Polygonaceae

Polygonaceae is a family of flowering plants in the order Caryophyllales, comprising approximately 48 genera and 1,200 species of herbs, shrubs, vines, and rarely small trees.^[1] These plants are distinguished by their alternate leaves with characteristic ocreae—membranous, tubular sheaths formed by fused stipules at the leaf bases—and small, actinomorphic flowers featuring 3 to 6 petaloid tepals in two whorls, typically producing a three-angled achene fruit.^[2] Native predominantly to the Northern Hemisphere's temperate regions but with a nearly cosmopolitan distribution extending into tropical areas like Mesoamerica and Southeast Asia, the family includes diverse growth forms adapted to various habitats from arid deserts to wetlands.^[1]^[3] Among the largest genera are Polygonum (knotweeds, ~150 species), Rumex (docks and sorrels, ~200 species), Eriogonum (buckwheats, ~250 species), and Coccoloba (sea grapes, ~150 species), many of which exhibit dioecious or monoecious sexual systems and pollination by insects, wind, or flies.^[1]^[2] Economically, Polygonaceae species are significant for food production, with buckwheat (Fagopyrum esculentum) serving as a pseudocereal crop for grains and flour, rhubarb (Rheum rhabarbarum) cultivated for its edible leaf stalks, and sorrel (Rumex acetosa) used in salads and soups due to its tangy flavor.^[4] Some members, like Antigonon leptopus (coral vine), are valued ornamentals for their showy pink flowers, while others, such as certain Polygonum species, are noted for medicinal properties including anti-inflammatory and antimicrobial effects in traditional veterinary and human uses.^[3]^[5] Ecologically, the family plays key roles in ecosystems as pioneer species in disturbed soils, providing nectar for pollinators and seeds for birds, though invasive species like Japanese knotweed (Reynoutria japonica) pose challenges by outcompeting native vegetation in temperate zones.^[6] The fossil record of Polygonaceae dates back to the Paleocene, underscoring their ancient lineage within the Caryophyllales.^[1]

Overview

Etymology and common names

The family name Polygonaceae was established by the French botanist Antoine Laurent de Jussieu in his seminal 1789 publication Genera Plantarum.^[7] This nomenclature formalized the grouping of plants previously recognized under various informal classifications. The term Polygonaceae derives from the Greek words polys (many) and gonu or gonia (knee or joint), reflecting the structure associated with the type genus Polygonum.^[8]^[9] In English-speaking regions, the family is commonly referred to as the knotweed family, smartweed family, or buckwheat family, with the latter two names particularly prevalent in the United States.^[10]^[11] Regional variations include the dock family, often used in European contexts to encompass genera like Rumex.^[12] These common names frequently stem from key genera such as Polygonum (knotweed) and Fagopyrum (buckwheat).^[13]

General characteristics and diversity

The Polygonaceae family encompasses approximately 46–55 genera and 1,100–1,200 species distributed worldwide.^[14]^[15] This family is placed within the order Caryophyllales, alongside other diverse flowering plant groups characterized by unique biochemical and structural features.^[16] Predominant life forms in Polygonaceae include herbs and shrubs, with rarer occurrences of small trees, vines, or lianas; most species are annuals or perennials adapted to a range of growth habits.^[14]^[3] Key unifying traits across the family are the presence of ocreae—tubular sheaths formed by fused stipules at the nodes—the alternate arrangement of simple leaves, and flowers featuring a perianth of 3 to 6 tepals rather than distinct sepals and petals.^[14]^[15]^[3] The family's diversity is emphasized in temperate and subtropical regions, though it includes some tropical and aquatic species, reflecting a cosmopolitan distribution with centers of richness in northern temperate zones and the Neotropics.^[14]^[1] This variation supports ecological roles in various habitats, encompassing weedy pioneers, ornamental plants valued for their foliage and flowers, and economically important crops such as buckwheat.^[14]^[17]

Taxonomy and classification

Historical development

The family Polygonaceae was established as a distinct taxonomic group by Antoine Laurent de Jussieu in his 1789 work Genera Plantarum, where it was delimited primarily by the perianth consisting of five or six tepals and the seed enclosed in an achene fruit.^[18] This initial recognition emphasized the uniformity of these floral and seed traits across genera centered on Polygonum, marking a shift from earlier artificial classifications toward a more natural system based on shared reproductive structures. During the 19th century, the family's scope expanded significantly through the contributions of Carl Friedrich Meisner, who in 1856 published a comprehensive monograph in the Prodromus Systematis Naturalis Regni Vegetabilis. Meisner incorporated woody tropical genera such as Coccoloba and Triplaris, previously treated separately or in allied families, and proposed an infrfamilial division into four subfamilies, including Eriogonoideae for North American elements distinguished by their involucrate inflorescences.^[18] This work reflected growing botanical exploration and herbarium collections from the Americas and Asia, broadening the family's circumscription to about 30 genera while highlighting morphological variability in habit and stipule sheaths (ocreae). Key revisions in the late 19th and early 20th centuries, notably by George Bentham and Joseph Dalton Hooker in their 1880 Genera Plantarum, adopted an even wider circumscription, uniting over 40 genera under Polygonaceae based on shared ocreae, perianth structure, and achene morphology. This broad approach, however, sparked ongoing debates about boundary genera, with some like those resembling Plumbaginaceae elements provisionally included but later excluded due to differences in calyx persistence and seed coat features. Pre-molecular taxonomy relied heavily on these vegetative and reproductive traits, often resulting in artificial groupings. By the mid-20th century, challenges in classifying Polygonaceae intensified, particularly with the genus Polygonum sensu lato, where morphological convergence in seed shape and inflorescence led to repeated lumping of disparate species into broad sections or splitting into segregate genera like Persicaria and Fallopia.^[19] Such instability underscored the limitations of phenotype-based systems, as subtle variations in ocreae and achene ornamentation were insufficient to resolve evolutionary relationships amid the family's global diversity of over 1,000 species. Recent molecular data have begun to reshape these historical views by revealing deeper phylogenetic structure.

Current subfamilies and tribes

The family Polygonaceae is currently classified into three subfamilies based on molecular phylogenetic analyses: Eriogonoideae, Polygonoideae, and the monogeneric Symmerioideae.^[20] This framework, proposed in a 2011 revision, recognizes approximately 50 genera across the family, with ongoing refinements reflecting new phylogenetic data.^[21] Eriogonoideae, the largest subfamily with about 20 genera and roughly 325 species, is primarily distributed in North America and includes many herbaceous and shrubby taxa. It is divided into six tribes: Brunnichieae, Coccolobeae, Eriogoneae, Triplarideae, Gymnopodieae, and Leptogoneae, the last two newly established in the 2011 classification.^[20] Key diagnostic traits include the absence of ocreae (or rudimentary ones in some genera), flowers often subtended by involucral bracts, unwinged fruits, and frequently drupaceous pericarps, as seen in genera like Coccoloba and Eriogonum.^[20]^[22] Polygonoideae, comprising around 30 genera and the majority of the family's cosmopolitan diversity, encompasses herbaceous to woody plants worldwide.^[23] A concurrent 2011 tribal revision delineates five well-supported tribes: Calligoneae, Fagopyreae, Persicarieae, Polygoneae, and Pteroxygoneae.^[24] Distinguishing features encompass persistent ocreae at nodes, achene fruits typically enclosed by persistent tepals that may be winged or accrescent, and bisexual flowers without involucres, exemplified in genera such as Rumex and Persicaria.^[24]^[25] Symmerioideae consists solely of the genus Symmeria, with one species, Symmeria paniculata, of scandent shrubs native to tropical West Africa and the Amazon Basin.^[21] It lacks a tribal subdivision due to its limited scope and is characterized by unique traits such as unisexual flowers, obsolete or scarious ocreae, and achenes with accrescent tepals forming a utricle-like structure.^[20] This classification builds on earlier dichotomous systems but incorporates phylogenetic evidence to resolve previously polyphyletic groupings.^[21]

Morphology and reproduction

Vegetative structures

The stems of Polygonaceae species are typically herbaceous, though woody forms occur in some shrubs and trees, and exhibit a range of growth habits including prostrate, erect, scandent, or climbing.^[15] They are often articulate, featuring swollen nodes from which ocreae arise, and can be solid or hollow, glabrous or pubescent, with occasional recurved spines in genera like Persicaria.^[15] In subfamily Eriogonoideae, caudex stems may be woody and compact or spreading.^[15] Leaves in the Polygonaceae are simple, alternate (rarely opposite or whorled), and petiolate, with blades that are entire-margined, occasionally crenulate or lobed, and shapes varying from ovate and lanceolate to cordate, hastate, or sagittate. Venation is typically pinnate, and a distinctive family feature is the ocrea—a membranous or fringed sheath formed by fused stipules that encircles the stem at the node above the petiole, persistent or deciduous in subfamily Polygonoideae but absent or rudimentary in Eriogonoideae.^[15] Leaves are deciduous in most species but persistent in genera such as Coccoloba, Antigonon, Eriogonum, Chorizanthe, and Polygonella.^[15] Roots in Polygonaceae are generally fibrous or form a solid taproot, though chambered or tuberous forms occur rarely, as in Rumex species where thickened tubers serve for storage.^[15] Mycorrhizal associations are common, with arbuscular mycorrhizae observed in roots of various genera like Polygonum and Rumex, facilitating nutrient uptake.^[26] Vegetative variations include rhizomatous growth in perennials like Fallopia japonica (Japanese knotweed), which produces extensive underground rhizomes for propagation.^[15] In arid-adapted taxa, such as those in Eriogonum, stems may be flattened and photosynthetic, as seen in Muehlenbeckia platyclados.

Floral and fruit characteristics

The inflorescences of Polygonaceae are typically axillary or terminal, arranged as erect to pendent racemes or panicles, often with flowers clustered in ochreolate fascicles.^[3] These structures vary across genera, such as spicate inflorescences in Muehlenbeckia or racemose forms in Podopterus and Magoniella.^[3] Flowering stems may bear ocreae similar to those on vegetative parts.^[15] Flowers in the family are bisexual or unisexual, actinomorphic, and feature a perianth of 3–6 basally connate tepals that are not differentiated into sepals and petals.^[3] The androecium consists of 6–9 stamens, usually in two series, with filaments distinct or basally connate.^[15] The gynoecium includes a superior, 1-locular ovary containing a single ovule, topped by 2–4 styles each ending in a stigma.^[3] Pollination is primarily entomophilous, facilitated by nectar or pollen rewards in many species, though some exhibit anemophily.^[27] For instance, Triplaris gardneriana relies on insect vectors despite traits suggestive of wind pollination.^[27] Fruits are achenes, typically one-seeded and trigonous, biconvex, or biconcave, often enclosed by persistent or accrescent tepals that may become fleshy or winged.^[15] In genera like Coccoloba and Muehlenbeckia, the tepals develop into fleshy structures, while in Podopterus and Magoniella, they form wings.^[3] Seeds within the achenes possess abundant, mealy endosperm and a straight or curved embryo.^[15] Dispersal mechanisms include anemochory via winged tepals, zoochory through fleshy fruits attractive to birds and mammals, and hydrochory in aquatic or riparian species.^[28] Examples include the ballistic "jumpseed" ejection in Persicaria virginiana and water-mediated spread in Fallopia species.^[29]^[30]

Distribution and ecology

Global distribution patterns

The Polygonaceae family exhibits a cosmopolitan distribution, with approximately 1,200 species across 48 genera found on every continent except Antarctica.^[15] The family is predominantly diverse in north temperate zones, including Europe, Asia, and North America, where the majority of species occur, reflecting a strong bias toward cooler climates.^[14] This temperate concentration is linked to the distribution of key subfamilies like Polygonoideae, which dominate in these regions.^[31] Regional hotspots of diversity and endemism include the Andes, where genera such as Coccoloba show high species richness and localized endemism, particularly in northern Andean dry forests of Ecuador and Peru.^[32]^[33] In Australia, the family is represented by approximately 36 native species, several of which are endemic to southern temperate areas.^[9] Southern Africa also hosts endemic Polygonaceae, with new species discoveries in tropical regions underscoring localized diversity.^[34] Several species have been widely introduced outside their native ranges, becoming invasive in temperate zones. Reynoutria japonica (Japanese knotweed), native to East Asia, is a prominent example, establishing populations across North America (in 45 states as of 2025), Europe, and other temperate areas through human-mediated dispersal and rhizome fragmentation.^[35]^[36]^[37] This has altered local biogeographic patterns in invaded regions.^[38] Latitudinal trends reveal fewer species in tropical lowlands compared to temperate areas, though Polygonaceae persist in tropical montane zones like the Andes and coastal habitats in the Neotropics.^[31]

Habitat preferences and ecological roles

Polygonaceae species are adapted to a variety of habitats, including disturbed soils, wetlands, grasslands, and forests, where they often thrive in marginal conditions such as poor, acidic, or saline environments. This tolerance enables the family to occupy pioneer niches in ecosystems recovering from disturbance, with many genera exhibiting ruderal characteristics that facilitate colonization of open or degraded sites. For instance, species in the subfamily Polygonoideae are noted for their presence across subtropical to alpine zones, contributing to vegetation in diverse topographic and edaphic settings.^[39] Key adaptations within the family include drought tolerance achieved through underground tubers or rhizomes, which store water and nutrients during dry periods, as observed in genera like Rumex and Fagopyrum. Aquatic and semi-aquatic forms, particularly in the genus Persicaria, are specialized for freshwater habitats such as riverbanks and ponds, where they can withstand periodic flooding. Additionally, certain species demonstrate high invasive potential in nitrogen-enriched sites, such as agricultural fields or urban areas, due to their rapid growth and vegetative reproduction. The diversity of Persicarieae exemplifies ecological adaptations to varied aquatic and terrestrial environments, enhancing the family's versatility.^[40] Ecologically, Polygonaceae play significant roles as soil stabilizers, with their extensive root networks preventing erosion in vulnerable habitats like slopes and riverine areas. They serve as important food sources for herbivores, pollinators, and insects, thereby supporting trophic interactions and biodiversity; for example, native Japanese species act as insectary plants for natural enemies. While not capable of true nitrogen fixation, some members form associations with mycorrhizal fungi that improve nutrient acquisition, indirectly aiding ecosystem fertility and plant community dynamics. In wetland ecosystems, they bolster biodiversity by providing structural habitat and stabilizing sediments against wave action.^[39]^[41] However, the invasive tendencies of several species, such as those in Reynoutria and Fallopia, pose threats to native flora by forming dense stands that suppress understory growth and alter soil chemistry in introduced ranges. These invasives often exploit disturbed or nutrient-rich sites, disrupting local ecological balance and reducing habitat quality for endemic species.^[42]

Economic and cultural significance

Culinary and agricultural uses

The Polygonaceae family includes several species valued for their culinary applications, particularly as pseudocereals and leafy vegetables. Fagopyrum esculentum, commonly known as common buckwheat, is the most prominent crop, cultivated primarily for its nutrient-dense seeds used in grains, flour production, and traditional dishes like Japanese soba noodles.^[43] In 2023, world production of buckwheat was approximately 2.2 million tonnes, led by Russia with 1.15 million tonnes (52% of the total), followed by China with 0.504 million tonnes, reflecting its role as a resilient alternative to conventional cereals in diverse agricultural systems.^[44]^[45] Leafy greens from the family also contribute to culinary traditions, especially in temperate regions. Rumex acetosa, or garden sorrel, provides tangy leaves that are harvested for use in salads, soups, and sauces, adding a lemon-like acidity to dishes.^[46] Similarly, the petioles of Rheum rhabarbarum, known as rhubarb, are a staple in desserts such as pies and crumbles, as well as in jams and savory accompaniments, due to their tart flavor when cooked with sugar.^[47] These vegetables are often grown in home gardens or small-scale farms for fresh consumption. Certain Polygonum species serve niche roles in food security and animal husbandry. Seeds from species like Polygonum aviculare have historically been utilized as famine foods, ground into meal or mixed with other grains during shortages.^[48] Additionally, buckwheat forage and by-products, including hulls and bran, are fed to livestock such as ruminants, providing a supplementary source of nutrition in feed rations.^[49] Cultivation of Polygonaceae crops generally favors cool, moist climates, where buckwheat matures quickly in 6-12 weeks under temperatures of 15-27°C, making it suitable for short-season areas. However, high oxalate content in leaves and stems of species like sorrel and rhubarb poses challenges, potentially limiting consumption due to risks of kidney stone formation in susceptible individuals and requiring processing methods like cooking to reduce levels.^[50]

Medicinal and ornamental applications

The roots of Rheum palmatum, a species in the Polygonaceae family, have been utilized in traditional Chinese medicine for their anthraquinone glycosides, which exhibit laxative properties and are employed to treat constipation and promote detoxification.^[51] These compounds also demonstrate anti-inflammatory and antioxidant effects, contributing to the plant's role in managing conditions like acute abdomen and blood stasis.^[52] Similarly, Polygonum cuspidatum (now classified as Reynoutria japonica) serves as a primary natural source of resveratrol, a flavonoid with potent anti-inflammatory activity that suppresses oxidative stress and NF-κB pathways, potentially aiding in the treatment of arthritis and cardiovascular issues.^[53] Extracts from this plant have shown efficacy in reducing inflammation in clinical settings, such as among athletes.^[54] While some Polygonaceae species offer therapeutic benefits, others pose health risks due to high oxalate content. For instance, Rumex species accumulate soluble oxalates, which can bind calcium and lead to mineral deficiencies, kidney stones, or urinary syndromes if consumed excessively, particularly in livestock or humans relying on them as wild greens.^[55] This toxicity underscores the need for moderation in their use, even in traditional remedies.^[56] In ornamental horticulture, Polygonaceae species are valued for their aesthetic and adaptive qualities. Persicaria capitata, with its creeping stems and pink flower heads, is employed as a low-growing ground cover in gardens, particularly in tropical and subtropical landscapes where it provides year-round foliage interest.^[57] Likewise, Coccoloba uvifera (sea grape) is widely planted for coastal landscaping due to its salt tolerance, rounded canopy, and edible purple fruits that attract wildlife, making it a low-maintenance choice for beachfront stabilization and ornamental borders.^[58] Certain Polygonaceae plants hold cultural significance in traditional folklore, such as Polygonum aviculare (knotweed), which Cherokee communities used in root infusions to treat flux and kidney ailments, reflecting its role in indigenous healing practices.^[59]

Genera

List of accepted genera

The Polygonaceae family currently recognizes approximately 48 genera, comprising about 1,200 species with a cosmopolitan distribution.^[7] These genera are distributed across two subfamilies, Polygonoideae and Eriogonoideae, with diverse habits ranging from annual herbs to woody shrubs and vines.^[7] Key genera include Polygonum (sensu stricto), which contains around 170 species of cosmopolitan weeds, often annual or perennial herbs with knotty stems and ocreae at nodes, native to temperate and subtropical regions worldwide.^[60] Rumex, with approximately 200 species known as docks or sorrels, features robust perennials or annuals with basal leaves and ocreae, primarily native to temperate and subtropical Old World regions but widely introduced elsewhere.^[61] Fagopyrum, the buckwheats, includes about 30 species of mostly annual herbs cultivated for edible seeds, native to temperate Asia, particularly the Himalayas and eastern China.^[62] Eriogonum, encompassing roughly 250 species of North American buckwheats, consists of diverse herbs, subshrubs, and shrubs with basal rosettes and involucrate inflorescences, endemic to western North America from Alaska to Mexico.^[63] Coccoloba, with about 150 species of tropical trees, shrubs, and vines known as sea grapes, is native primarily to the Americas and the Caribbean.^[64] In the Eriogonoideae subfamily, examples include Antigonon, a genus of climbing vines with tuberous roots and pink or white flowers, native to tropical America and often grown ornamentally. In Polygonoideae, Atraphaxis represents shrubs adapted to arid environments, with about 50 species featuring small leaves and spiny branches, primarily native to Central Asia and the Mediterranean. Notable genus-specific traits include the winged or keeled fruits in Chorizanthe, a group of small annual herbs with spiny involucres, native to arid western North America.^[65]

Formerly recognized genera

The genus Polygonum L. sensu lato historically encompassed over 200 species within the Polygonaceae family, including a diverse array of annuals, perennials, and shrubs characterized by variable vegetative and floral traits.^[66] Early taxonomic treatments in the 20th century treated this broad circumscription as cohesive, but morphological analyses in the late 1980s began to highlight inconsistencies, particularly in floral structures such as nectary morphology and tepal arrangements.^[67] Pioneering revisions by Louis P. Ronse De Craene and colleagues in the 1980s and 1990s proposed segregating Polygonum s.l. into more narrowly defined genera based on these morphological characters, dividing it into tribes like Polygoneae (including Polygonum s.s., Fallopia, and Polygonella) and Persicarieae (including Persicaria and related groups).^[68] Subsequent molecular phylogenetic studies in the 2000s confirmed the polyphyly of Polygonum s.l., using markers like rbcL and ITS to demonstrate that its species formed multiple distinct clades across the subfamily Polygonoideae.^[24] These findings necessitated further taxonomic restructuring to achieve monophyletic groupings. Major segregations included the recognition of Persicaria Miller for marsh-adapted species previously under Polygonum section Persicaria, such as wetland annuals and perennials with ocreae and spike-like inflorescences.^[19] Climbers like those formerly in Polygonum section Plebeia were transferred to Fallopia Adans., emphasizing their twining stems and achene traits.^[24] Similarly, invasive knotweeds, including Japanese knotweed (Reynoutria japonica), were placed in Reynoutria Houtt., distinguished by their robust rhizomes and paniculate inflorescences.^[69] The genus Bistorta L., encompassing species with basal leaves and terminal spikes like Bistorta officinalis, is recognized as distinct within Persicarieae, though earlier studies suggested synonymy under Persicaria based on phylogenetic data.^[70] Certain montane or alpine taxa, such as those with paniculate flowers, were reassigned to Aconogonon Reichenb., reflecting their closer affinity to that clade.^[71] These changes, driven by integrative evidence from morphology and DNA sequences during the 1990s and 2000s, reduced Polygonum sensu stricto to approximately 170 species, primarily annual or perennial herbs in section Polygonum with simple ocreae and small flowers.^[72] Post-revision classifications recognize these segregate genera as stable within current tribal frameworks.^[73]

Phylogeny and evolution

Molecular phylogenetic studies

Early molecular studies in the 1990s primarily relied on the plastid gene rbcL to establish the phylogenetic position of Polygonaceae within the Caryophyllales order. Chase et al. (1993) analyzed rbcL sequences from diverse angiosperms, confirming Polygonaceae's placement in Caryophyllales alongside families like Plumbaginaceae and Amaranthaceae. Kron and Chase (1993) further applied rbcL data specifically to Polygonaceae, revealing initial subfamily divisions and indicating that traditional groupings such as Polygonoideae were potentially paraphyletic, with Eriogonoideae emerging as a distinct clade. The matK gene, another plastid marker, began to be incorporated in late-1990s studies of Caryophyllales, providing complementary resolution for Polygonaceae's deeper relationships, though family-specific matK analyses remained limited until the 2000s.^[74]^[75] In the 2000s, comprehensive phylogenies expanded to multi-gene datasets, enhancing resolution within Polygonaceae. The Angiosperm Phylogeny Group II (APG II) classification (2003) synthesized emerging molecular evidence, including rbcL and matK, to solidify Polygonaceae's position in Caryophyllales and outline broad intrafamilial structure. Sanchez et al. (2009) conducted a large-scale analysis sampling 75 species across approximately 40 genera, using chloroplast genes (rbcL, matK, ndhF) and nuclear ITS regions; their trees, inferred via Bayesian methods and maximum likelihood, resolved key clades in Polygonoideae and supported the monophyly of Eriogonoideae. Building on this, Schuster et al. (2011) integrated matK, ndhF, and ITS data to propose a revised tribal classification for Polygonoideae, recognizing five monophyletic tribes (Calligoneae, Fagopyreae, Persicarieae, Polygoneae, and Rumiceae) based on maximum likelihood phylogenies. Recent advances have leveraged multi-locus datasets, including complete plastomes and nuclear markers, for finer-scale resolution. Liu et al. (2022) assembled 49 plastomes representing 22 genera, analyzing whole-chloroplast data with Bayesian inference and maximum likelihood to confirm Eriogonoideae's monophyly and clarify basal polytomies in Polygonoideae; this supported a modern taxonomy encompassing about 46 genera while highlighting incongruences between plastid and nuclear ITS topologies. These phylogenomic approaches have refined generic boundaries and influenced contemporary classifications by providing robust statistical support for clade stability.^[31]

Evolutionary history and adaptations

The Polygonaceae family diverged within the Caryophyllales order during the Early Cretaceous, with molecular clock estimates placing the stem age at approximately 111 million years ago and the crown-group origin around 77 million years ago (95% highest posterior density: 62–93 million years ago). This timeline is supported by fossil pollen records assigned to Polygonaceae or closely related caryophyllids from the Late Cretaceous, dating to about 80–72 million years ago, indicating an early establishment during the diversification of core eudicots. These ancient origins align with the family's basal position in Caryophyllales, predating the breakup of major landmasses and setting the stage for subsequent global spread. A 2023 phylogenomic study corroborated the late Cretaceous origin of Polygonoideae and highlighted adaptive evolution in key genes during Eocene and Miocene diversification.^[76] Diversification within Polygonaceae accelerated during the Miocene, roughly 20 million years ago, marked by increased net speciation rates that coincided with cooling climates and the expansion of open, temperate habitats worldwide. In the Neotropics, the woody genus Coccoloba exemplifies regional radiation, with phylogenetic analyses revealing a Mesoamerican origin, followed by one migration to South America, colonization of the Caribbean, and multiple returns to the mainland, driven by tectonic changes including the Andean uplift that generated diverse elevational gradients and isolation opportunities.^[77] The family's biogeographic history reflects a primary cradle in the Northern Hemisphere—Laurasian regions—with dispersals southward via long-distance seed transport, as evidenced by disjunct distributions in genera like Muehlenbeckia across Pacific islands and southern continents. Key adaptations have facilitated Polygonaceae's success across varied environments, including the independent evolution of C4 photosynthesis in the arid-adapted genus Calligonum, which enhances carbon fixation efficiency under high temperatures and low CO2 conditions, representing one of at least 62 convergent C4 origins in angiosperms. Chemical defenses, such as the accumulation of calcium oxalate crystals in leaves and stems, provide protection against herbivory by forming indigestible structures that irritate mouthparts or bind essential nutrients like calcium, a trait widespread in genera like Rumex and contributing to occupancy of nutrient-poor soils. Additionally, hybridization events within the Polygonum (now including Persicaria and Fallopia) complex have driven adaptive evolution, enabling homoploid hybrid speciation and increased morphological and ecological variation in temperate and wetland habitats.