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Hydrocotyle

Hydrocotyle is a of flowering in the family , consisting of approximately 180 species of slender perennial herbs that typically inhabit , aquatic, and moist terrestrial environments across a . These , commonly known as pennyworts or marsh pennyworts, are characterized by their creeping or floating stems, simple peltate or non-peltate leaves with palmate venation, and small greenish-white to purplish flowers arranged in simple umbels or spikes. The genus Hydrocotyle was first described by in 1753 and derives its name from the Greek words hydro (water) and kotylē (small cup), alluding to the water-loving nature and cup-shaped leaves of many species. Historically classified within the (carrot family), molecular phylogenetic studies have confirmed its placement in the (ginseng family), reflecting evolutionary relationships within the order . With centers of diversity in regions such as , , and southeastern Asia (particularly ), the genus exhibits a predominantly bias, though a few species extend into the . Morphologically, Hydrocotyle species are adapted to damp conditions, often forming dense mats via long, rooting stolons; leaves are typically rounded, kidney-shaped, or lobed, measuring 1–10 in diameter, with sheathing petiole bases and small stipules. Inflorescences are borne on scapes arising from leaf axils, featuring 3–20 tiny flowers with five petals, and the fruits are schizocarpic, laterally compressed, and ribbed with five filiform ridges per mericarp. Habitats range from freshwater marshes and stream banks to coastal dunes and even karsts in tropical and subtropical zones, with some species exhibiting high . Several Hydrocotyle species hold ecological, ornamental, and ethnobotanical significance; for instance, H. bonariensis is noted for its antioxidant-rich properties and traditional use in treating and in various cultures. Others, like H. verticillata and H. umbellata, are common in North American and can become weedy in disturbed areas, while H. sibthorpioides is valued in Asian for ground cover. Although not as prominently medicinal as the related Centella (formerly including some Hydrocotyle taxa), the genus contributes to in aquatic ecosystems and supports restoration efforts.

Taxonomy

Etymology and history

The genus name Hydrocotyle derives from the Greek words hydōr (ὕδωρ), meaning "," and kotylē (κοτύλη), meaning "" or "small dish," reflecting the or semi-aquatic habits of many in the and possibly alluding to the cup-like hollow at the base of the leaves. This etymology underscores the characteristic association of these plants with wet environments, where they often form creeping mats in marshes, streams, or damp soils. The genus was formally established by in his seminal 1753 publication , in which he described Hydrocotyle as a member of the family and included initial species such as H. vulgaris and H. umbellata based on their peltate leaves and umbellate inflorescences. Linnaeus's treatment marked the beginning of systematic recognition for the group, drawing from earlier herbal traditions that noted their medicinal uses in damp habitats across and beyond. This foundational description laid the groundwork for subsequent botanical explorations, particularly as European naturalists encountered diverse species in tropical regions during colonial expeditions. A pivotal taxonomic revision came in 1936 with Mildred E. Mathias's monograph "The Genus Hydrocotyle in Northern South America," published in Brittonia, which clarified species distinctions and separated Hydrocotyle from closely related genera within Apiaceae through detailed morphological analyses of fruits, leaves, and habits. Mathias's work, later expanded in collaborations with Lincoln Constance in publications such as their treatments in North American Flora (1944–1945), emphasized the genus's variability and helped resolve ambiguities in its circumscription. Historically, Hydrocotyle has been taxonomically confused with the genus Centella due to overlapping features like orbicular leaves and creeping stems; for instance, Centella asiatica was originally described as Hydrocotyle asiatica by Linnaeus in 1753 before its transfer to Centella by Ignatz Urban in 1879, a reclassification driven by differences in fruit structure and inflorescence arrangement. This confusion persisted into the early 20th century, complicating identifications in herbal medicine and floristic surveys until molecular and anatomical studies reinforced the separation.

Classification

Hydrocotyle is classified within the order , family (the ginseng family), and subfamily Hydrocotyloideae. This placement reflects modern phylogenetic understanding, as the genus was historically assigned to the family (carrot or parsley family) based on morphological similarities such as umbellate inflorescences. Molecular analyses, however, have demonstrated that Hydrocotyle aligns more closely with , leading to its transfer in the early . Within , Hydrocotyle forms a distinct lineage in the subfamily Hydrocotyloideae, which was originally recognized as a subfamily of by Oskar Drude in but later dismantled due to . The genus lacks a further tribal subdivision in current classifications, though some studies treat Hydrocotyloideae as a basal group encompassing Hydrocotyle and related genera such as Trachymene. This realignment across resolved longstanding issues in umbellifer phylogeny, positioning Hydrocotyle outside the core subfamilies Apioideae and Saniculoideae. Key diagnostic traits supporting the classification of Hydrocotyle include the absence of schizocarpic fruits with vittae (oil tubes), a hallmark of many , and the presence of simple, often solitary umbels rather than compound ones typical of Apioideae. These features, combined with cremocarp fruits that are rounded or ribbed without prominent wings, distinguish the genus from other members. Phylogenetic reconstructions have reinforced this position by showing Hydrocotyle's divergence near the base of . Post-2000 molecular studies have consistently confirmed the of Hydrocotyle using nuclear ribosomal (ITS) sequences and matK gene data, which resolved its sister relationship to other Hydrocotyloideae lineages. More recent phylogenomic approaches, incorporating whole genomes, have provided even stronger support (bootstrap values of 100 and posterior probabilities of 1.00), highlighting adaptive traits in habitats while affirming the genus's cohesive evolutionary history. These analyses, drawing from extensive sampling across , underscore Hydrocotyle's stable position in without evidence of .

Diversity and selected species

The genus Hydrocotyle comprises 182 accepted species, with a cosmopolitan distribution but a strong concentration in tropical and subtropical regions. These species exhibit a range of habits, from creeping perennials to subshrubs, often adapted to wetland environments. Taxonomic revisions have influenced species counts, including the separation of genera like Centella, where species such as Centella asiatica (formerly Hydrocotyle asiatica) were historically included in Hydrocotyle. Notable species include , known as European pennywort, which is native to and Mediterranean regions, featuring small, round, peltate leaves suited to aquatic or semi-aquatic habitats. , or floating pennywort, originates from the and is invasive in parts of and , distinguished by its deeply lobed, kidney-shaped leaves and rapid vegetative spread that can form extensive floating mats up to 20 cm per day. Hydrocotyle sibthorpioides, commonly called lawn , is native to tropical and subtropical and acts as a weedy species in moist lawns, characterized by its low-growing, creeping stems and small, orbicular leaves that form dense mats. Hydrocotyle bonariensis, from tropical and subtropical , serves as an with broader, oval leaves and a subshrubby form, often valued for its functional properties in traditional uses.

Morphology

Vegetative structures

Hydrocotyle species are typically herbaceous perennials characterized by a prostrate or creeping growth form, with stems that spread horizontally and root at the nodes to form dense mats. These stems can extend up to several meters in length, often filiform and glabrous or sparsely hairy, enabling vegetative propagation in moist environments. The leaves are simple and alternately arranged, usually orbicular to reniform (kidney-shaped), measuring 1–10 cm in diameter, with palmately lobed or crenate margins that provide a distinctive rounded outline. Petioles are typically longer than the leaf blades, often exceeding 10 cm, and bear scarious, sheathing stipules at the base that enclose the stem nodes. Leaf shape varies across , with peltate attachment common in forms for enhanced and surface adaptation; for example, exhibits typical orbicular, crenate leaves with peltate bases. Root systems are fibrous and adventitious, arising primarily from the nodes to anchor the in substrates and facilitate nutrient uptake in saturated soils. These are adapted for stability in loose, moist media, supporting the mat-forming without a prominent .

Reproductive features

The inflorescences of Hydrocotyle species are simple or compound borne on axillary peduncles or scapes that arise from the nodes of creeping stems, with the peduncles varying from short to elongate depending on the . These umbels are often solitary or occasionally arranged in superposed whorls, featuring small, membranous bracts at the base and inconspicuous bracteoles on the ; each umbel contains 1 to several flowers, though the number can reach up to 10 or more in some species. The flowers are small, usually less than 5 mm in diameter, and range in color from white to greenish or occasionally purple-tinged. Hydrocotyle flowers are bisexual and radially symmetric, exhibiting the typical 5-merous structure of the family, with minute or obsolete lobes (sepals), five imbricate petals that are obtuse to acute at the tips and not incurved, five short filaments bearing elliptic anthers, and an inferior, bicarpellate containing two locules each with a single pendulous . occurs primarily through , facilitated by the sequential maturation of stigmas before anthers in the inconspicuous blooms, though insect visitation or anemophily may contribute in open habitats. The fruits are schizocarpic, splitting at maturity into two mericarps that separate from a reduced or absent carpophore; they are strongly laterally compressed, elliptic to orbicular in outline, and measure 2–5 mm in length, with thin, thread-like to prominent ribs along the and commissural surfaces but lacking vittae (oil tubes). The mericarps feature a woody endocarp and secretory cells in the wall, with that are small; dispersal is primarily hydrochorous via currents in environments, supplemented by zoochory where fruits adhere to animals. Reproduction in Hydrocotyle encompasses both sexual and modes, with sexual propagation occurring via seeds produced from the schizocarps following . is prevalent through vegetative means, as the creeping stems readily root at nodes to form new plants, and fragmentation of stems or rhizomes enables rapid clonal spread, particularly in or moist habitats. This dual strategy enhances the genus's adaptability and colonization potential in diverse environments.

Distribution and habitat

Geographic range

The genus Hydrocotyle exhibits a , with species native to all continents except . This widespread occurrence spans tropical, subtropical, and temperate zones, reflecting the adaptability of the genus across diverse landmasses including the , , , , and . The highest species diversity is concentrated in the of the , , and , which serve as primary centers of and for the genus. South , in particular, hosts a substantial portion of the approximately 170 recognized species, underscoring the Neotropics as a key region for Hydrocotyle richness. Similarly, and parts of , including , represent significant hotspots where numerous endemic taxa have evolved, contributing to the global phylogenetic of the group. In temperate and , Hydrocotyle species are widespread, with distributions augmented by both native occurrences and human-mediated introductions. For instance, H. vulgaris is indigenous to parts of , while introductions have facilitated broader establishment across these regions. A prominent example is H. ranunculoides, native to the , which was introduced to via the ornamental trade starting in the and has since naturalized in waterways throughout countries such as the , , , and .

Environmental preferences

Hydrocotyle species predominantly inhabit environments, favoring shallow waters, marshes, and edges of where moisture levels remain consistently high. These thrive in areas with standing or slow-flowing water, often forming dense mats on the surface or along saturated banks. Some species, such as , exhibit strong adaptability to varying and temperature regimes within these habitats, enabling occupation of diverse aquatic settings from mesotrophic pools to eutrophic lakes. Regarding soil and water tolerances, Hydrocotyle prefers neutral to acidic levels ranging from 5.5 to 7.5, with extending to very acidic conditions in some cases. They require high moisture content in nutrient-rich sediments, such as loamy or clay soils that retain water effectively, and demonstrate resilience to periodic flooding and submergence up to complete coverage. Additionally, these plants accommodate low light conditions, particularly in shaded margins, while benefiting from nutrient availability in eutrophic waters. The genus exhibits broad climate adaptability, spanning tropical, subtropical, and temperate zones, with certain species occurring in coastal mangroves or high-elevation alpine bogs up to 3000 m. For instance, grows in stream banks and grassy places at altitudes reaching 3000 m in tropical and subtropical regions. Microhabitat variations are notable across the genus; floating forms, like those of , dominate in slow-moving rivers and ditches, whereas more terrestrial variants, such as , persist in damp grasslands and boggy meadows with persistent soil saturation.

Ecology

Biological interactions

Hydrocotyle species engage in various biotic interactions within their wetland and aquatic habitats, including herbivory, pollination, microbial symbioses, and interspecific competition. These interactions contribute to their ecological roles as foundational components of food webs. Leaves and stems of Hydrocotyle are consumed by a range of herbivorous insects, particularly in native ranges. For instance, larvae of moths such as Synclita obliteralis and Enigmogramma basigera feed on Hydrocotyle ranunculoides, causing significant defoliation, while weevils like Bagous lunatoides and Listroderes costirostris damage roots and stems. Grasshoppers, including Gymnoscirtetes pusillus and Paroxya atlantica, also graze on foliage of species like H. umbellata in the southern United States. Hydrocotyle plants produce flavonoids, secondary metabolites that function as chemical defenses against herbivores by deterring feeding and inhibiting insect development in many Apiaceae relatives. Pollination in Hydrocotyle primarily occurs through entomophily, with small insects serving as vectors, supplemented by self-pollination in sparse populations. Flowers of H. vulgaris and related species are visited by small flies and bees, which transfer pollen among the tiny, clustered umbels. In isolated or low-density settings, self-pollination predominates due to the hermaphroditic nature of the flowers, enabling reproduction without external agents and supporting persistence in fragmented habitats. The umbel structure, with its simple reproductive features, facilitates both mechanisms efficiently. Hydrocotyle forms symbiotic associations with aquatic microbes, particularly in the , enhancing uptake in -limited . such as those in Nitrospiraceae and Rhodobacteraceae facilitate nitrogen cycling, including fixation, , and , which boosts and removal by up to 95% in eutrophic conditions for H. vulgaris. These microbes respond to exudates like indoleacetic acid, promoting bacterial abundance and aiding overall acquisition for the host. As a primary producer, Hydrocotyle contributes substantially to wetland food webs by providing that supports detritivores and herbivores, channeling energy from to higher trophic levels. In competitive interactions, Hydrocotyle outcompetes in eutrophic waters through physical shading and . Dense floating mats of H. ranunculoides reduce light penetration, suppressing algal growth, while allelochemicals released by intact plants inhibit Chlorella vulgaris biomass by significant margins in controlled assays. These effects target more effectively than cyanobacteria like Synechocystis sp., altering microbial community dynamics and favoring Hydrocotyle dominance. compounds also impact nearby vascular plants, reducing establishment through growth suppression.

Invasive status and impacts

Several species within the genus Hydrocotyle exhibit invasive potential outside their native ranges, with H. ranunculoides (floating pennywort) being the most problematic in . This species was added to the European Union's list of invasive alien species of Union concern in 2016 under Regulation (EU) No 1143/2014, imposing restrictions on its trade, transport, and release to prevent further spread. Native to the , H. ranunculoides has established dense populations in waterways across western and central , forming expansive floating mats that can cover entire river surfaces and block . The ecological impacts of H. ranunculoides are significant, primarily through and habitat alteration. These mats smother submerged and emergent native , reducing by limiting light penetration and oxygen availability in aquatic ecosystems. Additionally, the plant modifies river by increasing water resistance and promoting sediment accumulation, which can exacerbate flooding risks and degrade . In the , management costs for H. ranunculoides alone exceed £25 million annually, encompassing mechanical clearance, applications, and monitoring efforts across affected waterways. Spread of H. ranunculoides occurs primarily through human-mediated pathways and natural dispersal. It was initially introduced to via the aquarium trade as an ornamental , with fragments discarded into waterways facilitating establishment. Further dissemination happens via waterfowl transporting seeds or fragments on their feathers and feet, as well as downstream flow in rivers. The species' rapid vegetative growth, reaching up to 20 cm per day under favorable conditions, enables quick colonization and regeneration from small fragments. Management strategies for H. ranunculoides emphasize integrated approaches to minimize reinvasion. removal, such as hand-pulling or cutting for small infestations, is effective but labor-intensive and requires follow-up to prevent regrowth from fragments. control using herbicides like has shown variable success, often requiring repeated applications at rates of 2-3 kg per , though resistance has been observed in some populations. Biological control efforts, including the release of specialist herbivores like the Listronotus elongatus from , are under active research and initial field trials since 2021, aiming for sustainable long-term suppression.

Uses and cultivation

Medicinal and traditional applications

Hydrocotyle vulgaris has been used in for treating conditions such as eczema and ulcers, as well as for its properties. It is applied topically to promote healing and internally as an alterative tonic. In traditional South American medicine, H. bonariensis is employed for treating , , and as an source. Pharmacological studies support its and activities, attributed to and phenolic compounds that scavenge free radicals and inhibit . These properties are observed in hydroalcoholic extracts, teas, or gels, though clinical data remain limited. Note that many historical references to medicinal "Hydrocotyle" actually pertain to (formerly H. asiatica), which is now classified in a separate and features prominent triterpenoids like asiaticoside for . Hydrocotyle lack extensive pharmaceutical approval and are used primarily in traditional contexts, with caution advised due to sparse long-term safety data.

Ornamental and other uses

Several of Hydrocotyle, particularly aquatic ones such as H. verticillata (whorled ), are employed in ornamental gardening for their ability to form dense ground covers in ponds, gardens, and aquariums. These plants thrive in shallow , creating lush, creeping mats that enhance aesthetic appeal and provide for small aquatic organisms. In , certain Hydrocotyle have been introduced as ornamental aquatic plants, contributing to garden designs and later becoming naturalized. Cultivation of Hydrocotyle for ornamental purposes is straightforward, with easy achieved by rooting cuttings or dividing rhizomes in consistently wet soils or shallow . These plants prefer full sun to partial shade and are in USDA zones 5-11, allowing overwintering in with sufficient depth for . Beyond decoration, Hydrocotyle species serve practical roles, including along pond banks and in erosion-prone areas, where their fibrous help bind . In some regions, they are used as for , though analyses indicate relatively low , with crude protein around 12.5% on a basis compared to higher-quality forages. The genus's popularity in the international aquarium plant trade has facilitated unintentional invasions, prompting EU regulations such as the 2016 Implementing (EU) 1143/2014, which bans trade in like H. ranunculoides to curb further spread.

Evolutionary history

Fossil record

The fossil record of the genus Hydrocotyle is limited and fragmentary, reflecting its primarily herbaceous and preference for environments that do not always favor long-term preservation. The earliest confirmed macrofossils include leaf impressions attributed to Hydrocotyle sp. from lower Eocene deposits. Additional evidence consists of a single fruit specimen of Hydrocotyle sp. extracted from borehole samples in the Middle freshwater deposits of the Basin, located in the West Carpathians of southern . Dated to approximately 15–13 million years ago, this provides direct evidence of the 's presence in Eurasian paleowetlands during the Miocene. Preservation of Hydrocotyle fossils predominantly occurs in lacustrine sediments, such as fine-grained shales and marls from systems, where delicate fruits and leaves could be embedded and mineralized under low-oxygen conditions. This mode of fossilization highlights the genus's association with stable, freshwater ecosystems throughout its history, from Eocene lake margins to basins. No significant new discoveries have been reported since 2010, and the record remains incomplete, particularly lacking well-documented fossils from tropical regions where much of the modern diversity resides.

Phylogenetic context

Hydrocotyle likely diverged from other lineages during the to early , approximately 67–72 million years ago, originating in environments associated with the breakup of . This early aligns with the broader radiation of , where ancestral adapted to tropical and subtropical moist habitats across southern continents. Miocene fossils further indicate the persistence of Hydrocotyle-like forms in deposits, supporting a long evolutionary history in such ecosystems. Molecular phylogenetic studies using genomes have confirmed Hydrocotyle's basal position within , forming a monophyletic sister to the rest of the family. It shares close relationships with genera such as and Trachymene, based on analyses of complete plastomes that resolve Hydrocotyloideae as an early-diverging now placed in . These studies highlight Hydrocotyle's distinct evolutionary trajectory, with positive selection on genes like atpE and psbB potentially linked to environmental adaptations. Over time, Hydrocotyle underwent a shift toward or semi- habits following the , coinciding with the diversification of angiosperms in niches. This transition, evidenced by morphological and genomic traits in basal lineages, allowed exploitation of flooded environments during the warming periods. As one of the few genera in , its ancient origins underscore the vulnerability of such specialists to contemporary , including altered and habitat loss.