Have you ever wondered why some corals are more colorful than others… That is because some corals increase the production of colourful protein pigments (such as these purple tips) when they are exposed to more intense sunlight and this colony, of a branching Acropora, is simply amazing. Scientist have found that these pink, blue and/or purple proteins act as sunscreens for the corals by removing substantial light components that might otherwise become harmful to the algae hosted in their tissue. Corals rely on these light-dependent miniature plants, the so-called zooxanthellae, since they provide a substantial amount of food. Furthermore, these tips consist of a particular polyp called an “apical polyp”. It is responsible of the growth of the particular branch. For instance, it will reproduce asexually by cloning itself, potentially an infinite number of times throughout its lifetime. Here and there, one of the “radial polyps” will differentiate becoming a new apical polyp with its distinguished purple color, driving the growth of a new branch.
Humans get a sun tan – corals become more colourful.
Look at this amazing visitor to your frame! These are just a few of the species that would often visit the coral frames and are extremely helpful at times when cleaning the frames. This species is called the Moon Wrasse (Thalassoma lunare) a very typical and brightly colored species of fish found in the Maldives. It belongs to the wrasse family which consists of over 600 described species that range on average around 20 cm although the Humphead and Napoleon wrasse can grow up to 2 meters! They are carnivores by nature, feeding on a wide range of small invertebrates such as crabs or snails. Many smaller wrasses follow the feeding trails of larger fish, picking up invertebrates disturbed by their passing.
Have you ever wondered why some corals are more colorful than others… That is because some corals increase the production of colourful protein pigments (such as these purple tips) when they are exposed to more intense sunlight and this colony, of a branching Acropora, is simply amazing. Scientist have found that these pink, blue and/or purple proteins act as sunscreens for the corals by removing substantial light components that might otherwise become harmful to the algae hosted in their tissue. Corals rely on these light-dependent miniature plants, the so-called zooxanthellae, since they provide a substantial amount of food. Furthermore, these tips consist of a particular polyp called an “apical polyp”. It is responsible of the growth of the particular branch. For instance, it will reproduce asexually by cloning itself, potentially an infinite number of times throughout its lifetime. Here and there, one of the “radial polyps” will differentiate becoming a new apical polyp with its distinguished purple color, driving the growth of a new branch.
As you can see from the picture, your coral frame are colonized by some little, brown and green organisms called Ascidia. The species is called Didemnum molle (also known as the green barrel sea squirt or the green reef sea-squirt.) and is very common in the Indo-Pacific area. Ascidia is a filter-feeder, feeding on suspended plankton and detritus and its green color is given by the algae living in symbiosis with them, in this way the algae is protected by the predation and the Ascidia can receive energy from its little hosts. Luckily they don’t possess any threat to the corals when they are few in numbers, however they can colonize quite quickly on the frames through asexual budding, as such they are regularly removed to minimize competition with growing corals.
Have you ever wondered how do corals grow bigger or how their branches are getting longer? Coral reefs are mainly built by stony or hard corals, together with their endosymbiotic algae (algae living in the corals), zooxanthellae. To give you some information on how the calcification process works. The main elements needed to build the skeleton are Ca2+ (Calcium ions) and DIC (Dissolved Inorganic Carbon). Both of these elements are transported into a specific area of the coral called the “calcifying region”, which is situated under each single polyp. Here, the calcium carbonate (CaCO3) is formed throughout a chemical reaction. Finally, the calcium carbonate (or technically crystals of aragonite) is deposited to form the skeleton. The process involves the polyp’s cells and the Zooxanthellae, and by the mutualistic work of these two counterparts the skeleton is formed. However, if for any reasons (i.e. high temperature) one of the two parts is not working properly the process stops and the coral may die.
This beautiful creature is known as the reeftop pipefish (Corythoichthys haematopterus), also known as the Bloodspot pipefish, Dragonface Pipefish or Yellowstreaked Pipefish. The Pipefish is in the same family as Seahorses and has the same head and snout. Pipefish feed on small animals that life on the bottom of the seafloor; they use their snout like a straw to suck up their food. They are often difficult to see when they are on the sandy seafloor, as their colors camouflage them very well. They are a common species around the coral frames and are often spotted moving in and out of the frame. They can grow up to 30 cm in length and are usually found at depths around 0 – 20 meters. An interesting fact is that Pipefish are like seahorses in that the male gives birth! The female deposits their eggs after fertilization into the males pouch, located under their tail to incubate the eggs for one month before giving birth.
Check out this intriguing creature we found on your coral frame… this is called a hermit crab, one of the 1110 species found today, so we cannot be too sure about the specific species. These specific groups of animals are called marine hermit crabs and they spend most of their life underwater. Most species have long, spirally curved abdomens which are soft, unlike their calcified relatives. This soft abdomen is protected from predators by a salvaged empty seashells usually abandoned by other gastropods. Often times they will use the shells of sea snails or other hermit crabs. Like all hermit crabs, as they grow bigger, they require bigger shells and often times when resources are limited there can be some competition between crabs for new shells. Their diets consist of algae and plankton but they are also omnivorous and depend on a reasonable amount of scavenging. They find the easiest ways to collect the plankton is by utilizing their claws to guide food into their mouths and suck in anything that is within reach.
This is your 6 month frame progress update. Unfortunately your frame is struggling!
Looking at your frame, we can notice lots of bleached corals as well as dead coral fragments. Unfortunately the warm months of March, April and May have been really rough on your frame. We are trying our best to keep the damage to a minimum by cleaning harmful algae off bleached corals. We also started moving extremely bleached frames under the Water Villa Restaurant to protect them from further damage through UV radiation. We hope to see some of your bleached corals recover over the next couple of months, but it will be a slow process. Now that the water temperatures are slightly decreasing the next step of action will be to replace dead coral fragments with new healthy fragments.
Over the following months we will continue with maintenance to keep harmful algae and predators off your frame and to give your frame the best chance for successful growth.
We have some unfortunate news this month as we are starting to see some evidence of bleaching around the coral frames. Coral bleaching can be ascribed to warming ocean waters for extended periods of time where the symbiotic algae (Zooxanthellae) living inside the tissue coral is expelled by their host and in turn leave behind a bleaching white skeleton. This algae shares a mutualistic relationship with the corals; the coral provides shelter to the algae and in turn the algae can provide as much as 90% of the nutrients produced by photosynthesis which is used towards their growth. Corals can survive bleaching events such as this, but if they are subject to more stress or prolonged heated waters, they will surely die. Unfortunately, your frame is also showing minor signs of bleaching of around 10%. This is a rough estimate based on the amount of bleaching fragments of the entire frame. As you can see from the images, their white skeletons are not something anyone can miss, especially in the water. The degree of bleaching on your frame is not too serious as we only saw these fragments in particular that seemed a little stressed and pale in color.
Unfortunately, there is not much we can do at this stage, but wait to see whether they recover or not in the next months. Should they not recover and they are completely dead, they will be removed from the frame and replaced with new live ones. This is of course a major setback for our coral conservation project, but it is also the reality we are dealing with today.
Just look at this amazing creature that lives on your frame. These are Christmas tree worms (Spirobranchus giganteus), a species that belongs to the tube-building polychaete worms. Its name refers to the two chromatically hued spiral structures that we can see here in the image. These multicolored spirals are highly modified structures for feeding and respiration and can also be various colors. They are known to occur throughout tropical oceans and commonly found embedded entirely in heads of massive corals, such as stony and brain corals but not unusual to find them in Acropora corals such as these. Similar to other members of this family, they secrete a calcareous tube around its body which serves as protection. When danger is close, they will retract into these tubes and only come out again after a few minutes. These worms luckily didn’t seem to mind that I was taking this beautiful picture of them
Looking closely to one particular fragment branch on your fame, you can see that there is some damage to the coral polyps here due to some predation. Since we are creating entire new reefs where there have been none before, we can see lots of fish species moving around the frames. Often times we can see coral-eating fish such as the Titan triggerfish, parrotfish or even some small wrasse species that is biting on the coral polyps and leave behind scars such as these. Many fish spend time grazing on corals due to the high content of algae, especially dead corals where you can see their scratch-bite marks, but there are some species that feed on live coral too. Luckily the damage on this fragment is not something to be concerned about, during maintenance we check to see if the condition improves or not and keep it free from invasive algae. We should see a quick recovery for this kind of damage.
Coral reefs are built and made up of thousands of tiny animals called coral “polyps” that can live individually (like many mushroom corals do) or in large colonies that comprise an entire reef structure. A polyp has a sac-like body and an opening, or mouth, encircled by stinging tentacles called nematocysts or cnidae (imagine an upside down jellyfish). The polyp extracts calcium and carbonate ions from seawater to build itself a hard, cup-shaped skeleton made of calcium carbonate (limestone). This limestone skeleton protects the soft, delicate body of the polyp. Coral polyps are usually nocturnal, meaning that they stay inside their skeletons during the day. At night, polyps extend their tentacles to feed. Most coral polyps have clear bodies whereas their skeletons are completely white, like human bones. Generally, their brilliant color comes from the zooxanthellae (tiny algae) living inside their tissues. Several million zooxanthellae live and produce pigments in just one square inch of coral. These pigments are visible through the clear body of the polyp and are what gives coral its beautiful color.
As you know we use plastic cable ties to attach fragments of corals to the iron bar structure which is very important for stability is necessary for corals to grow. The branching Acropora living on your frame is slowly growing over the cable tie. You can see part of the light-brown skeleton partially covering the two cable ties. In fact, it will be part of its skeleton forever. Plastic cable ties are a good compromise for attaching corals to the structure, since material is cheap, resistant and the results are great. However, we are following the upcoming researches to improve our technique in order to reduce the use of plastic.
Here you will see the first view of your frame, you will notice that all the plastic ties used to attach the fragments have been cut off. Some information about the fragments on your frame, 90 percent of them belong to the genus Acropora, which is a large and diverse group of hard corals with nearly 149 species described. These are well known to have a fast growth rate, between 13 and 15 cm every year. Your coral frame is now grouped with other very new frames by the Watervilla Restaurant in order to create a nice coral nursery. We will keep monitoring the colonies and updating you on the status of your corals! Thank you for supporting this project!
