Hubbry Logo
Chelonibia testudinariaChelonibia testudinariaMain
Open search
Chelonibia testudinaria
Community hub
Chelonibia testudinaria
logo
8 pages, 0 posts
0 subscribers
Be the first to start a discussion here.
Be the first to start a discussion here.
Chelonibia testudinaria
Chelonibia testudinaria
Chelonibia testudinaria
View on Wikipedia
from Wikipedia

Chelonibia testudinaria
Scientific classification Edit this classification
Kingdom: Animalia
Phylum: Arthropoda
Class: Thecostraca
Subclass: Cirripedia
Order: Balanomorpha
Family: Chelonibiidae
Genus: Chelonibia
Species:
C. testudinaria
Binomial name
Chelonibia testudinaria
Synonyms[1]
  • Chelonibia manati Gruvel, 1903
  • Chelonibia patula (Ranzani, 1818)

Chelonibia testudinaria is a species of barnacle in the family Chelonibiidae. It is native to the Atlantic Ocean, Mediterranean Sea and Gulf of Mexico where it lives as a symbiont on sea turtles, being particularly abundant on the loggerhead sea turtle.[2]

Taxonomy

[edit]

Historically, the genus Chelonibia contained C. testudinaria, found growing only on sea turtles, and C. patula, a generalist found growing on a range of living hosts including decapods, gastropods, mantis shrimps and sea snakes, but very rarely on sea turtles. It was puzzling why a barnacle that was adaptable to such a broad range of hosts, should avoid the sea turtle. The two are distinguished morphologically as well as by host, and were thought to be different species. However, examination of the genetic differences between the pair showed that they are in fact con-specific.[2]

Description

[edit]
Chelonibia testudinaria top view, hermaphrodite with male attached, by Melissa Merrill
Chelonibia testudinaria underside, by Melissa Merrill

C. patula has a conical shaped shell with smooth plates, with long cirri IV, V and VI. Dwarf males often settle on the plates and are distributed randomly. In contrast, C. testudinaria has a flatter, less conical shape, the cirri IV, V and VI are short, and there are shallow oval depressions on the radii at the junctions of the plates. Dwarf males commonly settle in these depressions.[2]

Size, Growth and Age

[edit]

The growth rate of C. testudinaria follows a non-linear growth pattern where rate of increase in length slows with age.[3] Applying a von Bertalanffy growth model to the population suggests that the maximum achievable size of C. testudinaria on loggerhead turtles in the wild is approximately 70 mm (2.8 in) in rostro-carinal length.[3] The largest individuals reported to date indicate that this species can live for at least 21 months.[3] However, mortality is (at least partially) controlled by the scute sloughing frequency of host turtles, meaning that barnacles living on hosts which shed less frequently, or not at all, may live longer.

Ecology

[edit]

Chelonibia testudinaria are found to attach themselves to shells/objects of the larger organisms from each region of the host's body. C. testudinaria preferentially behaviorally select green turtles as hosts compared to Chelonibia caretta, which select Hawksbill sea turtles as hosts.[4] On a turtle's shell, the greatest water flow is over the front central portion. It has been shown that C. testudinaria can relocate on the turtle's shell,[5] usually towards the optimal position with maximum water flow and thus the greatest filter feeding opportunities. The movement is around 1.4 mm (0.06 in) or less per day and is probably achieved by advancing the shell forward with each increment of growth. Over several months, several scutes can be crossed by these means.[6]

References

[edit]
Revisions and contributorsEdit on WikipediaRead on Wikipedia

Chelonibia testudinaria

View on Grokipedia
from Grokipedia
Chelonibia testudinaria is a sessile, epibiotic in the family Chelonibiidae, renowned as an obligate commensal primarily associated with sea s. This features a shell composed of eight wall plates forming a low-profile, conical structure, often reaching diameters of up to 8.6 cm, with distinctive oval depressions on the radii that house dwarf males. Hermaphroditic and a broadcast spawner, it releases eggs that hatch into planktonic naupliar larvae, which develop through a cypris stage before metamorphosing and settling onto turtle hosts, where they cement themselves using a membranous base. Native to tropical and subtropical neritic waters worldwide, C. testudinaria exhibits a circumglobal distribution, with populations showing between the Pacific and Atlantic basins due to the migratory behaviors of its hosts. It preferentially attaches to the anterior and central scutes of the —though also occurring on plastrons and other regions—of various species, most commonly the loggerhead (Caretta caretta) and green turtle (Chelonia mydas), but also on other genera within the family. As a filter-feeder, it consumes from the , deriving mobility and dispersal from its hosts without causing significant harm, though dense infestations may increase hydrodynamic drag. Notable for its post-settlement locomotion, C. testudinaria can reposition itself across the host's shell, potentially optimizing feeding or avoiding , with recorded movements up to 78.6 mm per year. Its growth rates, averaging around 0.0091 per day, serve as bioindicators of habitat use, revealing extended coastal residency prior to nesting—approximately 76 days in some populations. records trace the species back to the , and archaeological finds from pre-Columbian sites underscore its longstanding ecological and cultural ties to exploitation. Phenotypic variations, such as cirral length and shell shape, reflect host-specific plasticity rather than strict specialization, highlighting its adaptability as a generalist .

Taxonomy and Systematics

Classification

Chelonibia testudinaria belongs to the phylum Arthropoda, subphylum Crustacea, superclass , class , subclass Cirripedia, infraclass , order , superfamily Coronuloidea, family Chelonibiidae, and genus . This placement situates it among the sessile , characterized by a calcareous shell and attachment via a cement gland rather than a peduncle. As a member of the Coronuloidea superfamily, C. testudinaria is distinguished as a coronuloid adapted for epibiosis on mobile marine vertebrates, particularly sea turtles of the family , where it attaches to the host's skin or without causing significant harm. This specialization reflects evolutionary adaptations for commensal lifestyles on large, migrating hosts, differing from free-living or substratum-attached in other Thoracica lineages. The genus encompasses epibiotic species primarily associated with marine , including C. testudinaria on sea turtles, the closely related C. caretta also found on turtles, and C. manati primarily on manatees. These taxa share morphological similarities in their asymmetrical, host-conforming shells but exhibit host-specific variations that have prompted taxonomic debate, with some studies proposing conspecificity under C. testudinaria due to genetic uniformity and .

Taxonomic History

Chelonibia testudinaria was originally described by in 1758 as Lepas testudinaria in the 10th edition of Systema Naturae, based on specimens resembling tortoise shells attached to marine hosts. This initial placement reflected the early understanding of as pedunculate forms within the genus Lepas. Subsequent taxonomic revisions in the transferred the species to new genera as classifications evolved; for instance, it was synonymized under names such as Coronula testudinaria in early works like Lamarck's descriptions, and briefly associated with Platylepas in some historical accounts before stabilization in Chelonibia. The Chelonibia was established by in 1817 to accommodate turtle-associated , with C. testudinaria as the , resolving much of the early nomenclatural confusion. Throughout the , several junior synonyms were proposed based on morphological variations and host preferences, including Chelonibia patula (Ranzani, 1818), Chelonibia caretta (Spengler, 1790), and Chelonibia manati (Gruvel, 1903), which were distinguished by shell shape, size, and attachment sites on versus other hosts like manatees or crabs. These distinctions were debated, as morphological differences were often attributed to rather than true boundaries. Molecular genetic studies in the early provided key insights into these debates. Cheang et al. (2013) analyzed mitochondrial COI and 16S rDNA sequences from C. testudinaria and C. patula specimens across diverse hosts, revealing minimal (less than 1%) despite pronounced morphological and host-specific differences, leading to the conclusion that they represent conspecific variants of a single , with C. testudinaria as the senior . Similarly, phylogeographic analyses by Hayashi et al. (2003) using mitochondrial COI sequences from on loggerhead turtles demonstrated significant genetic structuring, with distinct clades separating Atlantic/Mediterranean populations (showing up to 2.5% divergence) from ones, indicating historical isolation and limited across ocean basins. These findings highlighted cryptic diversity within the nominal and influenced ongoing taxonomic refinements.

Description

Morphology

Chelonibia testudinaria exhibits a distinctive shell morphology adapted for epizoic life on marine turtles. The shell is flattened and irregular, forming a low cone composed of eight parietal plates. This shell can reach a maximum diameter of up to 86 mm, with the external surface featuring shallow oval depressions that serve as attachment sites for dwarf males. The operculum is reduced, and the overall low-profile design facilitates stable adhesion to the host's curved scutes while minimizing hydrodynamic drag during the turtle's movement. The feeding appendages, particularly cirri IV–VI, are notably short in length compared to related species, an adaptation suited for filter feeding in the low-flow boundary layer created by the host turtle's body. This configuration allows efficient capture of suspended particles in the relatively calm waters near the host, where water flow is reduced. Attachment is achieved through a specialized basal structure that initially facilitates contact and subsequently secretes a permanent adhesive to the turtle's scutes via powerful cement glands. These glands enable the barnacle to form a secure, long-term bond, often integrating deeply into the keratin layers of the carapace or plastron. Internally, the includes a spacious mantle cavity that functions in brooding developing eggs and provides space for the positioning of complementary dwarf males. C. testudinaria displays pronounced , with primary individuals being large, simultaneous hermaphrodites capable of self-fertilization, complemented by tiny, specialized males (averaging 6.6 mm in basal diameter) that occupy the shell depressions and contribute via short penises. The coloration of the shell is typically white to gray, blending with the host's and providing against predators.

Size and Growth

Chelonibia testudinaria exhibits a maximum basal of approximately 70 mm, representing its asymptotic size limit under optimal conditions. Growth in this species follows a non-linear pattern described by the , L(t)=L(1eK(tt0))L(t) = L_\infty (1 - e^{-K(t - t_0)}), where L(t)L(t) is the length at time tt, LL_\infty is the asymptotic length (approximately 70 mm), KK is the growth coefficient, and t0t_0 is the theoretical age at zero length. This model captures the initial rapid expansion followed by deceleration as the approaches its size ceiling, based on longitudinal observations of individuals on host turtles. Growth rates of C. testudinaria vary depending on host turtle size and habitat conditions, with empirical data indicating slower progression in oceanic environments compared to coastal ones. For instance, on loggerhead turtles in oceanic environments, the growth coefficient KK has been estimated at 0.0037 day⁻¹, while higher rates of approximately 0.0091 day⁻¹ have been observed on green turtles in coastal areas (as of 2024). In contrast, barnacles on turtles in open ocean settings exhibit reduced rates, likely due to limited nutrient availability and host mobility patterns. These variations highlight the epibiotic nature of the species, where host dynamics directly influence developmental trajectories. The lifespan of C. testudinaria is estimated at least 21 months, often truncated by host molting cycles that dislodge attached individuals. Age determination relies primarily on mark-recapture studies, which track size increments over time to back-calculate settlement age using the von Bertalanffy model. Shell ring counts have also been explored as an alternative method, providing insights into annual growth bands analogous to those in other .

Distribution and Habitat

Geographic Range

Chelonibia testudinaria is native to tropical and subtropical neritic waters worldwide, with a circumglobal distribution including the , , , and (including the region). It has been documented as a common on marine turtles in these areas, reflecting long-standing associations with host species such as loggerhead and green sea turtles, which facilitate its dispersal across coastal and neritic habitats. Natural records in the , including areas off , , and the southeastern Pacific, reflect part of its circumglobal distribution in tropical waters, facilitated by host migration. Archaeological evidence confirms the historical extent of its distribution in the , with wall plates identified in pre-Columbian deposits at sites on , , dating back over 1,000 years. These findings indicate a persistent association with indigenous populations in the region, predating modern human influences and underscoring the species' stability in Atlantic tropical ecosystems. Population densities of C. testudinaria are notably higher in tropical coastal waters, where settlement on hosts occurs preferentially in warm, shallow environments conducive to larval development. Phylogeographic studies reveal distinct genetic structuring, with Atlantic clades showing low divergence among populations from the western Atlantic and Mediterranean, separate from those in the Pacific, reflecting basin-scale divergence due to the migratory behaviors of its hosts.

Host Associations

Chelonibia testudinaria primarily associates with green sea turtles (Chelonia mydas) and loggerhead sea turtles (Caretta caretta), where it is the most frequently reported and densely colonizing . These two host species account for the majority of recorded attachments, with C. testudinaria occurring on up to 100% of loggerheads in certain populations and on approximately 30-40% of greens in others. Less commonly, it attaches to hawksbill sea turtles (Eretmochelys imbricata) and olive ridley sea turtles (Lepidochelys olivacea), as well as other cheloniid species, though densities and prevalence are notably lower on these hosts compared to greens and loggerheads. The exhibits clear preferences for attachment sites on the , particularly the scutes, where it cements to the external layers without penetrating underlying living tissue, ensuring a non-destructive . Posterior and trailing edge scutes are favored in many populations due to optimal water flow that facilitates larval settlement and adult feeding, though central scutes also receive significant colonization influenced by local hydrodynamics and host behavior. Attachments occasionally occur on the plastron margins or soft parts like flippers and head, but these are rare and typically represent less than 10% of total occurrences. This relationship is commensal, with C. testudinaria deriving benefits from the host's mobility for dispersal across ocean basins while imposing no detectable harm, as the superficial cementation aligns with natural shedding cycles. Barnacle densities typically range from 5-15 individuals per but can reach 20-40 or higher on larger adults, varying positively with host size and potentially accumulating during extended migrations when settlement opportunities increase. These patterns overlap geographically with the broad tropical and subtropical ranges of primary hosts, reinforcing the barnacle's distribution.

Biology and Ecology

Life Cycle and Reproduction

The life cycle of Chelonibia testudinaria commences within the mantle cavity of adult hermaphrodites, where fertilized eggs develop into embryos. These hatch as planktonic nauplius I larvae, which are released into the water column; nauplius II larvae are sometimes briefly brooded before dispersal. The larvae progress through six naupliar instars, relying on reserves for , before molting into a non-feeding cyprid . At 25°C, the full larval development spans approximately 9 days. Cyprid larvae seek suitable substrates in coastal waters, where settlement is influenced by host-associated cues, including chemical signals from the keratinous scutes of carapaces. These cues promote attachment to hosts, with cyprids metamorphosing into juveniles within 1–2 days of competency. Post-settlement, juveniles grow on the host, developing into hermaphrodites capable of . The species exhibits , with small dwarf males often attaching to the shell depressions of larger hermaphrodites, functioning as complemental males. Reproduction involves cross-fertilization among hermaphrodites, facilitated by the long, extensible penis that delivers sperm directly into neighboring mantle cavities; self-fertilization does not occur. Dwarf males enhance fertilization efficiency in small mating groups, which average fewer than three individuals, by providing additional spermatogenic capacity. Following internal fertilization, eggs are brooded within the female's mantle cavity until hatching, with each brood yielding 5,000–15,000 larvae. Larval dispersal is limited to 10–100 km due to the short planktonic duration, linking recruitment primarily to areas of turtle aggregation in coastal habitats. The complete life cycle, from egg to reproductive adult and subsequent generations, typically lasts 1–2 years, though high mortality during free-swimming larval stages significantly reduces survival rates.

Behavior and Movement

Adult Chelonibia testudinaria demonstrate directed locomotion across the carapaces of their hosts, allowing them to reposition for improved access to water currents. These movements occur at rates up to 78.6 mm per year, with individuals on loggerhead and green sea turtles advancing primarily in the anterior direction to optimize feeding exposure. Observations on captive hosts and artificial substrates reveal occasional abrupt course alterations of up to 90 degrees, indicating active behavioral control rather than passive displacement by external forces. The propulsion mechanism involves multi-layered, episodic secretion of adhesive cement, which facilitates lifting of the basal membrane and forward advancement of the shell, potentially coordinated with contractions of perimeter muscles. preferentially move against prevailing water flows, with those oriented into currents traveling over four times farther than others in controlled experiments, underscoring the role of hydrodynamics in directing paths. Relocation appears independent of nearby conspecifics, as distances to other individuals do not significantly influence movement patterns. As obligate passive , C. testudinaria extend their cirri into ambient water currents to capture planktonic prey without active beating or pumping motions. Feeding efficiency depends on host-generated flows, with no observed switch to active cirral activity even at low velocities, and relocation is prompted by insufficient current or competitive crowding to seek higher-flow positions on the shell. There is no evidence of behavioral manipulation of the host to enhance flow or oxygenation during diving or surfacing events.

Ecological Role

_Chelonibia testudinaria serves as a foundational species in sea turtle epibiont communities, providing structural complexity that supports the attachment and growth of diverse macro- and microorganisms on turtle carapaces. As the most widespread and least host-selective among sea turtle , it associates with all seven turtle and contributes to community assembly by offering a stable substrate for secondary colonizers. Its larvae actively respond to microbial biofilms on host surfaces, which facilitate initial adhesion and enhance overall . The also functions as an ecological indicator of use and migration patterns, particularly for juveniles. Settlement of C. testudinaria larvae occurs predominantly in coastal waters, and subsequent growth rates on the host reflect residency duration in these areas, serving as proxies for migration timing and behaviors. For instance, growth models derived from natural populations estimate ages up to approximately two years, allowing inferences about the host 's recent movements and preferences over extended periods. Although C. testudinaria may exert indirect effects on host thermoregulation through alterations in hydrodynamics or surface insulation, and potentially influence parasite dynamics by modifying community structure, no significant negative impacts on health have been documented. This reinforces its status as an commensal, benefiting from host mobility without harming the . In conservation contexts, the presence and analysis of C. testudinaria on endangered sea enable non-invasive tracking of population movements and foraging grounds. Stable isotope ratios in shells, which record environmental conditions like and during growth, distinguish foraging areas with high accuracy (up to 94% at regional scales), complementing traditional methods like satellite telemetry and aiding management of .

References

  1. https://www.sealifebase.se/summary/Chelonibia-testudinaria.html
  2. https://link.springer.com/article/10.1007/s00227-025-04683-8
  3. https://journals.[plos](/page/PLOS).org/plosone/article?id=10.1371/journal.pone.0057592
  4. https://www.[researchgate](/page/ResearchGate).net/publication/288977471_The_sea_turtle_barnacle_Chelonibia_testudinaria_Cirripedia_Balanomorpha_Coronuloidea_from_pre-Columbian_deposits_on_San_Salvador_Bahamas
  5. https://pubmed.ncbi.nlm.nih.gov/12969473/
  6. https://www.researchgate.net/publication/288977471_The_sea_turtle_barnacle_Chelonibia_testudinaria_Cirripedia_Balanomorpha_Coronuloidea_from_pre-Columbian_deposits_on_San_Salvador_Bahamas
  7. https://journals.plos.org/plosone/article?id=10.1371/journal.pone.0057592
  8. http://www.marinespecies.org/aphia.php?p=taxdetails&id=106235
  9. http://www.marinespecies.org/aphia.php?p=taxdetails&id=106128
  10. https://www.sealifebase.se/Nomenclature/SpeciesList.php?genus=Chelonibia
  11. https://www.sciencedirect.com/science/article/abs/pii/S0272771423002603
  12. https://www.marinespecies.org/aphia.php?p=taxdetails&id=106235
  13. https://biodiversitylibrary.org/page/41506024
  14. https://doi.org/10.1371/journal.pone.0057592
  15. https://doi.org/10.1046/j.1365-294X.2003.01925.x
  16. https://academic.oup.com/jcb/article/24/3/409/2670381
  17. https://academic.oup.com/zoolinnean/article/193/3/789/6149353
  18. https://gayana.cl/index.php/gn/article/view/260/112
  19. https://pmc.ncbi.nlm.nih.gov/articles/PMC8561864/
  20. https://journal.latakia-univ.edu.sy/index.php/bioscnc/article/download/13277/11686
  21. https://georgehbalazs.com/wp-content/uploads/2019/12/MoriartyEtAl2008Motility.pdf
  22. http://www.rodconnolly.com/uploads/2/5/7/2/25722279/doell_et_al_mar_biol_no_page_s.pdf
  23. https://doi.org/10.1007/s00227-025-04683-8
  24. https://tb.plazi.org/GgServer/html/094887F1FFC3D633FF6313F9FC91A476
  25. https://www.frontiersin.org/journals/ecology-and-evolution/articles/10.3389/fevo.2021.807237/full
  26. http://www.scielo.org.mx/scielo.php?script=sci_arttext&pid=S1870-34532012000400022
  27. https://doi.org/10.7550/rmb.27444
  28. https://www.cambridge.org/core/journals/journal-of-the-marine-biological-association-of-the-united-kingdom/article/abundance-placement-and-sexual-identity-of-the-epizoic-barnacle-chelonibia-testudinaria-relative-to-the-size-and-species-of-host-turtles-in-mabul-island-malaysia/5D24A718E3FC68A55269FA4A16ABB70A
  29. https://www.researchgate.net/publication/232693334_Larval_Development_and_Complemental_Males_in_Chelonibia_Testudinaria_a_Barnacle_Commensal_with_Sea_Turtles
  30. https://onlinelibrary.wiley.com/doi/10.1111/mec.13593
  31. https://www.genaqua.org/uploads/pdf_44.pdf
  32. https://royalsocietypublishing.org/doi/10.1098/rspb.2021.1620
  33. https://academic.oup.com/jcb/article/41/4/ruab053/6398004
  34. https://pmc.ncbi.nlm.nih.gov/articles/PMC8077887/
  35. https://doi.org/10.1093/iob/obab002
  36. https://link.springer.com/article/10.1007/s00227-017-3251-5
  37. https://doi.org/10.1007/s00227-017-3251-5
  38. https://www.nature.com/articles/s41598-019-42983-4
Add your contribution
Related Hubs
User Avatar
No comments yet.