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Planula
Planula
Planula
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A planula is the free-swimming, flattened, ciliated, bilaterally symmetric larval form of various cnidarian species and some species of Ctenophores, which are not closely related to cnidarians. Some groups of Nemerteans also produce larvae that are very similar to the planula, which are called planuliform larva.[1][2] In a few cnidarian clades, like Aplanulata and the parasitic Myxozoa, the planula larval stage has been lost.[3][4]

Development

[edit]
Planula stage of Clytia hemisphaerica

The planula forms either from the fertilized egg of a medusa, as is the case in scyphozoans and some hydrozoans, or from a polyp, as in the case of anthozoans.

Depending on the species, the planula either metamorphoses directly into a free-swimming, miniature version of the mobile adult form, or navigates through the water until it reaches a hard substrate (many may prefer specific substrates) where it anchors and grows into a polyp. The miniature-adult types include many open-ocean scyphozoans. The attaching types include all anthozoans with a planula stage, many coastal scyphozoans, and some hydrozoans.[5]

Feeding and locomotion

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The planulae of the subphylum Medusozoa have no mouth, and no digestive tract, and are unable to feed themselves (lecithotrophic), while those of Anthozoa show more variation and can be both lecithotrophic, parasitic or feed on plankton or detritus.[5][6][7]

Planula larvae swim with the aboral end (the end opposite the mouth) in front.[5][1]

References

[edit]
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Planula

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from Grokipedia
The planula is a small, ciliated, bilaterally symmetrical that represents the free-swimming developmental stage in the life cycle of most cnidarians, including members of the classes , , Cubozoa, and such as , corals, and sea anemones. Typically measuring less than 1 mm in length, it emerges from of eggs released into the water column by adult medusae or polyps, serving as a key mechanism for dispersal across marine environments. Structurally, the planula consists of an outer layer of ectodermal cells equipped with cilia for locomotion, surrounding a solid mass of al cells that form the basis of the future gastrovascular cavity. In anthozoan species like the Nematostella vectensis, it features an oral opening connected to a developing and , enabling selective uptake of nutrients such as dissolved proteins via , though it generally does not ingest particulate matter like or beads. This ciliated exterior propels the through the , often in a cigar-shaped form, while internal reserves—primarily (up to 70% of dry weight), proteins, and carbohydrates—sustain it during its brief planktonic phase. In the cnidarian life cycle, the planula develops from a zygote through a blastula stage before hatching and swimming freely for days to weeks, depending on the species and environmental conditions. Environmental cues, including light wavelength and substrate suitability, guide its settlement, after which it undergoes metamorphosis into a sessile polyp that may bud asexually to form colonies or develop into medusae. This alternation between polyp and medusa stages, with the planula bridging reproduction and benthic attachment, underscores its ecological significance in marine biodiversity and reef formation.

Definition and Characteristics

Morphology

The planula larva exhibits a free-swimming, elongated body that is bilaterally symmetrical, typically ranging from 0.1 to 1 mm in length, though specific examples like those in measure 200–350 μm long and 110–150 μm wide. This simple, cylindrical or pear-like form lacks appendages and is adapted for pelagic dispersal, with the body often broader at the anterior end and tapering toward the posterior. The external surface consists of a single layer of pseudostratified ciliated epithelial cells forming the , which covers the entire body and enables coordinated propulsion through ciliary beating. These cilia, along with scattered cnidocytes and cells, also contribute to sensory functions, such as detecting environmental cues. Internally, the planula is organized into two epithelial layers—an outer and an inner —surrounding a solid mass of endodermal cells containing loosely arranged mesenchyme-like interstitial cells, some of which serve as potential precursors. The is solid or contains a narrow, cleft-like lumen, devoid of a functional gut. Planulae display clear anterior-posterior polarity, with the blunt anterior (aboral) end frequently featuring an apical sensory organ containing elongated sensory cells. The tapered posterior end lacks such structures, emphasizing the larva's directional swimming. Early-stage planulae possess no complex organs, including a , digestive tract, or centralized , relying instead on diffuse sensory elements within the . Shape variations exist among cnidarian groups; for instance, hydrozoan planulae, such as those of Clytia hemisphaerica, are often pear-shaped and elongated, while anthozoan forms tend to be more flattened or ovoid. These structural differences influence and settlement behavior, though the ciliated surface remains uniform across variants.

Taxonomic Distribution

The planula larva is primarily found within the phylum , serving as a key stage in the indirect development of its four main classes: , , , and Cubozoa. In , such as colonial hydroids, the planula facilitates dispersal before settling into polyps. , including true jellyfishes, feature planulae that develop into polyps and eventually ephyrae, as seen in Aurelia aurita (moon jelly), where the planula transitions through strobilation to produce ephyra larvae. , encompassing sea anemones and corals, produce planulae critical for reef-building species; for instance, scleractinian corals release lipid-rich planulae that swim to suitable substrates for metamorphosis into polyps, contributing to the formation of vast reef ecosystems. Cubozoa, or box jellyfishes, also exhibit planulae that settle into primary polyps with limited mobility before budding into medusae. Rare or debated planula-like larvae, often termed planuliform, are reported in other phyla such as Platyhelminthes (particularly ) and , but these are not typical and may represent rather than shared ancestry. In , planuliform larvae develop directly from embryos in certain palaeonemertean species, contrasting with the more prominent pilidium type. Evolutionarily, the planula is considered an ancient larval type, with interpretations of fossils (approximately 635–541 million years ago) suggesting early metazoan larvae resembling planulae, predating the and potentially serving as an ancestral form to bilaterian larvae through shared ciliated, bilateral body plans. This early origin underscores the planula's role in the radiation of eumetazoans, linking non-bilaterian groups like to broader metazoan diversity via conserved developmental motifs.

Development and Life Cycle

Embryonic Formation

In many cnidarians, fertilization is external and occurs through broadcast spawning, where gametes are released into the water column, allowing sperm to fuse with eggs to form a zygote. This process is prevalent in species such as corals and scyphozoans, ensuring genetic diversity via outcrossing. However, some species, especially brooding anthozoans, undergo internal fertilization and release fully formed planulae. Following fertilization, the undergoes holoblastic cleavage, characterized by complete division of the into uniform blastomeres, resulting in a stereoblastula stage. This radial and often equal cleavage pattern is observed in hydrozoans like and scyphozoans like , where divisions proceed synchronously in early stages. Gastrulation in cnidarians typically proceeds via or of cells from the blastula, establishing the diploblastic with an outer and inner . The develops into the future ciliated epithelium of the planula, while the serves as a precursor to the gastrovascular cavity. These processes vary slightly by but consistently yield a polarized . The planula larva becomes competent for settlement within hours to days post-fertilization, with development in species like Hydra and Hydractinia typically completing in 1–3 days under optimal conditions. Environmental factors, including and , significantly influence cleavage rates and embryonic viability; for instance, higher temperatures accelerate cleavage in corals and hydrozoans, while deviations in salinity can reduce survival. Genetically, the plays a key role in regulating oral-aboral axis formation during these early stages, as evidenced in anthozoans and hydrozoans where it establishes polarity at the site.

Settlement and Metamorphosis

The settlement of the planula larva marks the end of its pelagic phase and the initiation of into a benthic form in cnidarians. This process is triggered by environmental cues that signal suitable habitats, such as marine substrates including rocks or biogenic films. Upon detecting these signals, the planula ceases locomotion, attaches to the substratum, and undergoes rapid morphological reorganization. Settlement cues primarily involve chemical signals from bacterial biofilms or microbial communities on surfaces, which induce attachment in species across . For instance, in hydrozoans like Hydractinia, substrate-borne release morphogens that stimulate sensory cells to initiate settlement via release. Physical factors, such as the texture of rocks or , also play a role by providing mechanochemical stimuli that the planula's aboral or anterior sensory structures detect. In corals, crustose (CCA) biofilms are particularly effective, prompting settlement within 0.5 hours of exposure. The settlement process begins with the planula adhering to the substratum, typically by the aboral end across cnidarian classes, followed by of the body. This attachment occurs 4–6 days post-release in some species and leads to within 1–7 days, involving tissue reorganization without significant in early stages. During this phase, the larva tests multiple sites via gliding before permanent fixation, a behavior that enhances habitat selection after dispersal. Metamorphic changes include the breakdown of larval tissues and differentiation of adult structures, varying by cnidarian class. In anthozoans like corals, the planula develops , a , and , forming a primary polyp that serves as the foundation for growth. Hydrozoans transform into polyps with similar features, while in scyphozoans such as , the settled planula forms a radially symmetrical polyp with a concavity, buds, and muscle fibers, preceding later strobilation to ephyra. These transformations involve ectodermal folding and endodermal epithelialization, completing within 4–12 hours in induced coral larvae. Success rates of settlement are generally low in natural environments, often below 1%, due to the challenges of finding appropriate cues amid dispersal over distances that reduce survival. In conditions with optimal bacterial cues, rates can reach 60–85% in octocorals like Rhytisma fulvum fulvum, but field observations show high post-settlement mortality from competition or unsuitable conditions. Gregarious settlement, where larvae cluster in response to conspecific cues, can boost local success but increases . If suitable cues are absent, planulae may fail to settle, leading to resorption of tissues or death within days of competence. In corals, uninduced larvae exhibit prolonged swimming until exhaustion, highlighting the critical role of precise environmental signals in survival.

Behavior and Ecology

Locomotion

The locomotion of the planula larva, the free-swimming stage of many cnidarians, primarily relies on coordinated beating of cilia covering its surface, generating metachronal waves that propel the larva forward with the aboral (anterior) end leading. These ciliary beats create thrust through hydrodynamic interactions, enabling swimming speeds typically ranging from 0.2 to 2.5 mm/s across species, depending on taxa and environmental conditions. In some species, such as certain corals, the cilia exhibit variations in length or density, with thicker or longer cilia at the posterior end providing enhanced thrust for propulsion. Directional control is achieved via anterior sensory structures, including statocysts in some taxa like scyphozoans and cubozoans, or clusters of sensory cells that detect environmental cues such as gravity and , facilitating geotaxis and phototaxis. These mechanisms allow the to orient toward optimal conditions, often exhibiting negative geotaxis to swim upward or positive phototaxis in response to gradients. Swimming patterns vary between spiral trajectories, which promote rotational stability and dispersal, and straighter paths during directed vertical migration, with larvae frequently maintaining positions near the water surface to exploit currents for broader distribution. The energy for this locomotion derives mainly from yolk reserves accumulated during embryonic development, as planula larvae are typically lecithotrophic with minimal or no feeding in early stages. The swimming phase generally lasts from 1 to several weeks, enabling by ocean currents over distances of tens to hundreds of kilometers, which is crucial for connectivity in sessile adult forms.

Feeding Mechanisms

Planula larvae of cnidarians primarily rely on endogenous yolk reserves derived from the for , which sustains short-lived through their dispersal phase without the need for external intake. In hydrozoans, these lecithotrophic planulae depend entirely on yolk stores and typically complete development within hours to a few days before settlement, as yolk depletion limits their planktonic duration. Similarly, scyphozoan planulae, like those of , are non-feeding and draw solely on maternal provisions, with metabolic rates low enough to support survival for 3–10 days, up to several weeks under optimal conditions at around 20°C depending on initial energy allocation. In contrast, longer-lived planulae, particularly in anthozoans, often exhibit planktivory to supplement reserves, using ciliary currents to draw in small particles such as , , or protozoans. For instance, planulae of the Anthopleura elegantissima actively capture and via mucus threads and cilia, acquiring symbiotic that enhance survival by providing additional photosynthetic nutrition. Ingestion occurs through adhesion to ciliated surfaces followed by in endodermal cells, as observed in Lophelia pertusa planulae feeding on picoplankton and smaller after three weeks, though some taxa like Nematostella vectensis preferentially assimilate dissolved (e.g., proteins) via rather than particulates. Feeding efficiency in planktotrophic planulae remains low due to their minimal metabolic demands, serving mainly to extend dispersal and boost in nutrient-scarce environments rather than being essential across all taxa. Active feeding correlates with residence in plankton-rich habitats, as seen in anthozoans where consumption increases larval persistence, whereas non-feeding strategies predominate in taxa with brief larval phases or oligotrophic conditions. Locomotion via ciliary beating facilitates particle encounter in feeding forms, but nutritional strategies vary independently of propulsion mechanics. Recent studies indicate that environmental stressors, such as and elevated temperatures, can impair planula locomotion and feeding efficiency, potentially reducing dispersal success and affecting cnidarian population connectivity in changing marine environments as of 2025.

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