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Tepal

A tepal is a floral structure in angiosperms where the sepals and petals are morphologically similar and indistinguishable from one another, collectively forming the of the flower. This undifferentiated condition is particularly prevalent in monocotyledons and certain , distinguishing tepals from the more specialized sepals and petals found in many eudicot flowers. Tepals serve dual functions in flower development and reproduction: they protect the inner reproductive organs, such as stamens and carpels, during the bud stage, and, when colorful and showy, they attract pollinators to facilitate pollen transfer. In evolutionary terms, tepals represent a primitive floral trait observed in early-diverging angiosperm lineages, potentially aiding in the diversification of flowering plants by combining protective and attractive roles in a single organ type. Common examples include lilies (Lilium spp.), where six colorful tepals form a striking bloom; tulips (Tulipa spp.), featuring six similar perianth segments; and magnolias (Magnolia spp.), with tepals in multiples of three that exhibit a leaflike appearance. These structures highlight the diversity of floral adaptations across angiosperm clades, contributing to the ecological success of flowering plants.

Definition and Terminology

Definition

A tepal is one of the outer parts of a flower, collectively forming the , where the individual segments cannot be clearly distinguished as either sepals or petals due to their similar . Unlike sepals, which are typically green and serve a protective function, or petals, which are usually colored and attract pollinators, tepals are undifferentiated and often combine aspects of both roles within the same structure. The term "tepal" was first proposed in 1827 by Swiss Augustin Pyramus de Candolle in his work on , created by analogy with "" and "" to describe these ambiguous elements. Tepals are arranged in whorls, commonly numbering three or six—often as two whorls of three each—in many monocotyledonous flowers, where they form the showy outer layer resembling petals.

Etymology and Historical Development

The term "tepal" originates from the New Latin tepalum, coined by Swiss botanist in 1827 within his Organographie végétale. It was created as an of the French pétale (), transposed by moving the initial syllable to the end in analogy with sépale (), to denote perianth segments lacking clear distinction between sepals and petals. De Candolle's introduction of the term occurred during the early 19th-century push to standardize botanical nomenclature, building on Linnaean foundations amid rapid advances in plant classification and organ description. Initially applied to undifferentiated perianth parts in monocotyledons, such as those of tulips (Tulipa) and lilies (Lilium), it addressed the need for a neutral descriptor in flowers where traditional petal-sepal differentiation proved inadequate. Over the subsequent decades, "tepal" gained broader adoption in European botany, extending from its monocot origins to and exhibiting similar perianth uniformity, as morphological studies refined floral concepts. In modern classifications, including those of the (APG IV, 2016), the term is routinely employed across diverse clades—such as , , and —to facilitate consistent phylogenetic and taxonomic descriptions.

Morphology

Structure and Shape

Tepals are typically arranged in one or two whorls around the receptacle of the flower, with the perianth often consisting of six undifferentiated parts in two series of three (3+3), a common pattern in many monocots such as those in the Liliaceae and Bromeliaceae families. These tepals may be distinct and free from one another or partially fused at their bases, forming structures like a short tube or hypanthium in certain species. In contrast to flowers with separate sepals and petals, tepals represent a homologous merger of the outer and inner perianth whorls. The , or pre-anthesis arrangement of tepals within the , varies and includes valvate aestivation where adjacent tepals touch along their margins without overlapping, imbricate aestivation with regular or irregular overlapping of edges, and contorted (or twisted) aestivation involving convolute twisting of the parts. Individual tepal shapes are diverse and often analogous to those of leaves, such as ovate (egg-shaped with the broader end at the base), lanceolate (lance-shaped, widest near the base and tapering to a point), or oblanceolate (inversely lance-shaped, widest toward the apex). For example, in , tepals commonly exhibit a lanceolate to lanceolate-linear form. Variations in tepal morphology include petaloid forms that resemble petals in texture and appearance, and sepaloid forms that are more leaf-like and rigid. In orchids such as , the tepals are predominantly petaloid, while in grasses ( family), the highly reduced tepals—known as lodicules—are linear or scale-like in shape. Certain orchids, like those in the genus , feature hooded tepals where the dorsal sepal and lateral petals converge to form a protective hood over the reproductive structures. Anatomically, tepals are vascularized with a network of veins, often displaying parallel venation in monocots, and typically include a prominent midrib along the central axis with defined margins that may be entire or slightly undulate.

Coloration and Surface Features

Tepals display a diverse array of colors, frequently resembling those of petals in their vibrancy, including reds, yellows, whites, greens, and mottled patterns. These hues arise primarily from pigments such as anthocyanins, which impart reds, purples, and blues, and , responsible for yellows and oranges. For instance, in , yellow tepals accumulate high levels of carotenoids with minimal anthocyanins, while red varieties in Asiatic hybrid lilies feature elevated anthocyanin concentrations throughout the tepal tissue. Color patterns on tepals often include spots, streaks, or basal markings, enhancing visual complexity. In species, raised spots on the inner tepal surface result from localized accumulation in protruding epidermal cells, creating textured, pigmented bumps. Streaks may appear as pigmented midribs, as seen in some Asiatic lilies where anthocyanins concentrate along the tepal veins. Basal nectaries or markings frequently occur at the tepal base, differing from the rest of the surface; the outer tepal surface is typically duller or greenish, while the inner surface exhibits more vivid coloration. Tepal surfaces vary in texture, ranging from glabrous (smooth and hairless) to pubescent (hairy), puberulent (minutely hairy), or papillose (covered with projections). In certain taxa, the inner tepal surface is granular-papillose, contributing to a roughened appearance. Many tepals bear cuticular coatings that provide repellency and a glossy sheen. These surfaces often feature thicker cuticles compared to those of typical petals, promoting greater durability and prolonged persistence after .

Function

Protective Role

Tepals serve a primary protective function during the pre-anthesis stage of flower development, enclosing the immature bud and acting as a physical barrier against environmental threats such as , pathogens, and herbivory. In plants like lilies ( spp.), the tepals form a tight covering that shields the developing reproductive organs from drying out and physical damage, similar to the role of in differentiated flowers. This enclosure prevents water loss by creating a humid microenvironment within the bud and reduces exposure to fungal or bacterial pathogens that could infect vulnerable tissues. Additionally, tepals deter herbivorous by presenting a tough outer layer that discourages feeding or oviposition on the enclosed bud; for instance, water-filled calyces in some species, analogous to tepal structures, have been shown to halve herbivory rates by submerging buds. In monocots such as tulips and lilies, where sepals and petals are undifferentiated, the tepals collectively fulfill this barrier role, often exhibiting greater robustness due to their uniform development across the . After the flower opens, tepals in certain , such as those in the family, can maintain partial enclosure around the stamens and carpels, providing continued shielding from rain, wind, or opportunistic herbivores during early . This persistent coverage helps safeguard and ovules from immediate environmental assault before occurs. The mechanical properties of tepals enhance their protective efficacy, with features like prominent venation and a stiff midrib conferring resistance to physical stresses such as wind or heavy rain. In Asiatic lilies, for example, the central midrib along each tepal not only supports structural integrity but also interlocks adjacent tepals to secure the bud against deformation. Compared to sepals in , tepals often integrate this sepal-like durability with a more extensive surface area, bolstering overall resilience in undifferentiated perianths. In some species, persistent inner tepals continue to protect developing seeds from insect predation post-anthesis.

Role in Pollination

Tepals play a crucial role in attracting through vibrant colors, emitted scents, and visual patterns that signal the presence of rewards such as or . In many animal-pollinated species, the bright coloration of tepals, often in hues visible to , , or bats, serves to draw these pollinators from a distance, mimicking food sources and enhancing floral against foliage. Additionally, specialized glands on tepal surfaces produce volatile organic compounds that release scents, further enticing pollinators like bees and by advertising the flower's location and quality. These scents, derived from osmophores or secretory tissues within the tepals, vary by species but commonly include and benzenoids that align with pollinator sensory preferences. Beyond initial attraction, tepals guide pollinators toward the reproductive organs via their shape, texture, and subtle patterns. The form of tepals often creates landing platforms or channels that direct insects to the stamens and pistils; for instance, in Albuca species (Hyacinthaceae), papillate apices of inner tepals facilitate precise pollen deposition by leafcutter bees, acting as secondary stigmas to ensure effective transfer. Ultraviolet-reflective patterns on tepals, invisible to humans but prominent to many insects, function as nectar guides, leading pollinators to the flower's center where rewards are located and cross-pollination is promoted. These adaptations in texture and patterning increase foraging efficiency, reducing handling time and boosting pollination success in specialized floral syndromes. In some lineages, tepals directly contribute to rewarding pollinators through nectar production via basal nectaries. For example, in the genus Fritillaria (Liliaceae), nectaries at the tepal bases secrete sugar-rich nectar—averaging 30.6 µl per flower with concentrations up to 77.5%—that attracts and sustains insects or birds, with hexose-dominant compositions tailored to specific pollinators like bees or hummingbirds. This nectar reward reinforces repeated visits, enhancing pollen transfer rates. Tepals are particularly prominent in animal-pollinated plants, where their development underscores specialization for biotic vectors, whereas in wind-pollinated species, they are often reduced or absent to minimize energy expenditure on unnecessary attractants. In grasses () and sedges (), for instance, the perianth is minimal or glume-like, lacking the elaborate tepals seen in entomophilous monocots, allowing pollen dispersal solely by air currents. This contrast highlights tepals' evolutionary tie to animal-mediated strategies.

Evolutionary and Taxonomic Context

Evolutionary Origins

The undifferentiated perianth, consisting of similar tepal-like organs, represents the primitive condition in angiosperms, as observed in basal lineages such as Amborella and Nymphaeales, where floral organs transition gradually from bracts to inner and outer tepals without clear distinction between sepals and petals. This ancestral state reflects a spiral arrangement of perianth parts derived from leaf-like structures or subtending bracts, providing a foundational model for early flower morphology before specialization. The evolution of differentiation into distinct sepals and petals occurred independently multiple times across angiosperm clades, notably in core , facilitated by genetic innovations such as duplications and divergence in the APETALA3 (AP3) and PISTILLATA (PI) gene lineages. These changes restricted B-class gene expression to inner whorls, promoting petal identity and enabling adaptations for specialized , such as attractive, nectar-guiding structures in insect-pollinated lineages. Fossil records from the , including simple flowers like from approximately 125 million years ago, exhibit tepal-like or reduced structures that align with the undifferentiated ancestral state, supporting the broader angiosperm radiation around 140 million years ago during the stage. This period marks the initial diversification of floral forms, with early s likely evolving from bracteate precursors to balance protection and reproductive efficiency. Secondary undifferentiation of the has arisen in various lineages as a reversal of , often linked to syndromes favoring efficiency, such as wind or generalist , where uniform tepals reduce developmental costs while maintaining basic attractive or protective functions. For instance, in some and monocots, the blurring of sepal-petal boundaries facilitates rapid floral maturation in resource-limited environments.

Occurrence in Plant Groups

Tepals are predominantly found in monocots, where they form the characteristic undifferentiated in many orders. In , such as lilies and tulips, flowers typically feature six identical tepals that are often showy and petaloid, serving as the primary attractive structures. Similarly, in , such as irises (), tepals are common, often colorful and expanded, though they can exhibit markings; in orchids, the perianth consists of three sepals and three petals that are generally petaloid but differentiated. In , tepals are present but often reduced; for instance, in grasses (), they are modified into lodicules, small scale-like structures that facilitate by swelling to open the florets. In , tepals occur frequently, reflecting primitive floral conditions. Among , such as magnolias (), the consists of spirally arranged tepals that are undifferentiated between sepals and petals, typically numbering 9 to 15 and varying in color from white to pink. In the ANITA grade, exemplified by , the is simple and composed of tepals in multiple whorls, with 6 to 11 in male flowers and fewer in female ones, arranged spirally without clear distinction between outer and inner series. Tepals are rare in , where a differentiated of sepals and petals is more typical, but they appear occasionally in certain basal and core groups. In , such as hellebores (Helleborus in ), the sepals are petaloid, large, colored, and showy, serving an attractive function similar to tepals, while true s are reduced to nectaries. In , tepals occur in some families like , where the comprises 4 to 6 undifferentiated, often green tepals that enclose the reproductive organs, though many lineages show petal reduction or loss. Tepals are absent or highly modified in derived eudicot groups like , where the is replaced by a pappus of bristles or scales, and the consists of fused petals without tepal-like structures. This distribution correlates with strategies, as tepals are more prevalent in animal-pollinated lineages where their showy, petaloid nature attracts insects and birds, whereas wind-pollinated groups often lack or reduce such elements.