Cryptocoryne
Cryptocoryne is a genus of approximately 60 to 70 species of aquatic and amphibious perennial herbs in the family Araceae, commonly known as water trumpets due to the shape of their inflorescences.[1] These plants are characterized by rosette-forming leaves that emerge from a short rhizome, with blades varying from linear to ovate or elliptic, often 5–30 cm long and green to reddish-brown in color.[2] The inflorescence consists of a spadix enclosed within a tubular to trumpet-shaped spathe, typically emerging above water during low-water periods for pollination.[3] Taxonomically, Cryptocoryne belongs to the subfamily Schismatoglottidoideae and tribe Cryptocoryneae within the Araceae, an order Alismatales of monocotyledonous flowering plants.[4] The genus was first described by Friedrich Ernst Ludwig von Fischer ex Wydler in 1830.[5] Species diversity is highest in Southeast Asia, with the native range extending from India, Sri Lanka, and Nepal through mainland Southeast Asia, the Malay Peninsula, Indonesia (including Borneo, Sumatra, and Sulawesi), the Philippines, to New Guinea.[5][6] A few species have been introduced outside their native range, such as in Texas, USA.[5] These plants inhabit a variety of freshwater environments, including slow-flowing streams, rivers, swamps, and peatlands in tropical and subtropical regions, often in shaded, lowland to mid-elevation areas.[1] They exhibit morphological plasticity, with submerged forms having narrower, translucent leaves and emersed forms displaying broader, more rigid foliage adapted to air exposure.[3] Cryptocoryne species are popular in the aquarium hobby for their ornamental value and ease of cultivation in submerged conditions, though many face threats from habitat loss and overcollection in the wild.[1]Description
Morphology
Cryptocoryne plants exhibit a rosette-forming habit as perennial aquatic or semi-aquatic herbs, emerging from a short, creeping rhizome that functions in both storage and propagation. True stems are absent, with leaves and roots arising directly from the rhizome. The root system consists of adventitious roots that extend into the substrate, facilitating nutrient and anchorage in sediment-rich aquatic environments, and often features laticifers for latex production.[7][8] Leaves are petiolate and arranged in dense rosettes, with blades typically lanceolate to ovate, ranging from 5 to 50 cm in length depending on species and conditions. Coloration varies from vibrant green to reddish-brown, influenced by light exposure and pigmentation such as anthocyanins, while texture spans smooth surfaces to undulate margins. Submerged leaves tend to be narrower, more linear, and translucent with reduced venation compared to emersed forms, which are broader, thicker, and more intensely pigmented to optimize photosynthesis in aerial versus aquatic settings. Petioles are sheathing at the base and contain vascular bundles surrounded by sclerenchyma for support.[9][7][8] The inflorescence is a characteristic spadix enclosed within a spathe, typical of the Araceae family, where female flowers occupy the basal portion and male flowers the apical region, separated by sterile synandria or staminodes. The spathe varies from tubular to flask-shaped, measuring 3-20 cm in length, with a constricted throat and flared limb; its inner surface often features papillose or colliculate textures for pollination facilitation. Externally, the spathe is smooth to ribbed, aiding in camouflage among foliage.[7][10] Key adaptations include extensive aerenchyma tissue—schizogenous air spaces—in the leaves, petioles, rhizome, and roots, enabling internal oxygen transport via diffusion from aerial parts to submerged tissues in hypoxic waters. This lysigenous or schizogenous formation of lacunae enhances buoyancy and gas exchange, critical for survival in stagnant or flooded habitats.[8][11]Reproduction
Cryptocoryne species exhibit both sexual and asexual reproduction, with the latter being the predominant mode in submerged habitats due to the challenges of flowering underwater. Sexual reproduction occurs primarily in emersed conditions, where inflorescences emerge above the water surface as a spathe enclosing a spadix with unisexual flowers. Most species are monoecious, bearing female flowers at the base of the spadix and male flowers toward the apex, though some exhibit dioecious tendencies or sex lability influenced by environmental factors.[12][13] Pollination is achieved mainly through entomophily, with small insects such as phorid flies (Phoridae), chloropid flies (Chloropidae), and ephydrid flies (Ephydridae) serving as primary vectors.[14] These pollinators are attracted by odors from the spathe—ranging from sweet scents to a "rotten fish" aroma—and enter the tubular "kettle" portion of the spathe, where they become temporarily trapped on sticky surfaces. After 1-3 days, they escape carrying pollen on their bodies to fertilize female flowers in subsequent visits. Successful pollination leads to fruit development, forming berry-like structures that contain multiple seeds, typically numbering from a few dozen to over 100 per fruit depending on the species. The peduncle elongates post-fertilization, and the fruit eventually dehisces at maturity, releasing seeds into the water.[12][13][15] Flowering is triggered by emersed conditions, often during seasonal low water levels or dry periods that expose plants, along with hormonal cues like gibberellins; submerged flowering is rare, occurring in fewer than 10% of species and usually under stressed or atypical conditions. In some species, vivipary occurs, with plantlets developing directly on the inflorescence before seed dispersal, enhancing survival in fluctuating wetland environments. Seeds germinate rapidly upon release, typically within a week, requiring moist substrates, temperatures between 20-30°C, and exposure to moderate light for optimal embryo development and radicle emergence.[12][13] Asexual reproduction predominates in natural populations, enabling rapid colonization and persistence in stable aquatic habitats. It occurs via rhizome division, where segments as small as 2 mm can root and form new plants, and through stolons or runners that produce daughter rosettes at nodes. Adventitious plantlets may also arise from leaf bases or damaged tissues, particularly in fragmented populations. This vegetative strategy is highly effective for hybrids and polyploids, which often show reduced fertility, allowing clonal lineages to dominate local stands.[13][16]Taxonomy
Taxonomic history
The genus Cryptocoryne was established in 1830 by Friedrich Ernst Ludwig von Fischer ex Wydler, with C. spiralis (originally described as Arum spirale by Anders Jahan Retzius in 1779) designated as the type species.[17] Early 19th-century botanical explorations focused on collections from India and Sri Lanka, where species such as C. spiralis from rice fields and C. walkeri from streams were documented, laying the foundation for recognizing the genus's aquatic habits in tropical Asia.[18] Significant advancements occurred in the mid-20th century through the work of H.C.D. de Wit, who published key revisions between 1958 and 1971, culminating in his 1990 monograph that clarified morphological variations and reduced synonymy across known taxa.[19] In the 1980s, Niels Jacobsen contributed detailed monographs, particularly on Bornean diversity, integrating cytological data to refine species boundaries.[20] Since the 1990s, Jan D. Bastmeijer has driven ongoing taxonomic efforts, documenting over 1,700 accessions and recognizing 105 taxa (including species and varieties) as of 2025 through his comprehensive online database and publications.[21] Taxonomic progress has been hindered by the genus's extreme morphological plasticity, which causes significant variation in leaf shape, color, and size under different environmental conditions, often resulting in extensive synonymy and misidentification.[18] Prior to 2000, estimates placed the number of species at 50–60, but enhanced field collections and analyses have expanded this to over 60 species plus numerous varieties.[22] Key milestones include 20th-century expeditions that unveiled Southeast Asian diversity, particularly in Borneo and the Philippines, expanding known distributions beyond initial Indian and Sri Lankan sites.[20] Post-2010 discoveries, such as C. joshanii from Basilan Island in 2018 and C. paglaterasiana from Zamboanga del Norte in 2022, highlight continued exploration in remote habitats.[23][24] Classification has evolved from placement within subfamily Aroideae (tribe Areae, subtribe Cryptocoryninae) to the distinct tribe Cryptocoryneae, supported by molecular phylogenetic studies revealing unique evolutionary lineages.[25]Etymology
The genus Cryptocoryne was established by the German botanist Friedrich Ernst Ludwig von Fischer ex Wydler in 1830 to accommodate aquatic species previously classified under other genera in the Araceae family.[17] The name is derived from the Greek words kryptos (hidden) and koryne (club), alluding to the spadix—a club-shaped flowering structure—that remains concealed within the protective spathe during anthesis.[26] An alternative etymological interpretation connects the name to the cryptic, often subterranean or submerged inflorescences of these plants, which are difficult to observe in their natural aquatic habitats.[27] This reflects the genus's adaptation to environments where reproductive structures are typically hidden from view, emphasizing the "concealed" aspect in both morphological and ecological contexts. Common names for Cryptocoryne species include "water trumpet," which describes the flared, trumpet-like form of the spathe in emergent forms. In the aquarium trade, these plants have influenced popular nomenclature, with terms like "crypts" becoming shorthand among hobbyists, though occasional mislabeling occurs with unrelated genera such as Anubias. Species epithets further illustrate descriptive naming practices; for example, C. ciliata derives from the Latin ciliatus (fringed or eyelash-like), referring to the ciliate margins on its leaves, while C. wendtii honors Albert Wendt, a prominent Dutch aquarium enthusiast and author who contributed to early documentation of Sri Lankan aroids.[28] Such conventions in Araceae nomenclature, rooted in classical languages to highlight morphological traits, have shaped both scientific and hobbyist terminology for the genus.[29]Phylogenetic relationships
Cryptocoryne is placed within the subfamily Aroideae of the family Araceae, specifically in the tribe Cryptocoryneae, which also includes the closely related genus Lagenandra as its sister taxon.[30] This tribal assignment is supported by both morphological and molecular data, with Lagenandra occasionally considered for merger into Cryptocoryne due to their shared aquatic adaptations and overlapping distributions in tropical Asia.[31] The monophyly of Cryptocoryne has been confirmed through analyses of plastid genes such as rbcL and nuclear markers, establishing it as a distinct lineage within Aroideae.[32] Molecular phylogenies from the 2000s, including rbcL-based studies, have positioned Cryptocoryne near the base of the Araceae radiation, reflecting an ancient divergence estimated at approximately 50 million years ago during the Eocene, when early aroid lineages adapted to diverse freshwater habitats.[33] This basal placement underscores the genus's role in the family's transition from terrestrial to aquatic environments, with the tribe Cryptocoryneae emerging as part of an early diversification event in Aroideae around 40-50 million years ago.[30] Key synapomorphies distinguishing Cryptocoryne from other aroids include its fully submerged habit, unisexual flowers enclosed in a twisted, kettle-like spathe adapted for fly pollination, and indehiscent berry fruits that facilitate underwater seed dispersal.[34] Phylogenetically, Cryptocoryne serves as an outgroup to genera like Anubias (tribe Anubieae) and Bucephalandra (tribe Schismatoglottideae), with the latter showing particularly close ties as sister to Cryptocoryneae in broader Aroideae phylogenies.[35] Debates persist regarding the delimitation of Cryptocoryneae versus a expanded Schismatoglottideae, as molecular data indicate non-monophyly in Schismatoglottis without inclusion of Cryptocoryne, prompting calls for tribal revision based on shared rheophytic traits and spathe morphology.[36] Recent genomic studies in the 2020s, including chromosome-level assemblies of species like Cryptocoryne crispatula, have resolved previously ambiguous hybrids and varieties as distinct evolutionary lineages through whole-genome sequencing and ortholog analysis, highlighting gene family expansions linked to aquatic adaptation and confirming the monophyly of natural hybrid swarms.[30][37]Distribution and ecology
Geographic range
The genus Cryptocoryne is native to tropical Asia, with its natural distribution extending from India and Sri Lanka eastward to New Guinea, encompassing a core region in Southeast Asia that includes Malaysia, Indonesia, the Philippines, Thailand, and Vietnam.[38][2] In India, species such as C. spiralis occur in regions like Kerala and Karnataka, often along riverine habitats, while Sri Lanka supports a high level of endemism with around 10 species, including C. parva and C. wendtii.[39][21][40] Isolated populations are also documented in southern China, particularly on Hainan Island, where species like C. crispatula var. tonkinensis inhabit coastal streams.[41][42] Diversity is highest in Peninsular Malaysia, followed by Borneo with more than 20 species across its peat swamps and rivers, and Sumatra with at least 15 known taxa, including recent additions like C. schulzei and C. minima.[43][44] Endemism patterns are pronounced on islands, with many species restricted to specific archipelagos; for instance, the Philippines host 11 endemic taxa, such as C. aponogetifolia, largely confined to Mindanao and Palawan.[45] Distributions often align with major river basins, including the Ganges in northern India (C. spiralis var. spiralis) and the Mekong in Thailand, Laos, Cambodia, and Vietnam, where species like C. mekongensis thrive in floodplain habitats.[46][47] Recent explorations in the 2020s have extended known ranges, particularly in the Philippines, with new populations and species documented in Mindanao, such as C. zamboangaensis and C. paglaterasiana in Zamboanga del Norte streams, highlighting ongoing discoveries in previously understudied island endemics.[48][49] These findings underscore the genus's concentration in Southeast Asian hotspots while noting occasional human-mediated introductions, such as potential escapes in northern Australia, though naturalization remains limited outside the native range.[21]Habitat preferences
Cryptocoryne species exhibit predominantly aquatic to semi-aquatic habits, thriving in submerged conditions within slow-flowing streams, rivers, and marshes across tropical Asia. Many populations remain fully submerged year-round in shaded, lowland forest waterways, while others transition to emersed growth on riverbanks or marsh edges during dry seasons when water levels recede. This versatility allows them to occupy dynamic environments influenced by seasonal monsoons and flooding cycles.[43] These plants tolerate a broad range of water parameters reflective of their diverse native ecosystems, with pH levels spanning from very acidic blackwater conditions (as low as pH 5 in peat-influenced streams) to alkaline hard water (up to pH 8.4 in limestone springs). Water hardness varies similarly, from soft and acidic in peat swamps of Borneo and the Malay Peninsula to high carbonate hardness (12–13 dH) in karst regions. Temperatures in their natural habitats typically range from 20–32°C, corresponding to the tropical climate, and Cryptocoryne demonstrate remarkable tolerance for low light levels and even stagnant or low-oxygen conditions in shaded, slow-moving waters.[43][50] Substrate preferences include nutrient-rich sandy, muddy, or gravelly bottoms in streams and rivers, as well as rocky or loam-based sediments derived from eroded limestone in karst landscapes, such as those in Borneo's cave systems and spring-fed brooks. In Borneo, for instance, species like Cryptocoryne noritoi anchor in limestone-derived loam along pond banks. These plants often co-occur with other aquatic vegetation, including submerged grasses, ferns like Ceratopteris thalictroides, and species such as Blyxa or Hygrophila in stream margins; some, like C. spiralis, even inhabit anthropogenically modified areas such as rice paddies in India and Bangladesh, while others appear in brackish tidal zones near mangroves.[43][50][51] Key adaptations enable Cryptocoryne to persist in fluctuating habitats, including leaf dimorphism where submersed forms produce narrower, more flexible leaves suited to underwater flow, contrasting with broader, terrestrial-like leaves in emersed states. This phenotypic plasticity, observed in species like those in the C. crispatula group, facilitates survival during seasonal flooding and exposure. Additionally, elongated peduncles in some species allow flowering above varying water levels, while thick leaf textures in mud-associated forms provide protection against sediment burial. These traits underscore their resilience to periodic inundation and emergence in tropical wetland niches.[43][52]Conservation status
Approximately 56% of the 113 assessed Cryptocoryne taxa are classified as threatened with extinction under IUCN Red List criteria, including 22 Critically Endangered (some possibly extinct), 24 Endangered, and 17 Vulnerable.[53] Of the 98 species and varieties evaluated by the IUCN Species Survival Commission Freshwater Plant Specialist Group, a similar proportion faces elevated extinction risk.[54] Primary threats to Cryptocoryne species include habitat destruction from deforestation, agricultural expansion (such as oil palm plantations), mining, and urbanization, alongside hydrological alterations like dam construction and water pollution.[53] Overcollection for the international aquarium trade exacerbates declines, with illegal poaching particularly severe in the Philippines and Indonesia, where commercial harvesting targets rare endemics.[53] For instance, Cryptocoryne annamica in central Vietnam is vulnerable due to logging and habitat disturbance at known sites, though recent reassessments list it as Near Threatened following improved data.[55][56] Similarly, the newly described Cryptocoryne paglaterasiana from the Philippines was immediately assessed as Endangered owing to quarrying, slash-and-burn practices, and collection pressures. Many populations have declined substantially, with species like Cryptocoryne thwaitesii in Sri Lanka showing ongoing reductions over the past 40 years from habitat loss and overcollection, and Cryptocoryne erwinii in Borneo dropping to around 500 individuals from formerly larger stands.[53] Range contractions of 30–50% in the last two decades are inferred for several taxa based on habitat conversion rates in Southeast Asian wetlands.[53] Conservation efforts are guided by the Water-Trumpet (Cryptocoryne): Conservation Action Plan 2023–2033, developed by the IUCN SSC Freshwater Plant Specialist Group with contributions from experts including Jan D. Bastmeijer, Niels Jacobsen, and Mark A. K. Naive.[53] Ex situ propagation occurs in botanic gardens, such as the Singapore Botanic Gardens, where tissue culture supports recovery for species like Cryptocoryne bogneri.[53] In situ protection includes designated areas in Malaysia, such as Tasek Bera Forest Reserve for hybrids like Cryptocoryne × purpurea, and surveys to monitor populations.[53] No Cryptocoryne species are currently listed under CITES Appendices.[57] Citizen science plays a vital role, with platforms like iNaturalist enabling discoveries of new species such as C. paglaterasiana and C. zamboangaensis in the Philippines, which inform rapid IUCN assessments and highlight undocumented threats.[48][45]Cultivation and uses
Aquarium cultivation
Cryptocoryne species are well-suited to aquarium cultivation due to their adaptability and low-maintenance nature, making them ideal for both novice and experienced aquarists. They generally require low to medium light intensities, ranging from 20 to 50 PAR, with a photoperiod of 8 to 12 hours daily to promote healthy growth without encouraging algae proliferation.[58][59] CO2 supplementation is optional and beneficial at low levels (6-14 mg/L) to enhance photosynthesis, though many thrive in non-injected setups using liquid carbon alternatives.[60][61] Optimal water parameters closely mirror their natural tolerances, with a pH of 6.0 to 7.5, temperatures between 22°C and 28°C, and soft to medium hardness (3-8 dGH) to support root health and nutrient uptake.[62] Stable conditions are essential, as fluctuations can stress the plants, though most species exhibit resilience in community tanks. For substrate, a 2-5 cm layer of nutrient-rich gravel or sand provides anchorage and access to essential minerals; supplementation with root tabs delivering iron and potassium is recommended to prevent deficiencies and sustain long-term vitality.[63][59] In aquarium setups, Cryptocoryne plants are typically positioned in the foreground or midground to create natural groupings, where they coexist harmoniously with community fish and invertebrates such as shrimp. Growth is characteristically slow to medium, with plants producing new leaves at a rate of approximately one to two per month under favorable conditions, eventually forming dense rosettes 8-15 cm wide and up to 30 cm tall.[60][61] Varietal care varies; hardy species like C. wendtii tolerate harder water and broader parameter ranges, while more delicate ones such as C. spiralis demand softer water and consistent stability for optimal development.[60][64] Some species can also be cultivated emersed in paludariums with high humidity to facilitate flowering, offering an alternative to fully submerged growth.[59] Commercially, Cryptocoryne plants are primarily sourced from aquaculture farms in Southeast Asia, where high demand drives cultivation in nutrient-enriched substrates like river sand. Sustainability efforts, particularly in regions like Sri Lanka, incorporate micropropagation techniques to produce disease-free plants and reduce pressure on wild populations.[65][66]Propagation
Cryptocoryne plants are primarily propagated asexually through division of rhizomes or separation of runners, methods that are straightforward and effective in cultivation settings. Rhizome division involves carefully separating mature clumps into smaller sections, each with at least one growth point and roots, typically performed during repotting to minimize stress; this approach ensures high transplant success when root integrity is maintained.[67] Runner separation exploits the stolons produced by many species, such as Cryptocoryne wendtii, where daughter plants form along the runners and can be clipped and replanted directly into substrate for independent growth.[67][68] These vegetative techniques allow for rapid clonal multiplication without genetic variation, making them ideal for aquarium hobbyists and commercial producers.[13] Sexual propagation of Cryptocoryne is uncommon in aquarium environments due to the plants' preference for submerged growth, which suppresses flowering, but it can occur when plants are grown emersed. In such cases, inflorescences (spathes) emerge above water, enabling hand-pollination between male and female flowers within the same or different spathes to produce seeds; these seeds are then sown in sterile, moist media under controlled conditions.[68] Germination requires a humid environment with moderate light, though success is limited by low seed viability and the labor-intensive process. This method introduces genetic diversity but is rarely pursued outside research or conservation efforts. Tissue culture, or micropropagation, provides an advanced asexual approach particularly suited for rare or virus-free stock production, starting from explants like shoot tips or meristems. Protocols often use Murashige-Skoog medium supplemented with cytokinins such as benzylaminopurine (BAP) at 4-6 mg/L and auxins like naphthaleneacetic acid (NAA) at 0.1-0.5 mg/L to induce shoot proliferation, yielding 25-28 shoots per explant after 4 weeks under 25°C and a 12-hour photoperiod.[69] Rooting follows on NAA-free media with 0.4 mg/L BAP, achieving 100% acclimatization survival in substrates like aqua soil.[69] For species like Cryptocoryne wendtii, establishment from rhizome tips yields 62% contamination-free cultures, with full plantlet production in 8 weeks.[70] This technique is commercially valuable for scaling up production of uniform plants. Propagation timing aligns with spring for emersed or natural cycles to leverage warmer temperatures and growth spurts, though aquarium conditions allow year-round efforts; success hinges on factors like intact roots during division (enhancing anchoring and nutrient uptake) and the use of rooting hormones such as indole-3-butyric acid (IBA) at 0.5 mg/L to promote adventitious roots, which may take 2-4 weeks to develop fully.[67][71] Challenges include slow initial rooting in low-nutrient substrates, mitigated by stable humidity and light levels around 50 µmol m⁻² s⁻¹.[69] In conservation contexts, propagation techniques like micropropagation support ex situ programs for endangered taxa, such as Cryptocoryne crispatula var. yunnanensis, where optimized protocols produce 23.75 shoots per explant using thidiazuron (TDZ) and NAA, enabling habitat restoration and reducing wild harvesting pressures.[71] Similarly, protocols for Sri Lankan endemics like Cryptocoryne beckettii and C. bogneri facilitate botanic garden initiatives, producing disease-free stock with up to 90% survival post-acclimatization.[72] These methods preserve genetic homogeneity while bolstering populations of critically endangered species.[70]Common issues
One of the most frequent challenges in cultivating Cryptocoryne species in aquariums is "crypt melt," a condition where leaves dissolve or decay during the initial acclimation period, typically lasting 1-3 months after introduction. This phenomenon occurs due to environmental stress from factors such as abrupt changes in lighting, water chemistry, or relocation from emersed to submersed growth, prompting the plant to shed old foliage and regrow submersed-adapted leaves from the root system.[73][74][75] Nutrient deficiencies can also hinder growth, with iron deficiency being particularly common, manifesting as yellowing (chlorosis) between leaf veins on younger foliage due to impaired chlorophyll production. High light levels without balanced fertilization may lead to algae overgrowth on Cryptocoryne leaves, competing for resources and exacerbating stunted development.[76][77] Pests and diseases pose additional risks, including grazing by snails that chew irregular holes in leaves, and bacterial rot in areas of low water flow where debris accumulates, causing soft, slimy tissue breakdown. Fungal infections are more prevalent in water temperatures below 20°C, leading to white, cottony growths on roots or crowns.[78][79] Environmental mismatches, such as sudden pH fluctuations or exposure to trace copper from medications or tap water, can trigger melting by disrupting cellular processes in sensitive species.[80][81] To mitigate these issues, quarantine new plants for 2-4 weeks, introduce gradual parameter changes, and shade them initially to reduce light stress while maintaining stable conditions aligned with their preferences for moderate lighting and soft, acidic water.[74][73]Species
Accepted species
The genus Cryptocoryne currently includes over 60 accepted species and more than 105 taxa when varieties are considered, based on 2025 assessments from Kew's Plants of the World Online and the taxonomic database maintained by Jan D. Bastmeijer.[21] This count reflects ongoing revisions, with a high rate of synonymy; for instance, the former species C. willisii is now treated as a variety of C. walkeri.[82] Approximately 72% of species are endemic to Southeast Asia.[83] Selected accepted species are listed alphabetically below in a table, including authorities, years of original publication, and brief notes on distribution. This inventory focuses on species-level taxa, with varieties noted where they represent distinct accepted infraspecific entities. Recent additions include C. zamboangensis Naive & Maguad (2023) from the Philippines (Zamboanga del Norte, endangered).[84]| Species | Authority and Year | Distribution |
|---|---|---|
| C. affinis | Hook.f. (1893) | Peninsular Malaysia, Sumatra, Borneo |
| C. alba | De Wit (1958) | Sri Lanka |
| C. albida | R.Parker (1937) | Southern India, northern Indochina |
| C. aponogetifolia | Merr. (1919) | Philippines (Luzon) |
| C. aura | Wongso & Ipor (2016) | Borneo (West Kalimantan) |
| C. auriculata | Engl. (1879) | Western India |
| C. balansae | Lepr. ex Mott. (1884) | Vietnam, Laos, Thailand |
| C. bangkaensis | Bastm. (2007) | Sumatra (Bangka Island) |
| C. bastmeijeri | Wongso (2017) | Borneo (Kalimantan) |
| C. beckettii | Thwaites (1859) | Sri Lanka |
| C. bullosa | Engl. (1920) | Southern India |
| C. burttii | N.Jacobsen (1982) | Peninsular Malaysia |
| C. ciliata | (Roxb.) Schott (1830) | India, Sri Lanka (type species of the genus) |
| C. cognata | Schott (1860) | India |
| C. commutata | Schott (1860) | India |
| C. cordata | Griff. (1845) | Peninsular Malaysia, Singapore |
| C. crispatula | Engl. (1899) | Thailand, Peninsular Malaysia |
| C. diderici | De Wit (1960) | Borneo |
| C. discolor | Engl. (1898) | Borneo |
| C. elliptica | Hook.f. (1893) | Peninsular Malaysia, Sumatra |
| C. erwinii | Wongso & Ipor (2017) | Borneo (Kalimantan) |
| C. esenbeckii | G.Don (1839) | India |
| C. evansii | (Solms) Engler (1912) | Sri Lanka |
| C. forbesii | Bogner (1979) | Borneo |
| C. fornsei | Bogner (2010) | Borneo (Sarawak) |
| C. fusca | de Wit (1958) | Borneo |
| C. gasseri | N.Jacobsen (1979) | Borneo |
| C. grabowskii | Engl. (1899) | Borneo |
| C. griffithii | Schott (1851) | Peninsular Malaysia |
| C. hudoroi | A.F.Blume ex De Wit (1958) | Sri Lanka |
| C. isae | Wongso (2017) | Borneo (Kalimantan) |
| C. jacobsenii | De Wit (1983) | Borneo (Sabah) |
| C. keei | N.Jacobsen (1981) | Borneo |
| C. korupensis | Bogner (2008) | Borneo (Sabah) |
| C. lacustris | Ridl. (1905) | Peninsular Malaysia |
| C. langesii | Ridl. (1905) | Peninsular Malaysia |
| C. longicauda | Lepr. ex Engl. (1920) | Thailand |
| C. lucens | De Wit (1993) | Borneo (luminous leaves in submersed forms) |
| C. lusitanica | Thwaites (1864) | Sri Lanka |
| C. mabaensis | De Wit (1990) | Borneo |
| C. minima | Ridl. (1911) | Peninsular Malaysia |
| C. nurii | Blume ex Schott (1857) | Peninsular Malaysia |
| C. paglaterasiana | Naive (2022) | Philippines (endangered, critically so) |
| C. parva | De Wit (1993) | Borneo |
| C. pontederiifolia | Schott (1857) | India |
| C. purpurea | Ridl. (1889) | Peninsular Malaysia |
| C. regina | Wongso & Ipor (2017) | Borneo (Kalimantan) |
| C. retrospiralis | (Roxb.) Kunth (1817) | India, Bangladesh |
| C. sahalii | Wongso & Ipor (2017) | Borneo (Kalimantan) |
| C. schulzei | Bogner & Jacobsen (1991) | Borneo |
| C. scutata | Engl. (1899) | Borneo |
| C. siamensis | Gagnep. (1941) | Thailand |
| C. sivadasanii | Bogner (2007) | Southern India |
| C. spiralis | (L.) Schott ex K.D.Koenig (1822) | India, Pakistan |
| C. striolata | Engl. (1899) | Borneo |
| C. thwaitesii | Schott (1857) | Sri Lanka |
| C. tirtadinatae | Wongso (2020) | Borneo (West Kalimantan) |
| C. undulata | R.Br. (1814) | India, widespread with emersed forms |
| C. uenoi | Iwasaki (1935) | Taiwan |
| C. verrucosa | Wongso & Asih (2022) | Borneo (West Kalimantan) |
| C. walkeri | Schott (1857) | Sri Lanka |
| C. wendtii | De Wit (1956) | Sri Lanka |
| C. yujii | Bastm. (2008) | Borneo |
| C. zaidiana | Ipor & Tawan (2008) | Borneo (Sarawak) |
| C. zamboangensis | Naive & Maguad (2023) | Philippines (Zamboanga del Norte, endangered) |
| C. esquerionii | Naive (2023) | Philippines (Mindanao, endangered) |