven species necessitate updated phylogenies; earlier studies positioned H. lupulus as basal with East Asian taxa like H. scandens and H. yunnanensis in a derived , supported by sequence divergences in noncoding cpDNA regions and ITS motifs (bootstrap support ≥95%). The name Humulus derives from Medieval Latin humulus, likely from a Frankish Germanic referring to the . Natural hybridization among Humulus species is rare, limited by geographic isolation and dioecious breeding systems, though interspecific crosses like H. lupulus × H. scandens have been documented in cultivation. The close genetic proximity to Cannabis raises potential for artificial hybridization, offering avenues for breeding programs to transfer traits such as disease resistance or secondary metabolites, despite chromosomal barriers that prevent widespread natural introgression.

Distribution and Habitat

Native Ranges

_Humulus lupulus, the common hop, is native to temperate regions across , western , and northwestern . In these areas, it commonly inhabits riparian zones along streams and rivers, open woodlands, and disturbed soils such as roadsides and forest clearings, typically at elevations ranging from to 3000 meters. Humulus japonicus, also known as Japanese hop, is endemic to , including , , and eastern . It thrives in moist, sunny environments such as riverbanks, floodplains, and forest edges, where it can form dense vegetative cover. Humulus yunnanensis is restricted to the Province in , occurring in high-altitude shrublands and valleys at elevations between 2000 and 3000 meters. This species occupies montane habitats characterized by cooler temperatures and seasonal moisture availability. All Humulus species prefer temperate climates with annual rainfall of 500-1000 mm, well-drained loamy soils, and a range of 6-7.5, which support their dioecious, climbing growth habit. In their native ranges, they interact with associated , including pollinators that facilitate wind-assisted but insect-enhanced , and herbivores such as the hop (Phorodon humuli), which is specialized to feed on Humulus foliage.

Introduced and Invasive Populations

Humulus lupulus has been widely introduced outside its native ranges primarily for purposes. English settlers brought the species to and in the early 1800s, where it established commercial production; by 1998, alone produced approximately 2,500 metric tons of . Introductions to , particularly , followed similar patterns in the to support growing industries, leading to naturalized populations in temperate regions. In , H. lupulus was introduced from starting in 1629 for cultivation, becoming naturalized in eastern regions where it persists as a in disturbed habitats. These introduced populations often derive from European cultivars, resulting in genetic homogenization and reduced diversity compared to native western North American subspecies. In contrast, has become a notable in eastern and , introduced in the latter half of the as an from eastern . It thrives in wetlands and riparian zones, outcompeting native vegetation through rapid vegetative growth—reaching up to 8 meters in a season—and prolific seed production, which facilitates dispersal via and . The species forms dense monotypic stands that smother understory plants and suppress tree regeneration by limiting light penetration and altering soil moisture levels. Ecological impacts of H. japonicus are significant in riparian , where it reduces and , transforming diverse floodplains into uniform mats that promote native plant mortality through and physical overgrowth. These changes disrupt functions, including nutrient cycling and availability for wildlife, with invasions documented from the Atlantic coast westward to and southward to . Humulus yunnanensis, endemic to high-altitude regions in China's province, has not been introduced outside its native range and remains confined to local without reports of global spread. Management of invasive H. japonicus focuses on early detection and integrated approaches, including mechanical removal by hand-pulling or mowing before seed set in late summer, which disrupts growth but requires repeated efforts due to root regeneration. Herbicide applications, such as glyphosate (1% solution) or triclopyr (0.8% solution) as foliar sprays in spring or mid-summer, provide effective short-term control by reducing biomass, often combined with reforestation using fast-growing native trees to restore canopy cover and prevent reinvasion. The species is classified as a noxious weed in several U.S. states, with sales prohibited in Connecticut and Massachusetts to limit further spread.

Cultivation

Growing Requirements

Humulus cultivation primarily focuses on H. lupulus, the common hop, with H. japonicus occasionally grown as an and H. yunnanensis showing potential for experimental cultivation in brewing and pharmaceutical applications. , the primary species cultivated within the genus Humulus, thrives in cool temperate climates characterized by a frost-free of at least 120 days, with optimal conditions extending to 150-180 days to support full development and cone production. Ideal daytime temperatures range from 15-25°C (59-77°F), promoting vigorous and bine , while the plant can tolerate brief extremes but suffers stress below -10°C (14°F) in winter or above 35°C (95°F) during active , which may reduce yields and increase disease susceptibility. These conditions are typically met between latitudes 35° and 55° N, where long photoperiods of 15+ hours in summer trigger flowering. Soil requirements emphasize deep, fertile profiles with excellent drainage to prevent , favoring sandy or loams that retain without waterlogging. Optimal levels fall between 6.0 and 7.5, ensuring availability while avoiding deficiencies in iron or at lower or toxicities at higher . Annual demands range from 500-800 mm, supplemented in arid regions to maintain consistent , particularly during the critical late-season cone development phase when rainfall may be insufficient. Full sun exposure is essential, providing at least 12-15 hours of direct daily to maximize , production, and cone quality, with partial shade increasing vulnerability to foliar diseases. typically involves vertical trellising systems reaching 6-7 meters (20-23 feet) to accommodate the climbing bines, with spacing of 0.8-1.2 meters (2.5-4 feet) between hills and 2-3 meters (6-10 feet) between rows to optimize air circulation and light penetration. Nutrient management focuses on high nitrogen demands to fuel rapid vegetative growth, with applications of 100-150 kg/ha (90-135 lbs/) split across the season from early spring to mid-summer, balanced by (20-30 kg/ha) and (120-150 kg/ha) to support root establishment and cone maturation. such as (1-2 kg/ha) are critical to prevent deficiencies that cause brittle bines or reduced yields, monitored through regular and testing. Over-fertilization, particularly with late in the season, should be avoided to prevent excessive vegetative growth at the expense of cone quality. Hops are susceptible to several pests and diseases that necessitate integrated management strategies, including cultural practices, resistant varieties, and targeted treatments. , caused by Pseudoperonospora humuli, thrives in cool, wet conditions and can devastate yields if systemic infections occur in crowns; prevention involves pruning infected shoots, improving air flow through spacing, and applying copper-based fungicides during high-risk periods. , induced by spp., leads to vascular discoloration and plant decline in poorly drained soils, with no effective cure—management relies on , , and planting resistant cultivars to avoid long-term losses. Other pressures include and , addressed through scouting, beneficial insects, and sulfur or insecticidal soaps as needed within IPM frameworks.

Propagation and Harvesting

Propagation of Humulus lupulus, commonly known as , is predominantly achieved through vegetative methods to maintain desirable varietal characteristics in commercial . Rhizome cuttings or root divisions, taken in early from healthy parent plants, are the primary means of , as they allow for rapid establishment and genetic fidelity. These cuttings, typically 15-20 cm long with at least two buds, are planted directly into prepared fields at a depth of 5-10 cm and spaced 1-1.5 m apart in rows. For disease-free stock, especially in regions prone to pathogens like , tissue micro is employed, enabling the production of virus-indexed plantlets before field transfer. is rarely used commercially, reserved primarily for breeding programs to introduce , as seeds do not produce true-to-type plants due to the dioecious nature of the species. Following propagation, focuses on robust in the first year, with planting occurring in early after the last to leverage cool, moist conditions for sprouting. Selected bines—the climbing stems—are trained manually onto vertical supports such as , twine, or wire strings suspended from trellises reaching 5-7 m in , typically wrapping to promote upward and maximize . In the initial season, minimal is applied to encourage extensive systems, which can extend up to 3-5 m laterally, while limiting bine selection to 2-4 per plant to avoid nutrient competition; yields are negligible during this phase as energy is directed toward vegetative . Well-drained, fertile soils with 6.0-7.5, as outlined in guidelines, support this , though specific environmental details are addressed elsewhere. Harvesting of female hop cones occurs from late summer through early autumn, timed to coincide with peak lupulin development when cones reach 20-25% content, ensuring optimal bitter acid and oil concentrations. Commercial operations employ either hand-picking for small-scale or high-value aromatic varieties, where workers selectively remove mature cones to preserve quality, or harvesters that cut and separate bines from supports before cones from foliage, suitable for large fields of high-alpha types. Post-harvest, cones are dried rapidly using forced-air kilns at 60-65°C to reduce moisture to 8-10%, preventing microbial growth while retaining volatile compounds; over-drying below 8% can lead to brittleness and quality loss. Yield factors in commercial hop production vary by variety, climate, and management, typically ranging from 1.5 to 3 tons of dry cones per hectare after the second or third year, with optimal irrigation and fertilization boosting outputs in established yards. To mitigate disease buildup, such as powdery mildew or viral infections, fields are rotated or replanted every 15-20 years, allowing soil recovery and reducing pathogen reservoirs. Modern hop varieties emphasize breeding for enhanced disease resistance and yield stability, with global germplasm collections maintained by institutions like the USDA preserving wild and cultivated accessions for genetic improvement. High-alpha varieties, such as Magnum, offer 12-14% alpha acids for efficient bittering, while aroma-focused ones like (6-9% alpha) and Saaz (2-5% alpha) are selected for flavor profiles and partial resistance to . These developments, driven by programs in the U.S., , and , support sustainable intensification amid expanding craft brewing demands.

Chemical Composition

Bitter Acids and Resins

The bitter acids and resins of Humulus species, particularly Humulus lupulus, are non-volatile polyphenolic compounds concentrated in the glandular trichomes of the female cones, comprising up to 20-30% of the dry weight and serving as key contributors to bitterness and . These resins are broadly classified into soft and hard fractions based on solubility in solvents like or ; soft resins, which constitute 10-20% of total cone mass, primarily encompass the alpha and beta acids responsible for during , while hard resins (3-5%) consist of more complex, oxidized polyphenolic derivatives that influence flavor aging. Alpha acids, also known as , form the primary group of bitter compounds within the soft resins, typically accounting for 2-17% of the cone's dry weight depending on and growing conditions. This fraction includes three major homologues: (20-50%), cohumulone (20-50%), and adhumulone (about 15%), which isomerize under boiling conditions to iso-alpha acids that impart bitterness measured in . Beta acids, or lupulones, share a similar prenylated structure but are less polar and soluble, comprising 2-10% of dry weight; the main components are lupulone, colupulone, and adlupulone, which contribute indirectly to foam stability and exhibit activity without significant . Hard resins, derived from oxidation of soft resin precursors, include compounds like hulupones and humulinones, which form during storage or processing and can alter beer flavor through astringency or residual bitterness, though they represent a minor fraction (3-5%) compared to soft resins. Polyphenolic oxidation products in this category, such as hulupones from beta acid degradation, impact long-term stability but contribute less to initial bitterness than iso-alpha acids. Content and ratios of alpha and beta acids vary markedly by hop variety, with high-alpha bittering types like Nugget exhibiting 11.5-14% alpha acids and 3-5% beta acids, whereas aroma-focused cultivars maintain lower alpha levels (2-5%) and higher beta proportions for subtle flavor enhancement. These variations arise from genetic and environmental factors, influencing selection in . Quantification of bitter acids and resins typically employs (HPLC) with reverse-phase columns and UV detection at 275-370 nm, using methanol-water gradients for separation; this method allows precise determination of homologues and oxidation products, with extraction via solvents like ensuring recovery rates above 95%. Storage stability of these compounds is variable, with alpha acids degrading up to 20-30% over months under suboptimal conditions, leading to increased hard formation.

Essential Oils and Flavonoids

Essential oils in Humulus species, particularly H. lupulus, constitute 0.5-3% of the dry weight of hop cones and are primarily responsible for the plant's characteristic aromas. These volatile compounds are obtained through , yielding approximately 0.2-1 ml per 100 g of dry material. The major components include monoterpenes such as (20-50%, imparting resinous and herbal notes) and sesquiterpenes like α-humulene (15-35%, contributing woody aromas) and β-farnesene (variable, up to 7-8%, with citrus-like qualities). Composition varies by chemotype; for instance, Hallertau varieties exhibit elevated α-humulene levels (30-50%), influencing their distinct spicy profiles. Flavonoids in Humulus are polyphenolic compounds concentrated in lupulin glands, with prenylated chalcones like xanthohumol (0.1-1% of dry weight) and desmethylxanthohumol serving as key antioxidants. These flavonoids exhibit estrogenic activity due to their structural mimicry of phytoestrogens, potentially modulating hormonal responses. Other polyphenols, such as proanthocyanidins, contribute to astringency through protein-binding interactions in plant tissues and extracts. Similar prenylflavonoids, including xanthohumol, are present in other species like H. yunnanensis, supporting their potential pharmaceutical applications. Analytical methods for profiling these compounds include gas chromatography-mass spectrometry (GC-MS) for essential oils, enabling separation and identification of terpenoids based on retention times and mass spectra. Liquid chromatography-mass spectrometry (LC-MS) is employed for , providing high-resolution quantification of prenylated structures. Environmental factors, including , soil conditions, and harvest timing, significantly influence oil and profiles, with warmer temperatures often elevating content. Biosynthetically, essential oils derive from the in cytosolic compartments, producing isopentenyl diphosphate precursors that form monoterpenes and sesquiterpenes via terpene synthases; this process links to broader evolution in for defense and attraction. arise from the phenylpropanoid pathway, with enhancing their bioactivity.

Uses

Brewing Applications

Humulus lupulus, commonly known as , has been integral to production since the 11th century in , where it replaced traditional herb mixtures to impart bitterness and enhance preservation through properties. This shift began in regions like northern and , with hopped becoming commonplace by the late medieval period, as evidenced by royal decrees such as King Louis IX's 1268 edict limiting ingredients to and . The adoption of not only standardized brewing but also extended 's shelf life compared to earlier ale styles. In modern brewing, are added at various stages to balance bitterness, flavor, and aroma. Early additions, typically during a 60-90 minute , isomerize alpha acids for primary bitterness, with high-alpha varieties like Magnum preferred for this purpose due to their efficient contribution to the scale, where 1 IBU equates to 1 mg/L of iso-alpha acids. additions post- extract flavor compounds at lower temperatures around 80-90°C, while dry-hopping in vessels preserves volatile oils for aroma without additional bitterness. These methods allow brewers to tailor profiles, with aroma-focused like Citra—rich in essential oils—deployed late to emphasize and tropical notes. Hop varieties are categorized by use: bittering types such as Magnum (12-14% alpha acids) for clean, high-efficiency bitterness; aroma varieties like Citra (11-13% alpha acids, high oil content) for vibrant scents; and dual-purpose options like that serve both roles. Processing enhances usability, with compressing dried cones into dense forms for uniform extraction and reduced volume in kettles. CO2 extraction yields concentrated resins for precise control in , minimizing vegetative material. Additionally, hop polyphenols contribute to foam stability by interacting with proteins to form a lasting head. Global hop production reached approximately 118,000 metric tons in 2023 and declined to about 113,500 metric tons in 2024, supporting the industry's demand for these versatile ingredients. Leading producers include the (around 47,000 tons in 2023; approximately 39,500 tons in 2024), (over 40,000 tons in 2023; about 49,000 tons in 2024), and (about 10,000 tons in 2023), with the U.S. and accounting for roughly 75% of the world crop in 2023.

Medicinal and Therapeutic Uses

Humulus lupulus, commonly known as , has been employed in for centuries, particularly for digestive ailments and as a mild . Historical records indicate that teas prepared from hop cones were used to soothe the , stimulate , and promote healthy , with recommendations from herbalists dating back to medieval . In the , hop pillows—filled with dried strobiles—gained popularity as a remedy for , leveraging the plant's reputed calming aroma to induce . The sedative properties of hops are primarily attributed to compounds like , which modulate GABA_A receptors, mimicking the action of benzodiazepines to promote relaxation and . extracts of hops have been incorporated into sleep aids, with clinical trials demonstrating mild effects; for instance, a randomized placebo-controlled pilot study found that hop extract reduced self-reported anxiety symptoms. These effects are often enhanced when combined with , as evidenced by human studies showing improved quality without significant respiratory depression. Hops also exhibit antimicrobial and anti-inflammatory activities, driven by beta acids and xanthohumol. Beta acids demonstrate potent activity against Gram-positive bacteria, including strains of Staphylococcus and Clostridium, by disrupting cell membranes, as shown in in vitro assays against pathogens like C. difficile. Xanthohumol inhibits NF-κB signaling, reducing inflammation and exhibiting potential cancer-preventive effects in cell-based studies, though human trials remain limited. Contemporary research explores ' phytoestrogens, such as , for menopausal symptom relief, with randomized controlled trials indicating reductions in hot flashes and sleep disturbances at doses of hop extract standardized to 100 μg of . Preliminary evidence suggests benefits for prevention through estrogenic effects on , supported by animal models showing increased content. The U.S. FDA recognizes extracts as (GRAS) for use in foods and supplements, but no hop-derived compounds are approved as prescription drugs for these indications. Common forms include tinctures, capsules, and teas, with typical dosages ranging from 200-500 mg of dried extract daily for effects or 10-100 mg of for targeted benefits, divided into 1-3 doses. Hop supplements may interact with depressants like or , potentially enhancing drowsiness and respiratory suppression, necessitating caution in concurrent use.