Evidence of fostering in an internally brooding sea anemone

Evidence of alloparental care during the incubation stage has largely been demonstrated for species that incubate their offspring externally in a nest. Alloparental care in these species generally consists of the rearing of mixed broods which contain a low proportion of “foreign” young alongside the host's own offspring. However, many animals, including sea anemones, incubate offspring either on or within their bodies. The beadlet anemone Actinia equina incubate their young internally, and as many sea anemones are capable of reproducing both sexually and asexually, the origin of these internally brooded young has been the subject of much debate. While genetically identical young are brooded internally under the juvenile stage, it is thought that those produced sexually are released as larvae into the water and must return to the gastric cavity of an adult in order for metamorphosis to occur. As the likelihood of a planula larva finding its way back to its parent is slim, this suggests that alloparental care may play a role in the survival of juveniles in this species, a hypothesis first suggested a century ago but rarely tested. Here, using highly polymorphic microsatellite markers, we find evidence of alloparental care in A. equina. Our results indicate that while a high proportion of juveniles were genetically identical to their brooding adult, the remaining juveniles showed stark genetic differences to their brooding adult. These juveniles shared far fewer alleles with their “parent” than expected under sexual reproduction, indicating that they were not the adult's offspring. Furthermore, we found variation in the genetic composition of broods, which consisted either of (a) entirely genetically identical individuals, (b) a mix of unique individuals and clonemates or (c) entirely unique individuals, that is no shared genotype. Our results thus indicate that adult A. equina tolerate the presence of non-offspring within their gastric cavity and furthermore that they may incubate entirely “foreign” broods.     

Direct attachment of eggs to the body wall in the externally brooding sea anemone <Emphasis Type="Italic">Cnidopus japonicus</Emphasis> (Actiniaria; Actiniidae)

The externally brooding sea anemone Cnidopus japonicus (Verrill) inhabits boulder shores between the mid-intertidal and shallow subtidal zones of Mutsu Bay, northern Japan. The anemones usually adhere to the side and under-surfaces of boulders. These anemones keep offspring on the middle part of their body wall during the breeding season. Our observations of spawning behavior in an aquarium revealed that this anemone lays eggs through an elongated oral margin and directly attaches the eggs to its body wall, while making a circular groove on the column. The anemone rotates its elongated oral margin around its body trunk several times and arranges eggs in the circular brooding groove. This behavior suggests that mother anemones, regardless of their attachment position on substrata, are able to attach their offspring effectively to their body wall. Electronic Publication     

Internal brooding affects the spatial structure of intertidal sea anemones in the Arctic-boreal region

Primarily for intertidal species, internal brooding has been reported as a frequently used reproductive strategy of sea anemones. While brooding reduces dispersal, this strategy seems to be beneficial in a harsh environment, such as the intertidal zone. We focused on the species composition, habitat preference and spatial structure of the internally brooding sea anemones, Aulactinia stella and Urticina crassicornis, which both form aggregations in the intertidal zone of the Barents Sea. We analyzed the color patterns of polyps within aggregations and the distance between polyps at different ages. Juveniles settled near the individual parent that released them. The distance between the U. crassicornis parent individual and its juveniles increased with increasing size of the juveniles. This tendency leads to a spatial structure based on the aggregations comprising one or two reproducing individuals that are surrounded by small, identically colored anemones. Our findings revealed that monochromatic aggregations dominated, which suggests that U. crassicornis similar to A. stella may reproduce asexually. A. stella appeared to be more resistant to wave action and more able to colonize the sandy ground compared to U. crassicornis, which prefers large boulders providing shelter, avoids sites exposed to strong wave action and often occurs in dense aggregations in the habitat patches favorable for survival and reproduction. It seems that internal brooding allows for the successful colonization of harsh and heterogeneous habitats, such as the intertidal zone, by counteracting the washout by waves and tidal action.     

Egg mass destroying behaviour of the female giant water bugLethocerus deyrollei Vuillefroy (Heteroptera: Belostomatidae)

After being laid on emergent aquatic vegetation, the egg masses ofLethocerus deyrollei are brooded by the male. In laboratory studies, females were observed to destroy egg masses and ingest the fluid of eggs. Brooding males fought with these attackers at first, but then gave up the defense and mated with them. After destroying the egg masses, females laid new ones at the same sites on the same night or the following one, and males brooded the new offspring. The population density of this species is very low. Most males engage in brooding and cease to become acceptable mates after most of the females lay the first egg masses. It is costly for females to search out free males in the aquatic vegetation. By destroying egg masses, however, individual females can gain new mates with little exertion and can make them brood their own offspring. Furthermore, the survival of their own offspring increases with the elimination of their competitors.     

Sea anemones (Cnidaria,Anthozoa, Actiniaria) from coral reefs in the southern Gulf of Mexico

Seven sea anemone species from coral reefs in the southern Gulf of Mexico are taxonomically diagnosed and images from living specimens including external and internal features, and cnidae are provided. Furthermore, the known distribution ranges from another 10 species are extended. No species records of sea anemones have been previously published in the primary scientific literature for coral reefs in the southern Gulf of Mexico and thus, this study represents the first inventory for the local actiniarian fauna.     

Neurotoxin localization to ectodermal gland cells uncovers an alternative mechanism of venom delivery in sea anemones

Jellyfish, hydras, corals and sea anemones (phylum Cnidaria) are known for their venomous stinging cells, nematocytes, used for prey and defence. Here we show, however, that the potent Type I neurotoxin of the sea anemone Nematostella vectensis, Nv1, is confined to ectodermal gland cells rather than nematocytes. We demonstrate massive Nv1 secretion upon encounter with a crustacean prey. Concomitant discharge of nematocysts probably pierces the prey, expediting toxin penetration. Toxin efficiency in sea water is further demonstrated by the rapid paralysis of fish or crustacean larvae upon application of recombinant Nv1 into their medium. Analysis of other anemone species reveals that in Anthopleura elegantissima, Type I neurotoxins also appear in gland cells, whereas in the common species Anemonia viridis, Type I toxins are localized to both nematocytes and ectodermal gland cells. The nematocyte-based and gland cell-based envenomation mechanisms may reflect substantial differences in the ecology and feeding habits of sea anemone species. Overall, the immunolocalization of neurotoxins to gland cells changes the common view in the literature that sea anemone neurotoxins are produced and delivered only by stinging nematocytes, and raises the possibility that this toxin-secretion mechanism is an ancestral evolutionary state of the venom delivery machinery in sea anemones.     

Assemblage and interaction structure of the anemonefish-anemone mutualism across the Manado region of Sulawesi,Indonesia

The Manado area (Indonesia–North Sulawesi), a marine high diversity hot-spot, hosts 7 species of anemonefish (family Pomacentridae, subfamily Amphiprioniae) living in symbiosis with 9 species of sea anemones (family Stichodactylidae and Actiniidae). This high biological diversity −27% and 80%, respectively, of the total known diversity of anemonefish and sea anemones—allows us to test different hypotheses focused on the obligate mutualism between anemonefish and sea anemones. In the Manado area, species richness of anemones and anemonefish across several sites was not correlated, but all anemones contained at least one fish individual, and there was a strong positive correlation between the numbers of individual anemonefish and anemones. As expected, each fish species had a preferred anemone host; also a partial niche overlap (Pianka’s Index) was often detected. The analysis of unique species composition suggests that competition is not an important factor determining the presence or absence of particular combinations of either anemonefish or host anemones (no evidence of competitive exclusion). The NODF algorithm showed that, at both a regional and local scale, the interaction between anemonefish and host anemones is not significantly nested, as a result of a combination of local conditions with competition, forcing species that regionally are more generalist to become more specialist.     

Development of the deep‐sea viviparous quill worm Leptoecia vivipara (Hyalinoeciinae,Onuphidae, Annelida)

Development of Leptoecia vivipara, a brooding deep‐sea onuphid polychaete with a circum‐Antarctic distribution, was studied using light microscopy, scanning and transmission electron microscopy, and histology. All specimens examined were brooding viviparous females or juveniles; no male gametes were detected. Anterior segments of juvenile and adult worms bore paired compact ovaries with clusters of vitellogenic oocytes. In adults, the mid‐body region formed a chamber containing up to 12 offspring at different stages of development, from oocyte to 13 chaetigers. Mature oocytes freely floated in the coelomic fluid, while embryos and juveniles were enclosed in peritoneal envelopes. Chaetal replacement in juveniles and the morphology of the provisional maxillae are described. Leptoecia vivipara is argued to be a progenetic species with juvenile‐like external morphology and accelerated sexual maturation. These traits may have arisen as adaptations to epibenthic life in a high‐latitude deep‐sea environment affected by seasonal pulses of organic matter.     

The evolution of mating systems in a group of brooding sea anemones (Epiactis)

Summary

The sea anemone genus Epiactis provides an unusually good opportunity to study the evolution of brooding and mating systems. The four Epiactis species on the Pacific coast of North America all brood their offspring up to the juvenile stage, but each has a different combination of internal vs. external brooding and gonochory vs. simultaneous or gynodioecious hermaphroditism. Two of the four species (E. prolifera and E. lisbethae) were indistinguishable with allozymes (20 loci), but could be differentiated using multilocus DNA fingerprinting. Phylogenetic analyses of the allozyme data by distance and parsimony methods using three outgroups suggest that the four nominal Epiactis species are polyphyletic, with the two internal brooders evolving independently of the two external brooders. This topology does not allow inferences about the evolutionary order of hermaphroditism, dioecy and gynodioecy. Separate sexes and obligate outcrossing are of ten believed to be ancestral, with hermaphroditism and the potential for self-fertilization being favored in taxa where restricted dispersal promotes inbreeding. Previous studies of population genetic structure in these Epiactis species is consistent with this hypothesis, as even the cross-fertile species were highly inbred.     

Phylogenetic Relationships among Deep-Sea and Chemosynthetic Sea Anemones: Actinoscyphiidae and Actinostolidae (Actiniaria: Mesomyaria)

Sea anemones (Cnidaria, Actiniaria) are present in all marine ecosystems, including chemosynthetic environments. The high level of endemicity of sea anemones in chemosynthetic environments and the taxonomic confusion in many of the groups to which these animals belong makes their systematic relationships obscure. We use five molecular markers to explore the phylogenetic relationships of the superfamily Mesomyaria, which includes most of the species that live in chemosynthetic, deep-sea, and polar sea habitats and to test the monophyly of the recently defined clades Actinostolina and Chemosynthina. We found that sea anemones of chemosynthetic environments derive from at least two different lineages: one lineage including acontiate deep-sea taxa and the other primarily encompassing shallow-water taxa.     

Highly stable symbioses among western Atlantic brooding corals

The reproductive mode of corals largely determines how zooxanthellae (Symbiodinium spp.) are acquired. Typically, broadcast spawning corals obtain symbionts from the surrounding environment, whereas most brooders transfer symbionts from maternal parent to offspring. Brooding corals are therefore predicted to harbor stable communities of Symbiodinium. This study documents the associations between Symbiodinium spp. and brooding corals in response to seasonal environmental fluctuations. Between March 2002 and December 2005, endosymbiont identity was determined seasonally from replicate colonies (n = 6) of three brooding species, Agaricia agaricites, Porites astreoides and Siderastrea radians, from shallow environments (1–4 m) of the Florida Keys and Bahamas. Symbionts were identified via denaturing gradient gel electrophoresis (DGGE) of the internal transcribed spacer 2 (ITS2) region. No change was detected in the Symbiodinium communities harbored within these brooding colonies. Additionally, no change in symbiosis was observed through a moderate bleaching event, thereby demonstrating that some bleached corals recover without changing symbionts.     

Effects of anemonefish on giant sea anemones: expansion behavior,growth, and survival

The symbiosis between giant sea anemones and anemonefish on coral reefs is well known, but little information exists on impacts of this interaction on the sea anemone host. On a coral reef at Eilat, northern Red Sea, individuals of the sea anemone Entacmaea quadricolor that possessed endemic anemonefish Amphiprion bicinctus expanded their tentacles significantly more frequently than did those lacking anemonefish. When anemonefish were experimentally removed, sea anemone hosts contracted partially. Within 1–4 h in most cases, individuals of the butterflyfish Chaetodon fasciatus arrived and attacked the sea anemones, causing them to contract completely into reef holes. Upon the experimental return of anemonefish, the anemone hosts re-expanded. The long-term growth rate and survival of the sea anemones depended on the size and number of their anemonefish. Over several years, sea anemones possessing small or no fish exhibited negative growth (shrinkage) and eventually disappeared, while those with at least one large fish survived and grew. We conclude that host sea anemones sense the presence of symbiotic anemonefish via chemical and/or mechanical cues, and react by altering their expansion behavior. Host sea anemones that lack anemonefish large enough to defend them against predation may remain contracted in reef holes, unable to feed or expose their tentacles for photosynthesis, resulting in their shrinkage and eventual death.     

Deep-Sea Octopus (Graneledone boreopacifica) Conducts the Longest-Known Egg-Brooding Period of Any Animal

Octopuses typically have a single reproductive period and then they die (semelparity). Once a clutch of fertilized eggs has been produced, the female protects and tends them until they hatch. In most shallow-water species this period of parental care can last from 1 to 3 months, but very little is known about the brooding of deep-living species. In the cold, dark waters of the deep ocean, metabolic processes are often slower than their counterparts at shallower depths. Extrapolations from data on shallow-water octopus species suggest that lower temperatures would prolong embryonic development periods. Likewise, laboratory studies have linked lower temperatures to longer brooding periods in cephalopods, but direct evidence has not been available. We found an opportunity to directly measure the brooding period of the deep-sea octopus Graneledone boreopacifica, in its natural habitat. At 53 months, it is by far the longest egg-brooding period ever reported for any animal species. These surprising results emphasize the selective value of prolonged embryonic development in order to produce competitive hatchlings. They also extend the known boundaries of physiological adaptations for life in the deep sea.     

Juvenile Thalassoma amblycephalum Bleeker (Labridae, Teleostei) dwelling among the tentacles of sea anemones: A cleanerfish with an unusual client?

At least 51 species of fishes are facultative symbionts of sea anemones. Most of the behavioural, ecological and physiological aspects of these associations including their costs and benefits are unknown. We recorded the behaviour and the habitat use of eight assemblages (three or ten specimens each) of the juvenile wrasse Thalassoma amblycephalum dwelling among the tentacles of the two sea anemones Entacmaea quadricolor (clonal type), and Heteractis magnifica at a coral reef in southern Japan during 16 months in daylight hours. There are only two past records of this facultative association, one from east Africa and one from Indonesia. The wrasse remained close to and was occasionally in physical contact with the host when foraging amongst the tentacles. When frightened, they took shelter among corals, away from the host anemone. The wrasse co-existed with the anemonefishes Amphiprion frenatus in E. quadricolor and A. ocellaris in H. magnifica. By using forced host contact tests ex situ and scanning electron microscopy examination of the fish epidermis, we show that juveniles of this wrasse are protected from E. quadricolor, but possibly not from H. magnifica. We suggest that juvenile T. amblycephalum dwelling among the tentacles of sea anemones are cleanerfish with an unusual client, in that they appear to clean mucus and, or, necrotic tissue from the sea anemone host.     

Mucus antigenicity in sea anemones and corals

The antigenicities of external mucus from the sea anemones Stoichactis haddoni, Radianthus ritteri and Gyrostoma hertwigi and from the coral Trachyphyllia geoffroyi were compared. Marked differences were found between species but not within species. The differences suggested that mucus composition might be species specific, and hence that it might be one of the factors used by sea anemones and corals in the recognition of foreign anthozoan species.     

Do Brooding Pythons Recognize their Clutches? Investigating External Cues for Offspring Recognition in the Children's Python,Antaresia childreni

Parental care provides substantial benefits to offspring but exacts a high cost to parents, necessitating the evolution of offspring recognition systems when the risk of misdirected care is high. In species that nest, parents can use cues associated with the offspring (direct offspring recognition) or the nest (indirect offspring recognition) to reduce the risk of misdirected care. Pythons have complex parental care, but a low risk of misdirected care. Thus, we hypothesized that female Children's pythons (Antaresia childreni) use indirect cues to induce and maintain brooding behavior. To test this, we used a series of five clutch manipulations to test the importance of various external brooding cues. Contrary to our hypothesis, we found that female A. childreni are heavily internally motivated to brood, needing only minimal external cues to induce and maintain egg‐brooding behavior. Females were no more likely to brood their own clutch in the original nest as they were to brood a clutch from a conspecific, a pseudoclutch made from only the shells of a conspecific, or their clutch in a novel nest. The only scenario where brooding was reduced, but even then not eliminated, was when the natural clutch was replaced with similarly sized stones. These results suggest that egg recognition in pythons is similar to that of solitary‐nesting birds, which have similar nesting dynamics.     

Flexibility of nutritional strategies within a mutualism: food availability affects algal symbiont productivity in two congeneric sea anemone species

Mutualistic symbioses are common, especially in nutrient-poor environments where an association between hosts and symbionts can allow the symbiotic partners to persist and collectively out-compete non-symbiotic species. Usually these mutualisms are built on an intimate transfer of energy and nutrients (e.g. carbon and nitrogen) between host and symbiont. However, resource availability is not consistent, and the benefit of the symbiotic association can depend on the availability of resources to mutualists. We manipulated the diets of two temperate sea anemone species in the genus Anthopleura in the field and recorded the responses of sea anemones and algal symbionts in the family Symbiodiniaceae to our treatments. Algal symbiont density, symbiont volume and photosynthetic efficiency of symbionts responded to changes in sea anemone diet, but the responses depended on the species of sea anemone. We suggest that temperate sea anemones and their symbionts can respond to changes in anemone diet, modifying the balance between heterotrophy and autotrophy in the symbiosis. Our data support the hypothesis that symbionts are upregulated or downregulated based on food availability, allowing for a flexible nutritional strategy based on external resources.     

Isolation of two novel neuropeptides from sea anemones: the unusual, biologically active L-3-phenyllactyl-Tyr-Arg-Ile-NH2 and its des-phenyllactyl fragment Tyr-Arg-Ile-NH2

Using a radioimmunoassay for the carboxyl-terminal sequence Arg-Val-NH₂, two novel peptides were purified from extracts of the sea anemone Anthopleura elegantissima. These peptides were L-3-phenyllactyl-Tyr-Arg-Ile-NH₂ (name: Antho-RIamide I) and its des-phenyllactyl fragment Tyr-Arg-Ile-NH₂ (Antho-RIamide II). Immunocytochemical staining showed that these peptides were localized in neurons of sea anemones. Application of low concentrations (10⁻⁸ M) of Antho-RIamide I inhibited spontaneous contractions in several muscle groups of sea anemones, whereas Antho-RIamide II was inactive. Antho-RIamide I is the second neuropeptide from sea anemones that bears the unusual, amino-terminal L-3-phenyllactyl blocking group. We suggest that this group renders the peptide resistant against degradation by nonspecific aminopeptidases. In addition, the L-3-phenyllactyl residue might also play a role in receptor binding.     

Prodigies of propagation: the many modes of clonal replication in boloceroidid sea anemones (Cnidaria,Anthozoa, Actiniaria)

Summary

Diverse modes of clonal propagation were documented in tiny zooxanthellate sea anemones from the tropical Pacific. All were boloceroidids, as indicated by the tentacles' basal sphincter and the animals' swimming behavior. In one species, single tentacles were pinched off at the sphincter, shed into the coelenteron, and brooded there while regenerating into minute new polyps in ~4 days. Within a day of release, the propagules fed on live prey and swam by lashing the tentacles. A similar process occurs in another species studied, Bunodeopsis medusoides. In a third species a previously undescribed mode of replication was seen. These anemones bore a primary cycle of tentacles that engaged actively in feeding and swimming, were not shed, and showed no sign of producing polyps. Alternating with these tentacles were fan-like clusters of shorter tentacles that were relatively inactive in feeding and swimming. Despite the sphincter at the base of each of these clustered tentacles, they were never shed singly; instead, each cluster separated as a unit that then regenerated into a new polyp. Two other replicative modes were observed in similar, minute boloceroidid anemones collected together in the same habitat: longitudinal fission, not previously reported in boloceroidids, and pedal scission. Modes of replication in these actinians are more diverse than once thought, but the selective forces behind this variation are so far unexplored. These prolific anemones may regularly be taking advantage of their combination of swimming and regenerative abilities to achieve dispersal, not only by sexually produced larvae, but also by cloned polyps.