Renilla is a genus of Pennatulacea. It is the only genus within the monotypic family Renillidae. Sea pansy is a common name for species in this genus.
Species
The following species are recognized:
-
Renilla amethystina Verrill, 1864
-
Renilla koellikeri Pfeffer, 1886
-
Renilla muelleri Kölliker, 1872
-
Renilla musaica Zamponi & Pérez, 1996
-
Renilla octodentata Zamponi & Pérez, 1996
-
Renilla reniformis (Pallas, 1766)
-
Renilla tentaculata Zamponi, Perez & Capitali, 1996
Anatomy and morphology
Renilla has a distinctive heart shaped colony with a violet or red color.
Pennatulaceans, in the order Pennatulacea, are soft corals in the subclass
Octocorallia.
But Pennatulaceans have different structures and functions from other octocorals.
They form one main polyp, oozooid, which anchors itself onto the seabed using a stalk, peduncle, instead of forming a large colony like most soft corals.
The top of this oozooid grows into a rachis which is the central structure.
From the rachis the Pennatulaceans can grow smaller polyps which have 2 functions; the autozooids which do the feeding, and the siphonozooids which are smaller and aid in movement.
The
Renilla genus and some other pennatulaceans have structures called polyp leaves. These polyp leaves, which hold many autozooids, are extensions that give
Renilla a feather-like appearance. Which is where their common name of Pennatulacea "sea pen" comes from, as these polyp leaves resemble the writing quills.
They consist of bilateral symmetry and a soft outer body, the coelenchyme, with three tissue layers: an outer layer called the epidermis, an inner layer called the
gastrodermis, and a middle layer called the
mesoglea, a jelly-like layer. Inside of a mesoglea, a wide variety of skeletal elements called sclerites are formed.
Distribution and habitat
Sea pansies are geographically worldwide, from the
polar seas to the equatorial
tropics. And they extend across depths from the shallow shores of intertidal flats to the deep ocean trenches of 6100 meters.
Most
Renilla often anchor to soft sediment like sand or mud, but some can even anchor to rocky surfaces.
Benthic zone marine environments are where the sea pansies thrive. Some examples include: continental shelves and slopes, shallow coastal areas, coral reefs, deep-sea plains, and hadal zones which are deep ocean trenches. They can live in all of these environments because of the peduncle, which helps them anchor into soft sediment.
You can find them in abundance in the
Gulf,
Atlantic Ocean, and the coasts of Southern California.
Ecology and behavior
Renilla are predatory
.
Their diet consists of other small animals and larvae.
This is accomplished by stinging their prey and capturing them in the mucus they secret on their surface. Which helps pre-digest their prey for swallowing. Once inside, the food is digested through septal filaments and intracellular digestion.
Renilla are colonial, but they still exhibit some interesting behaviors;
bioluminescence, contraction of their rachis, and polyp withdrawal, which are all thought to be responses of "fear" to external environmental stimuli.
Their life cycle consists of a zygote which develops into planktonic larva.
Metamorphosis involves the formation of
, pharynx, and a septa. Then the larval settlement forms at the aboral end of the
Renilla. They use sexual and asexual reproductions through the budding of secondary polyps on their surface.
They are eaten by the Loggerhead Turtle,
Caretta caretta.
Sea pansies use their calcified sclerites to give their body structure and to defend against predators.
are formed in the mesoglea and they aid in the composition of the colonies. Research
shows that they alter the colonies in response to external stimuli in the environment like predation and water motion. The smaller sclerites provide resistance and stiffness, while the larger sclerites contribute to ward off predators.
In a research observation, field assays of sea pansies and their sclerites were conducted at three depths. It was concluded that the consumption of sea pansies were greatly reduced, due to the sclerites of the
Renilla.
Bioluminescence
Renilla reniformis are model organisms for studying
bioluminescence.
They produce a protein called
luciferase.
This protein involves a calcium triggered reaction which breaks down a chemical called
coelenterazine in the presence of oxygen to form
coelenteramide, carbon dioxide, and light.
Because of this, luciferase can be used as a reporter gene in experiments with cell culture and small animal imaging. As for the
Renilla themselves, there are plenty of hypothesized reasons why they use
bioluminescence. It could serve as a mechanism of defense, an escape response, a way to deter predators, and plenty of other reasons. But no definitive reason has been backed by substantial scientific and statistically significant evidence.
Examples of some other bioluminescent animals include
Firefly, some bacteria, and
.
Fossil record and evolution
The
phylogeny of sea pansies are still being studied, but there are a few difficulties. The genus
Renilla and their order
Sea pen does not have many distinctive physical traits for analysis.
And with the traits they do have, the sea pansies are really delicate. A lot of preserved samples, as fresh specimens are hard to collect, are too damaged for
DNA analysis. But there are some evolutionary histories which we can take note of. Sea pansies have traits like bilateral symmetry and polyp leaves which are features that were definitely modified and evolved features. And there are a lot of similarities between the
Sea pen and
Ellisellidae.
Research
There was research done as a part of project where they studied 3 species in the genus
Renilla,
Renilla muelleri,
Renilla musaica, and
Renilla tentaculata.
They were found in Southern
Brazil along the continental shelf between latitudes 28°S and 34°S. These
Renilla have a big influence on the ecology of that environment such as type of sediment, water temperature, and salinity. But the populations of the
Renilla species are affected by their
Predation (turtles), competitors (
), and human interactions with their habitats. In the study, significant numbers of young
Renilla colonies were observed, so they concluded that these interactions with biotic stimuli are not inhibiting reproduction and growth at an alarming rate.
Research done by studied LBP, a luciferin-binding protein, which has a big part in the
Bioluminescence process in
Renilla reniformis.
The LBP is compact with globular shape and a disulfide bond. When calcium binds to LBP, the protein changes shape exposing the
coelenterazine, which is a luciferin, to the
luciferase enzyme producing light. This reaction is hypothesized to be a response to external stimuli like touch or changes to the environment for defense and/or communication.
