The effect of bacteria on planula-larvae settlement and metamorphosis in the octocoral Rhytisma fulvum fulvum

The free-living stages of sedentary organisms are an adaptation that enables immobile species to exploit scattered or transient ecological niches. In the Cnidaria the task of prospecting for and identifying a congenial habitat is consigned to tiny planula larvae or larva-like buds, stages that actually transform into the sessile polyp. However, the sensory equipment of these larvae does not qualify them to locate an appropriate habitat from a distance. They therefore depend on a hierarchy of key stimuli indicative of an environment that is congenial to them; this is exemplified by genera of the Anthozoa (Nematostella, Acropora), Scyphozoa (Cassiopea), and Hydrozoa (Coryne, Proboscidactyla, Hydractinia). In many instances the final stimulus that triggers settlement and metamorphosis derives from substrate-borne bacteria or other biogenic cues which can be explored by mechanochemical sensory cells. Upon stimulation, the sensory cells release, or cause the release of, internal signals such as neuropeptides that can spread throughout the body, triggering decomposition of the larval tissue and acquisition of an adult cellular inventory. Progenitor cells may be preprogrammed to adopt their new tasks quickly. Gregarious settlement favours the exchange of alleles, but also can be a cause of civil war. A rare and spatially restricted substrate must be defended. Cnidarians are able to discriminate between isogeneic and allogeneic members of a community, and may use particular nematocysts to eliminate allogeneic competitors. Paradigms for most of the issues addressed are provided by the hydroid genus Hydractinia.

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The Light-Dependent Behaviour of Planula Larvae of Eunicella Singularis and Corallium Rubrum and its Implication for Octocorallian Ecology

Bijdragen tot de Dierkunde ◽

10.1163/26660644-04901002 ◽

1979 ◽

Vol 49 (1) ◽

pp. 16-30 ◽

Cited By ~ 34

Author(s):

Steven Weinberg

Keyword(s):

Chemical Properties ◽

Corallium Rubrum ◽

Light Gradient ◽

Settlement And Metamorphosis ◽

Dependent Behaviour ◽

Planula Larvae

The behaviour of Mediterranean octocoral planulae was studied in light-dark situations and in a light gradient. Larvae of Eunicella singularis (Esper, 1794) reacted photopositively but it is uncertain which mechanism (klinotaxis or klinokinesis) determines this property. The blind larvae probably possess a dermal light sense, but it cannot be excluded that the yolk contains photosensitive carotenoids while the symbiotic zooxanthellae may also play a role. The photopositive behaviour of planulae of this species explains some aspects of the distributional ecology of adult colonies. It was also found that for the induction of settlement and metamorphosis the chemical properties of a given substratum seem to be far more important than its roughness. Larvae of Corallium rubrum (Linnaeus, 1758) are geonegative and indifferent to light. This latter fact is surprising, since in nature the colonies are exclusively found in dark places. It is supposed, therefore, that tolerance of the colonies rather than larval choice determines light-dependent zonation of this species in nature.

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Bacterial Induction of Settlement and Metamorphosis in the Planula Larvae of Cassiopea andromeda (Cnidaria: Scyphozoa, Rhizostomeae)

Marine Ecology Progress Series ◽

10.3354/meps001021 ◽

1979 ◽

Vol 1 ◽

pp. 21-28 ◽

Cited By ~ 64

Author(s):

R Neumann

Keyword(s):

Settlement And Metamorphosis ◽

Planula Larvae

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Shorter, warmer winters may inhibit production of ephyrae in a population of the moon jellyfish Aurelia aurita

Hydrobiologia ◽

10.1007/s10750-020-04483-9 ◽

2020 ◽

Author(s):

Alexandra Loveridge ◽

Cathy H. Lucas ◽

Kylie A. Pitt

Keyword(s):

Incubation Time ◽

Life Stage ◽

Aurelia Aurita ◽

The Moon ◽

Minimum Period ◽

Moon Jellyfish ◽

Winter Conditions ◽

Scyphozoan Jellyfish ◽

Significant Production ◽

Planula Larvae

AbstractScyphozoan jellyfish blooms display high interannual variability in terms of timing of appearance and size of the bloom. To understand the causes of this variability, the conditions experienced by the polyps prior to the production of ephyrae in the spring were examined. Polyps reared from planula larvae of Aurelia aurita medusae collected from southern England (50°49′58.8; − 1°05′36.9) were incubated under orthogonal combinations of temperature (4, 7, 10 °C) and duration (2, 4, 6, 8 weeks), representing the range of winter conditions in that region, before experiencing an increase to 13 °C. Timing and success of strobilation were recorded. No significant production of ephyrae was observed in any of the 2- and 4-week incubations, or in any 10 °C incubation. Time to first ephyra release decreased with longer winter incubations, and more ephyrae were produced following longer and colder winter simulations. This experiment indicates that A. aurita requires a minimum period of cooler temperatures to strobilate, and contradicts claims that jellyfish populations will be more prevalent in warming oceans, specifically in the context of warmer winter conditions. Such investigations on population-specific ontogeny highlights the need to examine each life stage separately as well as in the context of its environment.

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Formation and Function of the Primary Tube During Settlement and Metamorphosis of the Marine Polychaete Hydroides elegans (Haswell, 1883) (Serpulidae)

Biological Bulletin ◽

10.1086/713623 ◽

2021 ◽

Vol 240 (2) ◽

pp. 82-94

Author(s):

Megan J. Huggett ◽

Eugenio J. Carpizo-Ituarte ◽

Brian T. Nedved ◽

Michael G. Hadfield

Keyword(s):

Hydroides Elegans ◽

Settlement And Metamorphosis ◽

Marine Polychaete ◽

And Function

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How do coral barnacles start their life in their hosts?

Biology Letters ◽

10.1098/rsbl.2016.0124 ◽

2016 ◽

Vol 12 (6) ◽

pp. 20160124 ◽

Cited By ~ 9

Author(s):

Jennie Chien Wen Liu ◽

Jens Thorvald Høeg ◽

Benny K. K. Chan

Keyword(s):

Survival Rate ◽

Coral Tissue ◽

Video Recordings ◽

Settlement And Metamorphosis

Coral-associated invertebrates are the most significant contributors to the diversity of reef ecosystems, but no studies have examined how larvae manage to settle and grow in their coral hosts. Video recordings were used to document this process in the coral barnacle Darwiniella angularis associated with the coral Cyphastrea chalcidicum . Settlement and metamorphosis in feeding juveniles lasted 8–11 days and comprised six phases. The settling cyprid starts by poking its antennules into the tissue of the prospective host (I: probing stage). The coral releases digestive filaments for defence, but tolerating such attack the cyprid penetrates further (II: battling stage). Ecdysis is completed 2 days after settlement (III: carapace detachment). The barnacle becomes embedded deep in the coral tissue while completing metamorphosis between 4 and 6 days (IV: embedding stage), but reappears as a feeding juvenile 8–11 days after settlement (V: emerging stage; VI: feeding stage). Cyprids preferably settle in areas between the coral polyps, where they have a much higher survival rate than on the polyp surfaces.

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