Fact-checked by Grok 2 weeks ago

Perianth

The perianth is the collective term for the sterile, outermost floral envelope in angiosperms, typically comprising the (sepals) and (petals), or undifferentiated structures known as tepals, which enclose and protect the reproductive organs while often functioning to attract pollinators. This structure forms the visible, non-reproductive portion of most flowers, surrounding the androecium (stamens) and (carpels). Structurally, the perianth consists of organs arising from the floral and arranged in whorls, with the usually providing mechanical protection during bud development and the enhancing visual and olfactory cues for . Sepals are generally green and leaf-like, while petals are more modified for display, though in wind-pollinated flowers, the perianth may be reduced or absent to minimize energy expenditure. In monocotyledons and certain basal , the perianth segments are homologous and termed tepals, lacking clear distinction between sepals and petals. The perianth's diversity reflects evolutionary adaptations, with actinomorphic (radially symmetrical) forms common in insect-pollinated species for broad accessibility, and zygomorphic (bilaterally symmetrical) types in specialized syndromes, such as those seen in orchids or snapdragons. Its developmental genetics involve key regulators like class A floral identity genes, which specify perianth formation in the . Overall, the perianth plays a crucial role in angiosperm , contributing to the group's dominance through varied protective and attractive functions.

Definition and Terminology

Etymology

The term "perianth" derives from the Modern Latin perianthium, coined in the to describe the envelope surrounding a flower, literally combining the Greek peri- meaning "around" with anthos meaning "flower". This was first employed in during the by , who used perianthium specifically to denote the in his classifications of floral parts, as seen in works such as Philosophia Botanica (1751) and descriptions of species like Gratiola, where he described it as "Perianthium quinquepartitum, erectum". An alternative etymological interpretation appears in the related term perigonium (or perigone), which emphasizes the structure's role in enclosing reproductive organs and derives from peri- "around" and gonos "seed" or "progeny". This variant highlights the protective enclosure of sexual structures, contrasting slightly with the flower-focused perianthium. The term entered English botany through the périanthe, with the earliest recorded English usage in 1785 by Thomas Martyn in a of a botanical text, marking its adoption in the late before wider use in 19th-century English botanical . This linguistic evolution relates to modern terms like and , which denote specific components of the perianth.

Basic Components

The perianth serves as the sterile outer envelope of a flower, enclosing and protecting the reproductive organs in its early stages of development. In dichlamydeous flowers, it comprises two distinct whorls: the outer , formed by sepals that are typically green and leaf-like, and the inner , composed of petals that are often colorful and showy. This structure is characteristic of many angiosperms, where the calyx provides mechanical protection while the corolla aids in visual attraction, though both are non-reproductive. Perianth arrangements are classified as biseriate or uniseriate based on the number of whorls. A biseriate perianth features two whorls—the and —arranged in series around the flower's , with sepals and petals alternating or opposite each other. In contrast, a uniseriate perianth consists of a single whorl, often undifferentiated into sepals and petals, resulting in a more simplified envelope. This distinction highlights evolutionary variations in floral morphology, with biseriate forms predominant in core . The fusion states of perianth parts further describe their anatomical configuration. In apotepalous conditions, the individual sepals or petals remain free and separate from one another, allowing independent movement. Conversely, syntepalous (for tepals) or gamopetalous (for petals) arrangements involve fusion of these parts, forming a tube or bell-shaped structure that can enhance durability or pollination efficiency. Basic diagrams of perianth structure typically illustrate these components as concentric whorls surrounding the inner androecium (stamens) and gynoecium (carpels), with lines or shading denoting free versus fused segments—for example, in a tulip (biseriate, apotepalous) versus a morning glory (biseriate, gamopetalous).

Structure in Flowering Plants

Calyx and Corolla

In most angiosperms, particularly , the perianth is differentiated into two distinct whorls: the outer and the inner . The consists of sepals, which are typically green, leaf-like structures that form the outermost protective layer of the flower bud. These sepals enclose and shield the developing flower from environmental damage, desiccation, and herbivores before , while often remaining photosynthetic post-opening. For instance, in roses ( spp.), the five sepals are free or slightly connate at the base, providing a persistent protective envelope around the () after . The comprises the inner whorl of petals, which are usually more delicate, brightly colored, and non-photosynthetic, serving primarily aesthetic roles in attraction. Petals exhibit diverse morphologies, including radial (actinomorphic) , where the flower can be divided into mirror images along multiple planes, as seen in many like sunflowers, or bilateral (zygomorphic) , with a single plane of reflection, common in specialized syndromes such as those in snapdragons. This differentiation into and represents the dichlamydeous condition, prevalent in including families like (e.g., ) and (e.g., ), where the sepals and petals are morphologically and functionally distinct. Variations in fusion occur within these whorls; for example, a gamosepalous features sepals united at least basally into a tube or cup, as in many species where the five sepals form a persistent structure that aids protection. Such fusions enhance structural integrity and can influence mechanics, though polysepalous (free) sepals predominate in basal . The and are believed to have originated from modified leaf-like structures in early angiosperm ancestors, with sepals retaining more foliar traits and petals evolving specialized pigmentation and nectar guides. Fossil evidence from deposits, around 130 million years ago, shows primitive flowers with undifferentiated or minimally differentiated perianths, lacking clear calyx-corolla division, suggesting this specialization arose through subsequent evolutionary refinement in core .

Tepals

Tepals are the undifferentiated segments of the perianth in homochlamydeous flowers, where the calyx and corolla are not distinctly separated, resulting in a uniform envelope of similar floral organs. These flowers are characteristic of many monocots, such as tulips (Tulipa spp.) and lilies (Lilium spp.), as well as basal angiosperms like magnolias (Magnolia spp.), where the perianth consists of multiple whorls or spirals of tepals that are often petaloid in appearance. In these taxa, tepals serve as the primary perianth structures, blending sepal-like and petal-like traits without clear morphological boundaries between outer and inner whorls. The arrangement of tepals varies phylogenetically, often occurring in spirals or whorls. In such as water lilies ( spp.), tepals are arranged spirally around the receptacle, reflecting an ancestral condition with gradual transitions between perianth and reproductive organs. Conversely, in petaloid monocots like orchids (Orchidaceae), tepals form two whorls of three, with the outer whorl comprising sepals and the inner featuring petals, though all may appear similarly colored and textured due to shared developmental cues. Adaptations in tepal morphology emphasize color and texture to enhance visual appeal, particularly in petaloid forms. For instance, in wind-pollinated grasses (Poaceae), the perianth is reduced, with two or three lodicules—modified, scale-like structures homologous to petals—exhibiting petaloid characteristics that swell to expose reproductive parts during anthesis. These lodicules, positioned adjacent to stamens, represent a derived adaptation where subtle coloration and hygroscopic movement facilitate pollination without prominent display. Developmentally, tepal formation in homochlamydeous flowers aligns with modifications to the ABC model of floral organ identity, where class A genes (e.g., APETALA1 and APETALA2 homologs) predominate in the outer perianth without strict B-class differentiation, yielding uniform identity across whorls. In like , the outer tepal whorl lacks B-class (APETALA3 and PISTILLATA homologs), resembling sepals under A-class influence alone, while inner tepals may show partial overlap, yet overall similarity arises from broad AGL6-like expression promoting perianth traits. In monocots such as lilies, an outward expansion of B-class genes to the first whorl creates petaloid outer tepals, blurring distinctions and supporting a "sliding " variant of the model. This genetic framework underscores how tepals evolve from conserved gene networks, adapting perianth uniformity to diverse ecological roles.

Functions

Protection

The perianth acts as a primary barrier, shielding the immature reproductive organs of the flower from environmental stresses including , physical damage, and herbivory during the pre-anthesis stage. The arrangement of perianth parts in the flower bud, known as , reinforces this protective role by forming a tight that limits entry and external threats. Imbricate and valvate aestivation patterns are particularly common in the , the outer whorl, allowing overlapping or edge-to-edge contact that seals the bud effectively; valvate aestivation predominates in protective sepals to maintain integrity during development. In certain species, the perianth persists post-anthesis, extending its protective function to developing fruits or seeds. For instance, in Helleborus foetidus, persistent sepals contribute photosynthetic resources to seed development, increasing seed mass. Similarly, in apples (Malus domestica), the calyx with attached sepals remains at the fruit's stem end. Thicker cuticles on sepaloid organs further minimize water loss, contributing to overall desiccation resistance.

Pollination Attraction

The perianth, especially the corolla, attracts pollinators through diverse coloration and patterns tailored to specific pollinator sensory capabilities. Petals often display pigments like anthocyanins for blue-violet hues that appeal to bees, or carotenoids contributing to red corollas that signal to birds while being inconspicuous to insect competitors. These colors enhance long-distance visibility, with red predominating in bird-pollinated species to facilitate nectar access via tubular structures. Ultraviolet (UV) patterns on petals serve as nectar guides, invisible to humans but detectable by insects like bees, directing them to reproductive structures. In sunflowers, UV bullseye patterns contrast with surrounding petal areas to highlight nectar rewards, while in Mimulus species, similar guides formed by pigment gradients improve pollinator efficiency. These visual cues, often combined with white or yellow lines on petals, significantly boost pollination success; for example, in Lapeirousia oreogena, nectar guides increase male and female fitness by ensuring accurate proboscis insertion by fly pollinators, raising fruit set from 26% to 59%. Olfactory attraction complements visuals, as glandular trichomes on tepals or petals emit volatile scents that lure pollinators from afar, with species-specific bouquets evolving to match insect or bird preferences. Structural adaptations in the perianth further facilitate contact , particularly in zygomorphic flowers where bilateral creates specialized landing platforms. In snapdragons (), the ventral petal, regulated by genes like DIVARICATA, forms a broad platform that supports bee weight while guiding them toward anthers and . Such modifications reduce handling time and increase transfer precision. Evolutionarily, perianth persistence involves trade-offs; in mass-flowering species like petunias, post-pollination corolla wilting and abscission within 48 hours enable nutrient remobilization (e.g., and ) to developing seeds, minimizing energy costs for maintenance after attraction duties are fulfilled. This ephemeral strategy optimizes resource allocation in high-density blooming, where rapid supports fruit set without prolonged floral investment.

Specialized Structures

Corona

The corona is a specialized appendage of the perianth in certain angiosperm flowers, typically manifesting as a cup-shaped, tube-like, or filamentary structure that arises from the bases of the corolla or filaments, often positioned between the petals and stamens. In the Amaryllidaceae family, such as in Narcissus species (daffodils), it forms a prominent single corona, exemplified by the trumpet-like cup in Narcissus tazetta, which emerges as an independent structure late in floral development. Conversely, in the Apocynaceae subfamily Asclepiadoideae (formerly Asclepiadaceae), coronas can be multiple, with up to five elements including staminal and interstaminal projections, as observed in species like Asclepias curassavica and Oxypetalum banksii. In Passiflora (Passifloraceae), the corona consists of multiple rows of filaments, typically up to eight series, forming a colorful, elaborate fringe that encircles the reproductive organs. Developmentally, the corona originates as an outgrowth of perianth or hypanthial tissue, initiating after the formation of the primary floral whorls (sepals, petals, stamens, and carpels), which underscores its status as a novel, fifth-like organ rather than a modification of existing ones. In Narcissus bulbocodium, for instance, it begins as six discrete primordia from the hypanthium between tepals and stamens, later fusing into a coherent ring, with genetic markers like NbAGAMOUS indicating stamen-like identity but distinct from orthodox whorls. In Asclepiadeae, coronas develop primarily from androecial tissue, though some species like Matelea denticulata exhibit both androecial and corolline types, often incorporating nectar-producing glands. Cross-sections of these structures reveal vascular connections to the perianth base, with internal chambers or lobes that hold nectar, as seen in the lobed, villose interior of Narcissus coronas. Functionally, the corona aids by serving as a visual attractant through its vibrant colors and patterns, while physically guiding via its tube- or filament-like projections that direct access to and reproductive parts. In Narcissus, it enhances pollinator efficiency, particularly for short-styled flowers, by providing a reservoir and structural barrier that promotes precise transfer. Similarly, in Asclepiadeae and , the corona's nectar-holding capacity and filament arrays facilitate specialized mechanisms, such as pollinia removal in milkweeds or filament-guided probing in passionflowers, thereby increasing .

Other Modifications

In the family, the perianth undergoes modification through formation, where the bases of sepals, petals, and often stamens fuse to create a cup-shaped structure that elevates and surrounds the , contributing to floral and development. This perigynous condition is evident in species like strawberries (Fragaria × ananassa), where the enlarges post-fertilization to form the edible, fleshy pseudocarp that bears numerous small achenes on its surface. Another notable modification occurs in the , where the portion of the perianth evolves into a pappus—a persistent ring of capillary bristles, scales, or awns that aids in wind-mediated of the cypsela fruits. In sunflowers ( annuus), for instance, the pappus persists after corolla withering, enabling the lightweight fruits to be carried long distances by air currents. This adaptation enhances dispersal efficiency in open habitats. Perianth reduction or complete absence represents an evolutionary simplification in many wind-pollinated angiosperms, resulting in apetalous flowers that prioritize release over attraction. (Quercus spp.) exemplify this, with male catkins featuring stamens enclosed by a greatly reduced perianth consisting of 4-7 small lobes, minimizing energy allocation to non-essential structures. In the family, such as various grasses (e.g., , Triticum aestivum), the perianth is drastically reduced to two or three minute, hygroscopic lodicules that briefly swell with moisture to pry apart the bract-like and palea, exposing reproductive organs for anemophily without visual appeal. Elaborations of the perianth also arise as specialized outgrowths, such as the nectar spurs formed from the inner whorl of petals in Aquilegia (columbine) species. These tubular extensions, varying in length from 1 to 5 cm across taxa, secrete nectar and match the tongue lengths of pollinators like bees or hawkmoths, driving diversification through pollinator specialization. In some Poaceae, bracts like the lemma can develop awns or subtle coloration that indirectly supports perianth-like protective or dispersive roles, though the family predominantly exhibits reduction.

Occurrence in Non-Flowering Plants

Bryophytes

In bryophytes, the perianth serves as a protective envelope around the female reproductive structures, particularly the archegonia, facilitating reproduction in moist environments. In mosses of the class , the archegonia are typically enclosed within a perianth formed by modified leaves or gametophytic tissue, often resembling a calyptra and positioned on an archegoniophore in species like . This structure shields the developing from and mechanical damage during early embryogenesis. In liverworts (), the perianth takes the form of a perigynium, a fleshy, tubular outgrowth of gametophytic tissue surrounding clusters of archegonia, as prominently seen in where it emerges from the ventral side of the . The perigynium provides a humid microenvironment essential for and fertilization, often complemented by perichaetial bracts for additional protection. Variations occur across taxa, with some leafy liverworts exhibiting plicate or smooth perianths that aid in species identification. Evolutionarily, the perianth represents a for colonization, analogous yet simpler than the perianth in angiosperms, primarily functioning to retain around gametangia for water-dependent fertilization. In species, pseudoperianths—thalloid tissues derived from gametophyte outgrowths—exhibit variations in thickness and inflation, enhancing buoyancy for dispersal in habitats. records from deposits, such as those of the bryophyte-like Naiadita lanceolata, reveal archegonia surrounded by perianth-like leaflike lobes approximately 300 μm long, indicating this structure's ancient role in reproductive protection.

Gymnosperms

In gymnosperms, which are seed-producing plants that lack flowers and fruits, the perianth is typically absent, as their reproductive structures are organized into cones (strobili) rather than floral organs. The sporophylls in these cones bear naked seeds or sacs without surrounding protective or attractive envelopes equivalent to a or . This absence reflects the evolutionary divergence of gymnosperms from angiosperms, where the perianth evolved as part of floral diversification for protection and . An exception occurs within the gnetophytes, a small but diverse subgroup of gymnosperms that includes , , and , where perianth-like structures have developed convergently. These structures consist of bracts or fused bracteoles forming an envelope around the reproductive units, often termed a "perianth" due to their functional similarity to floral perianths in enclosing and potentially aiding in . For instance, in (Ephedraceae), the microsporangiate (male) cones feature a perianth of connate bracteoles subtending microsporangiophores, while megasporangiate (female) cones have ovules enveloped by similar bract-like coverings that form a micropylar tube. In (Gnetaceae), the reproductive units exhibit integuments or bract-derived envelopes resembling a floral perianth, contributing to the flower-like appearance of their cones. These modifications in gnetophytes highlight a partial convergence toward angiosperm floral traits, though they remain distinct in lacking true petals or sepals.

References

  1. [1]
    perianth - NAL Agricultural Thesaurus: NALT
    Type. Topic ; Definition. Information A collective term for the floral envelopes, usually the combined calyx and corolla, or tepals of a flower. Source: Burns, ...
  2. [2]
    UCMP Glossary: Botany
    Jan 16, 2009 · perianth -- The sepals and petals of a flower are together called the perianth; literally "around the anthers". More info?Missing: definition | Show results with:definition
  3. [3]
    3. Botany | NC State Extension Publications
    Feb 1, 2022 · Anatomy and Morphology—Plant Structure and Their Functions. Cells ... The calyx and corolla together are called the perianth. The ...
  4. [4]
    Environmental control of sepalness and petalness in perianth ...
    Jul 2, 2009 · The perianth is an important element of most flowers. It consists of several sterile, dorsiventrally flattened organs (phyllomes) that surround ...
  5. [5]
    [PDF] Topic 13: Angiosperms: Flowers, Inflorescences, and Fruits
    The Perianth. Sepals are the leafy organs that comprise the outermost whorl called the calyx. The petals are the leafy organs that comprise the next whorl ...
  6. [6]
    More on Morphology of the Anthophyta
    Around these reproductive organs is the perianth, usually consisting of an outer whorl of sepals and an inner whorl of petals. In monocots and "primitive" ...
  7. [7]
    Evolution of Perianth and Stamen Characteristics with Respect to ...
    Monosymmetry commonly refers to the perianth, even though associated androecium modifications have been reported. The evolution of perianth symmetry is examined ...Missing: definition | Show results with:definition
  8. [8]
    [PDF] Chapter 3. Reproductive morphology of plants
    The gene function A is required in order to determine the identity of the verticils of the perianth (sepals and petals), while the gene C is required to ...
  9. [9]
    Perianth Biology in the Basal Grade of Extant Angiosperms
    The perianth is a basic part of the flowers of the crown group of angiosperms (for which the name Angiospermae was proposed; Cantino et al. 2007) and may even ...Missing: definition botany
  10. [10]
    Perianth - Etymology, Origin & Meaning
    in botany, "envelope of a flower," 1706, from French périanthe, from Modern Latin perianthium (17c.), literally "that which is round the flower," from Greek ...
  11. [11]
    A Grammatical Dictionary of Botanical Latin
    Perichaetium, “W. J. Hooker's name for the perianth in Hepaticae” (Jackson). Pseudoperianth, (in bryophytes) “tissue of thalline origin surrounding the ...
  12. [12]
    perigonium - Wiktionary, the free dictionary
    Etymology. From peri- +‎ -gonium. Noun. perigonium (plural perigonia). (botany) ... Synonyms: perianth, perigone. (botany) The modified leaves around the ...Missing: gonos | Show results with:gonos
  13. [13]
    perianth, n. meanings, etymology and more | Oxford English Dictionary
    ... perianth is from 1785, in a translation by Thomas Martyn, botanist. perianth is a borrowing from French. Etymons: French périanthe. See etymology. Nearby ...
  14. [14]
    Bentham's Outlines of Botany: Chapter 1: Section 8 - The Flower in ...
    A Flower is. dichlamydeous, when the perianth is double, both calyx and corolla being present and distinct. monochlamydeous, when the perianth is single ...Missing: definition | Show results with:definition
  15. [15]
    Perianth - an overview | ScienceDirect Topics
    The perianth (or perigonium) is the outermost, nonreproductive group of modified leaves of a flower (The term perianth has also been used for components of the ...
  16. [16]
    Perianth, Calyx, Corolla, Petal, Sepal, Tepal
    The perianth functions as a protective envelope, and indeed the term is derived from Latin words meaning “around the anthers.”
  17. [17]
    Basal Angiosperms - OpenEd CUNY
    In the outer whorl of the magnolia flower the sepals and petals are undifferentiated and are collectively called tepals. The reproductive parts are arranged ...
  18. [18]
    The Botany of Magnolias - Smithsonian Gardens
    Mar 12, 2021 · In magnolias, the petals and sepals are similar in size, shape, and color, so we collectively call them all tepals. Magnolias are also ...
  19. [19]
    Key characteristics of monocot families
    Flowers actinomorphic, usually bisexual. Inflorescence often a raceme. Perianth 2 whorls of 3 tepals, free or united; stamens 6; carpels 3; ovary superior.<|separator|>
  20. [20]
    Anatomy of an Orchid
    The orchid flower is typically has an outer whorl of three sepals, an inner loop of three petals, a single large column in the center, and an enlarged bottom ...
  21. [21]
    Conservation of B class gene expression in the second whorl of a ...
    This phenotype is consistent with an interpretation of lodicules as modified grass petals and palea as grass sepals.<|separator|>
  22. [22]
    Evolution of petal identity | Journal of Experimental Botany
    As such, the appearance of lodicules in the grasses and of petals in the core eudicots could reflect the parallel evolution of different organ types based on a ...
  23. [23]
    30.12: Plant Development - Genetic Control of Flowers
    Nov 22, 2024 · 1 : ABC model of flower development: Class A genes (blue) affect sepals and petals, class B genes (yellow) affect petals and stamens, class C ...Learning Objectives · Genetic Control of Flower... · ABC Model of Flower...
  24. [24]
    The role of ABC genes in shaping perianth phenotype in the basal ...
    Oct 1, 2015 · In conclusion, Magnolia genus is capable of forming, in some species, a perianth differentiated into a calyx (sepals) and corolla (petals).Missing: lilies | Show results with:lilies
  25. [25]
    The ABC model of floral development - ScienceDirect.com
    Sep 11, 2017 · The ABC model is a simple and satisfying explanation for how this conserved floral architecture is genetically specified.
  26. [26]
    The ABC Model and its Applicability to Basal Angiosperms - PMC
    The ABC model has long been the unifying paradigm for floral developmental genetics, but it is based on phylogenetically derived eudicot models.
  27. [27]
    Quercus - FNA - Flora of North America
    Nov 5, 2020 · Staminate flowers: sepals connate ... Other products include tannins and dyes, and oak bark and leaves were often used for tanning leather.
  28. [28]
    Evolutionary diversification of the flowers in angiosperms
    Mar 1, 2011 · Valvate aestivation, if present, occurs preferentially in the whorl that is protective in bud, thus more often in sepals than in petals (see ...
  29. [29]
    Post‐floral perianth functionality: contribution of persistent sepals to ...
    Sep 1, 2005 · The perianth persists after flowering in many plants, yet its post-floral functionality has been little investigated, and the few studies ...
  30. [30]
    Phytohormonal dynamics in the abscission zone of Korla fragrant ...
    Oct 8, 2024 · Fruits with a protruding calyx end and persistent sepals are called 'persistent calyx fruits'. Fruits with a top end that is concave like a ...
  31. [31]
    Kinematical, Structural and Mechanical Adaptations to Desiccation ...
    Nov 19, 2018 · R. myconi possesses structural and mechanical adaptations to desiccation (in addition to physiological adaptations), which may mainly be passively driven by ...Missing: perianth | Show results with:perianth
  32. [32]
    Visual Cues - USDA Forest Service
    Nectar guides are patterns seen in some flowers that guide pollinators to the nectar and pollen. In many bee-pollinated flowers, there is a region of low ...
  33. [33]
    Why Are So Many Bird Flowers Red? - PMC - PubMed Central - NIH
    Oct 12, 2004 · Most bird-pollinated flowers are both red and rich in nectar. The traditional explanation for this association is that, since red is inconspicuous to bees, it ...
  34. [34]
    Experimental evidence for bird pollination and corolla damage by ...
    The question of why so many bird-pollinated flowers are red has been explored by Raven (1972) and more recently reviewed by Rodríguez-Gironés and Santamaría ...
  35. [35]
    https://www.mdpi.com/2223-7747/12/7/1458
  36. [36]
    https://www.researchgate.net/publication/318460467_Corona_development_and_floral_nectaries_of_Asclepiadeae_Asclepiadoideae_Apocynaceae
  37. [37]
    The corona of the daffodil Narcissus bulbocodium shares stamen ...
    Feb 14, 2013 · Flowers of the genus Narcissus (the daffodils) possess a distinct fifth organ termed the corona, a cup-shaped or crown-like structure located ...
  38. [38]
    Emergence of Corona Is Independent of the Four Whorls of Floral ...
    Mar 27, 2023 · The corona is a structure independent of and different from the typical four whorls of floral organs, but also highly correlated with stamen.Missing: definition | Show results with:definition
  39. [39]
    (PDF) Corona development and floral nectaries of Asclepiadeae ...
    Jul 17, 2017 · Given the complexity and importance of these structures for reproduction, this study aimed to analyze the ontogeny of the corona, the structure ...
  40. [40]
    Space matters: meristem expansion triggers corona formation in ...
    Dec 11, 2015 · One of the typical flower capacities is represented by the formation of a corona, i.e. an attractive structure located between the petals and ...
  41. [41]
    The function of the floral corona in the pollination of a Mediterranean ...
    Our results suggest that the corona in Narcissus is more important for the pollination of S-flowers, which generally have lower seed production compared to L- ...Missing: definition structure examples<|control11|><|separator|>
  42. [42]
    Hypanthium - an overview | ScienceDirect Topics
    Hypanthium is defined as a floral structure that is formed by the fusion of the bases of the sepals, petals, and stamens, typically surrounding or supporting ...Introduction · Plant Morphology · Myrtales
  43. [43]
    Fruits of Life: Rose Family Study Leads to New Understanding of ...
    As for flowers, most Rosaceae species share some common ancestral characters, such as bearing a hypanthium, which is a connation of the receptacle and the ...
  44. [44]
    Sepal Identity of the Pappus and Floral Organ Development in the ...
    One of the most important traits for seed and fruit dispersal in the Asteraceae is the pappus, a scaly, bristly, or hairy appendage that facilitates uptake by ...
  45. [45]
    How to lose a whorl: the evolutionary and developmental biology of ...
    The general plan of the core eudicot flower involves two perianth whorls, a calyx, and a corolla. However, numerous eudicots, in multiple lineages, have only ...
  46. [46]
    Flower Terminology (Part 2) - WAYNE'S WORD
    In some grasses, the minute remnants of perianth segments called lodicules are visible at the base of the ovary. Grasses are typically wind-pollinated, ...<|control11|><|separator|>
  47. [47]
    Evolution of spur-length diversity in Aquilegia petals is achieved ...
    Nov 16, 2011 · Aquilegia petal spurs exhibit striking size and shape diversity, correlated with specialized pollinators ranging from bees to hawkmoths in a ...Missing: perianth | Show results with:perianth
  48. [48]
    Flower Stalk - an overview | ScienceDirect Topics
    ... pollinator or better effecting the transfer of pollen. Some perianths are highly modified for other functions, such as the lodicules of grasses, which are ...
  49. [49]
    [PDF] bryophytes - The PhycoLab
    •Sporophyte surrounded by a tubular sheath known as perianth. Page 17. MOSSES: PHYLUM BRYOPHYTA. •There are several classes. •Sphagnidae, the peat mosses.
  50. [50]
    [PDF] Bryophyte Ecology Glossary - Digital Commons @ Michigan Tech
    Jun 6, 2022 · perianth: organ of foliar origin enclosing archegonia in most leafy liverworts perichaetial leaf: modified leaf among those surrounding ...
  51. [51]
    [PDF] Liverwort reproductive structures – demystifying the jargon
    Perichaetial bracts are found below the perianth and, in certain genera, such as Jungermannia and Solenostoma, a short fleshy tube called a perigynium may also ...
  52. [52]
    Life cycle - sporophyte - liverwort - bryophyte
    Sep 12, 2012 · The bulbous green cylinder around the base of the pale seta is a perianth. In this case the perianth is rather smooth. There are also fleshier ...
  53. [53]
    Appendix C - Glossary
    Perigynium - a fleshy tubular structure around the developing sporophyte of liverworts. Peristomate - with a peristome present. Peristome - structures ...<|separator|>
  54. [54]
    Reproduction & dispersal - bryophyte
    Sep 12, 2012 · Bryophytes have neither pollen nor flowers and rely on water to carry the male gametes (the sperm) to the female gametes (the eggs). The spore ...Missing: perianth moisture retention
  55. [55]
    Bryophyte - an overview | ScienceDirect Topics
    Some specimens possess stem-borne archegonia, which are ∼300 μm long and surrounded by a “perianth” of leaflike lobes. Although antheridia are not known, ...
  56. [56]
    Perianth is present in________of gymnosperm - Brainly.in
    Oct 30, 2019 · Answer: Sporophylls in cones develop like flower but lack perianth lobes. Explanation: The gymnosperms are usually woody with two types of branches.
  57. [57]
    How to Evolve a Perianth: A Review of Cadastral Mechanisms ... - NIH
    Oct 29, 2018 · Here we propose that cadastral mechanisms maintaining reproductive identity to the center of the flower could have supported perianth appearance ...
  58. [58]
    Gnetophyta - an overview | ScienceDirect Topics
    In the axil of the bracts are the microsporangiate (male) reproductive units, each of which consists of a so-called perianth of bracts that surround a pair of ...
  59. [59]
    MADS-box genes reveal that gnetophytes are more closely related ...
    The flower-like appearance of the reproductive units of Gnetum is based largely on the presence of integuments (or envelopes) that resemble a floral perianth.
  60. [60]
    https://www.conifers.org/gn/Gnetaceae.php