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Tuesday, December 30, 2014

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Saturday, December 13, 2014

2nd Largest Aquarium in the World!

While this is wonderful to behold is it a sustainable solution?

The prettiest CORAL in the Sun.. The Sun Coral


QUICK STATS
Care LevelModerate
TemperamentPeaceful
LightingLow
WaterflowMedium to Strong
PlacementBottom
Water Conditions72-78° F, dKH 8-12, pH 8.1-8.4, sg 1.023-1.025
Color FormYellow
SupplementsCalcium, Strontium, Trace Elements
OriginFiji
FamilyDendrophylliidae



Sun Coral Profile

There are few corals that can stand up to the brilliant colors of the members of the genus Tubastrea, which are known as orange cup corals or sun corals. The most commonly encountered species in the aquarium trade have orangish pink corallites, and bright orangish yellow or white polyps. If you look back at the aquarium literature on the members of this genus, you will find they are considered to be very difficult to keep. But this coral will actually thrive and even reproduce in captivity if you are willing to devote the time to feed them.

Difficulty:

The sun coral is non-photosynthetic — that is, it does not harbor zooxanthellae. All of its nutrition comes from ingested food, namely plankton. The key to keeping Tubastrea colonies alive is to feed the polyps daily (some people have had success with this coral by feeding them several times a week, but they grow and reproduce more if
fed more frequently). If you feed the sun coral smaller meals three or four times a day, the polyps will open more during the day. Feed your sun coral a meaty food, such as finely chopped frozen seafood, frozen fish eggs, chopped frozen mysid shrimp. By alternating food types, you can assure that the polyps continue to open more fully. You can squirt food among the sun coral polyps with a turkey baster. In most cases, the polyps open to feed at night, but if you schedule feeding at the same time every day, the sun coral polyps will begin to open at that time as they await a meal.

Physical description: 

The sun coral has a skeleton that is orange, orange-yellow or red-orange in color, while the polyps are usually bright yellow (it is referred to as a sun coral because of the yellow coloration). It usually grows in round clumps. They have relatively large polyps that are usually retracted during the day and open after dark.
Range: 

Tubastrea species are found in subtropical and tropical coral and rocky reefs around the world. The sun coral is found in a variety of reef habitats, but most often occur in shaded areas of the reef (on pier pilings, in crevices, caves, under overhangs).
Compatibility: 

The sun coral does not have sweeper tentacles and is generally pretty peaceful toward its neighbors. An adjacent coral will have to contact the tentacles of the sun coral polyp to receive potential damage from its stinging cells. This coral is eaten by a specialized snail called Epitonium billeeanum. It is yellow and orange and blends beautifully among the corallites of its prey.

Aquarium conditions: 

The sun coral can be kept in aquariums of various sizes, but it tends to do better in smaller aquariums because it is easier to feed. In fact, the sun coral makes a great coral for a specialized deepwater aquarium that contains some fish from deepwater habitats (these types of displays are becoming fairly commonplace at public aquariums). The sun coral also is not dependent on bright lighting to survive — thus, lighting selection is not a factor. Water movement should be moderate to strong. Water parameters for the sun coral are: calcium 400 to 450 ppm, alkalinity 3.2 to 4.8 meq/L and no phosphates. The Tubastrea corals also tend to grow best at lower water temperatures (between 74 to 78 degrees Fahrenheit).

Care considerations: 

Handle your Tubastrea as little as possible, as rough treatment can damage the polyps. Do not place the sun coral near a sandbed, especially if you keep sand-sifting gobies, as sand that collects on the colony will cause tissue death. If sand gets on your sun coral, blast it off with a jet of water. The sun coral is also sometimes smothered by hair algae, but if you keep it in shaded locations, this is less likely to occur. Another problem faced by Tubastreakeepers are Aiptasia (glass) anemones. These noxious little cnidarians tend to do best in aquariums that are fed often – exactly the situation we find in the sun coral aquarium. These anemones can sting and damage Tubastrea tissue.

Further Identification:

The sun corals we see in the hobby start out as single polyps, but they typically develop into fist-sized colonies that are colored in red to orange to yellow, or uncommonly pink. The tentacles may be the same color as the thin tissue that covers the rest of a colony, and are rather translucent, but sometimes they're lighter in color or even white. The tentacles are also dotted with numerous visible batteries of nematocysts used to capture food items.

While some species have polyps that are independent of each other, the polyps of most sun corals form relatively tall cylinders that rise from a typically ball-like base. Regardless of growth form, the polyps can also completely retract their tentacles when not feeding. In fact, the tentacles often spend several hours at a time closed down, primarily during the day, with a thin sheath of tissue closed over the top of the polyp in a draw-string fashion that keeps them out of sight. This is normal behavior, but do keep in mind that they shouldn't stay closed all of the time. After acclimation to an aquarium, which may take several days, the polyps should open up and take food when it is offered. 

All in all, there are 7 species of sun corals in the genus Tubastraea2, and another 23 species in the genusDendrophyllia3. However, according to Borneman4, any specimens of sun coral seen for sale are most likelyTubastraea faulkneri or T. coccinea, as these are the two most commonly imported species. However, many species of Tubastraea and Dendrophyllia are so similar in appearance that they cannot be identified at the species or even generic level without a close examination of some features that can only be examined when a specimen is dead. To show how futile it can be trying to pin a specific name on some sun coral specimens, here's what I found when I thumbed though a few of the books on my shelf: Fossa and Nilsen5 state "...it is very difficult to distinguish the Dendrophyllia and Tubastraea species from one another. A determination is only possible based on the form and position of the mesenterial filaments, characteristics which are impossible to recognize in living animals." Next to a photograph in Delbeek and Sprung6 the authors state "These look like Dendrophyllia, but cannot be distinguished from Tubastraea without examining the skeletal structure of the corallites." And, Veron7 states "Tubastraea and Dendrophyllia are not distinguishable without examination of the pattern of septal fusion."

So, despite the fact that Tubastraea faulkneri or T. coccinea are supposedly the most common species available.

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Tubastraea coccinea
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Here's one of the sun corals that can easily be identified at the species level. It's Tubastraea diaphana, which is dark-colored but does not form a branching skeleton like T. micrantha

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Closed sun coral







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While identification is difficult, I did find that the polyps of Dendrophyllia are often oval and larger in diameter than those of Tubastraea. This might be a dendrophyllid. Regardless, all of these look-alikes have the same care requirements, and not knowing exactly what is what is unlikely to have any effect on your chances of success or failure with them. 

Water Quality:

Despite being azooxanthellate, sun corals still build a calcium carbonate skeleton just as other stony corals do. And, they're adapted to life in reef waters, so water quality should be the same as it would be for any other stony corals.

The salinity should be in the range of 1.023 to 1.027 as measured using its specific gravity. The temperature should stay in the range of about 72° to 84°F. However, somewhere around 75° to 81°F is really the optimal range you should try for, as this is perfectly suitable for corals and gives some room up and down if your heater/air conditioner should ever fail. The concentration of calcium, the pH, and the alkalinity of the aquarium's water are particularly important for all stony corals too, so all three of these must be maintained at acceptable levels, as well. Keeping calcium concentrations in the range of 400 to 450ppm is optimal, but they can be a bit lower or higher. The pH should optimally be kept around 8.2 to 8.4, and alkalinity should be kept in the range of 7 to 12dKH, although these often go a little higher or lower, as well.

Lastly, you'll also need to keep waterborne nutrients at minimal levels, particularly phosphorus in the form of phosphates. The presence of phosphates can affect the production of calcium carbonate skeletal material by stony corals, and elevated phosphate levels can shut down its production completely. In addition, phosphates also act a great fertilizers, but for all the wrong stuff. Elevated phosphate concentrations can quickly lead to the rapid growth unwanted algae, which can really muck up an aquarium and can even overgrow and kill many corals.

It is particularly important to think about this with respect to sun corals, as they lack zooxanthellae and will require significant amounts of food on a regular basis (covered below). Adding enough food to keep sun corals healthy can easily lead to unsuitable nutrient levels in a closed aquarium system, and that's really the single biggest issue with respect to caring for these corals. It can be difficult enough to keep nutrient levels low in a "regular" reef aquarium, but the constant addition of extra foods can make it even harder. Thus, you'll very likely need to use a good skimmer and perform more frequent and/or larger water changes than normal in order to keep things in check.

For example, you can find two articles online8/9 covering the aquariums of Mike Cao, which are stocked with a variety of azooxanthellate corals. He started with a 20 gallon aquarium, and was doing two 25% water changes a week (yes, that's 200% per month), using activated carbon, running an oversized skimmer, and using ozone in order to keep nutrient levels in check. Then he created a multiple tank system with a total volume of 155 gallons. Now he's doing 22.5% water changes weekly (90% per month), and is still using carbon, a large skimmer, and ozone. That obviously quite demanding. Of course, you may get by just fine doing something much closer to "regular" maintenance if you only have one or a few sun coral specimens in a relatively large aquarium. Regardless, the bottom line is that it's important to remember that the more food that goes in, the more time, effort, and money it's going to take to keep nutrients levels low.

Feeding:

Again, sun corals have no zooxanthellae, so they'll obviously rely on capturing food particles to stay alive. Fortunately, they can feed on relatively large bits of food and can be kept healthy using a variety of things, which can be target fed directly to polyps using a turkey baster or large needleless syringe, or by adding other sorts of foods to the whole tank. Brine shrimp, mysis shrimp, rotifers, copepods, etc. and even bits of chopped fish, clam, or other marine meats can be used. Soaking bits of such foods in a vitamin supplement is often suggested, as well.
While many hobbyists have been successful feeding sun corals every two or three days, some suggest that doing so daily is best. Some hobbyists even use a drip/dosing system to constantly add zooplankton products, oyster eggs, etc. However, I've found that using a turkey baster every other day will get the job done just fine, and numerous other hobbyists have been successful doing the same.
Regardless of the timing, a good way to do the job if a specimen's tentacles aren't extended when you're ready to feed is to put whatever food you're using into a shot glass along with some water from the tank. Swirl the food around a bit (and let it thaw if it's frozen), and suck up a little bit of the water with a baster/syringe, then squirt a little of the water over a specimen. This will typically elicit a feeding response, and the tentacles should emerge within a few minutes. At that point you can go ahead and suck up some of the food and begin squirting it into the waiting tentacles.


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Sun Coral shown closed

Sun corals typically extend their tentacles when feeding, but may spend most of the time with them retracted.
With diligence it's typically possible to train a specimen to eat at a particular time. While many new specimens seem reluctant to extend their tentacles, if you make attempts to feed a specimen at the same time every day for anywhere from a couple of weeks to a couple of months, it'll catch on. Once a specimen begins to consistently open up and feed at that time, it's common to see them opening up in anticipation of food before any is even added. Once that happens, you can obviously skip the teasing step of feeding it and skip straight to adding the food.

Also, when feeding you'll need to see that each polyp receives its own meal. This is especially important for species that have polyps that are not connected together by soft tissue, and for normally connected species that are suffering from any tissue loss between the polyps. Once a polyp has some food it will ingest it and momentarily retract its tentacles. So, it should be easy enough to see if they've all gotten something to eat.

If you aren't giving them enough of what they need, the first clear sign of trouble is often a lack of polyp expansion, which is followed by a deterioration of the thin sheet of tissue that covers the skeletal area between the polyps. Once it starts to go, the rest will soon follow if things aren't changed quickly. To make matters worse, algae will oftentimes show up on any exposed area where the tissue has died, which can lead to further tissue loss and can also make it more difficult for a specimen to recover if feeding is increased. So, it is imperative that you take action if you see any such signs of ill-health.







Current

Sun corals are found in areas where there is sufficient water motion to bring them food, and to keep them clean and free of sediment, too. So, all of them will do best where water flow is moderate to strong. For species that have a layer of tissue connecting the polyps at their base, keep in mind that if the flow is too low sediment can easily settle onto this tissue and collect over time, especially if they're not placed in a vertical or upside position. Thus, you'll need to keep a close watch on any such specimen and make sure that it is getting a strong enough current to prevent this from happening. If sediment does accumulate on a specimen it will typically lead to tissue loss in the covered area.


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Sun Coral

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Sun Coral closed

This is what a sun corals typically look like when unhealthy. The tissue that covers the colonies' bases has disappeared, which often leads to further problems and death if water quality and flow is not improved and/or feeding is not increased.

Aggression

Despite having relatively large batteries of nematocysts lining their tentacles, sun corals are not aggressive and should not cause troubles for other corals in an aquarium. To the contrary, they're more likely to be the victim of a more aggressive species, so pay attention to how close they may be placed to such neighbors.

Placement

Sun corals are typically found in shaded and dark areas, such as the undersides of overhangs and in open caves. However, if space is available, they can also be seen in many other areas, too. I've seen them cover entire walls at times, where there was little or no competition from other types of corals. Regardless of location, they're always firmly attached to the substrate, and most are found in a vertical orientation or upside down. This likely helps to keep sediment from settling and collecting on the tissue covering the areas of a colony down between the polyps. Due to their lack of zooxanthellae, they can also live much deeper than most corals, being found as deep as about 360 feet2.

The absence of light obviously doesn't hurt these corals. So, a specimen can be placed anywhere that there's a sufficient current to keep it clean and where it won't be potentially harmed by other corals. It's okay to place a specimen on the bottom, but it's far better to place it in a vertical or even upside down orientation and attach it to the rockwork using glue or epoxy. Drilling a hole in a colony and attaching it to some live rock with plastic screws is another option that works well when done properly. You do need to keep in mind that no matter where you place a specimen, you'll need to be able to get at it at feeding time without too much trouble, though.

Also note that light certainly won't harm a sun coral as long as it is slowly acclimated. Any specimen should initially be placed where it doesn't get much light at all, then it can slowly be moved out/up into a more brightly lit area over a period of several days to a couple of weeks depending on the intensity of your lighting.

Reproduction and Breeding:

The sun coral will spawn in the home aquarium, and the asexually produced planula will attach and grow. If kept in optimal conditions, they can overtake a medium-sized aquarium in a couple of years. Some of the more branching forms can be fragged by breaking off a section.

Under optimal conditions, sun corals can reproduce quite rapidly in a number of different ways. First, they can produce small versions of themselves, called polyp buds or balls, which grow from a parent polyp until they are large enough/heavy enough to break away. Then they settle somewhere else and begin the formation of a new colony10.

Second, sun corals are hermaphroditic and can also reproduce sexually and/or asexually by producing planulae larvae11/12, which they will also do in aquariums at times. These can drift around an aquarium until they eventually settle and develop into a new colony. So, don't be surprised if new colonies seem to spring up from nowhere in an aquarium containing a well cared for specimen.


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New Coral Polyp

Under optimal conditions, sun corals may reproduce rapidly. These new polyps seem to arise from nowhere where parent colonies produce offspring in aquariums.
And there's more… While I haven't heard of anything like this occurring in an aquarium, some sun corals can produce "runners" that can extend several inches per year from a parent colony. Then, new polyps can develop at the ends of the runners, leading to the formation of a new colony13. Sounds a lot like the stolons that daisy polyps and such form.


Lastly, if you're interested in manual propagation, it can be done. Healthy colonies can be cut into fragments using a small saw or power tool. But, that's another topic.

Lastly, a warning

Before stopping there's one species, Tubastraea micrantha, commonly called the black sun coral, that I have to warn you about. It isn't offered very often, but that's a good thing, as its survival record in aquariums is dismal to say the least.

It looks quite different, forming a branching skeleton covered with fluorescent dark olive green to brownish black tissue and tentacles. It  typically grows in a rather two-dimensional branching form, as well. It can also get rather large, as individual specimens can grow into fan-shaped colonies that may be up to a few feet across at times, with the branches being thicker than a big finger.


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Black Sun Coral
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Black Sun Coral

This is Tubastraea micrantha, the black sun coral, which is apparently exceptionally difficult to keep long-term in aquaria. I found this beautiful specimen off the coast of Sulawesi, Indonesia.
For reasons unknown, the black sun coral apparently requires especially high current, and while I've never tried to keep this species in an aquarium myself, from what others have said it seems that it needs considerably more food input than the other sun corals. While it isn't clear if it's the quantity, quality, or delivery of food in aquariums that's the problem (or all of the above), this species apparently has almost no chance of surviving long-term in captive systems no matter what or how you try to feed. It has been unanimously black-listed by those in the know, and Fossa and Nilsen5 state quite plainly, "We are of the opinion that it is not possible to maintain this species successfully in reef aquaria." I think that should get the point across.
And with that said, it should be clear at this point that, despite their appearances in stores, none of these corals are as easy to care for as the zooxanthellate corals we keep in our aquariums. So avoid the black sun coral completely, and be ready to do what it takes and put forth the extra effort if you think you want to try a sun coral in your tank. If you'll provide them with ample food supplies and good conditions, they can certainly thrive in aquaria and even reproduce, thus there's no need to shy away from the other species of sun coral if you're up to the task.



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Sun Coral




This is quite unusual too, as it's a branching, white azooxanthellate stony coral that I also saw at an aquarium in Japan.

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A few more sun corals.


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Sun Coral
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Sun Coral
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Sun Coral
What is coral? When you see pictures in National Geographic of huge rock like things in the ocean with fish swimming all around, is that coral? Well, sort of. That is a coral reef.

Coral is an animal that belongs to the phylum cnidaria. A phylum is a group that scientists place animals in which share certain characteristics. Cnidarians are radially symmetric, which means that they are the same all the way around, 360 degrees! They are built like sacs with a hole in one end that is surrounded by stinging tentacles. Jellyfish are cnidaria. Now, you are probably thinking, jellyfish don't look anything like what I thought coral was! That's because the most common pictures of coral are colonies called reefs.
During the mating season coral polyp release eggs and sperm into the water (picture below) and when an egg and a sperm meet they form a larva known as a planula.

coral mating
Mountainous star coral (Montastraea faveolata) in the process of releasing
both eggs and sperm. Photo taken by Susan Colley, University of New Orleans in 1990s.


The baby coral looks like a little tiny jellyfish and it floats around in the water until it finds a hard place to attach to, usually a coral reef. Then it lands and starts to build itself a shell. It builds it by combining carbon dioxide (CO2) and calcium (Ca) in the water to make calcium carbonate (CaCO3) also known as limestone. This shell is shaped like a round vase and the coral polyp lives inside.

bright yellow coral polyp
Coral Polyp
(Photo courtesy Jeffrey N. Jeffords)


Coral polyps are primarily nocturnal. At night a coral polyp will stick its tentacles out of its vase and let the tentacles wave in the current. Then, when plankton float by, the coral polyp stings them with its tentacles and brings the plankton inside its shell to have for lunch.

A coral reef is about a million of these individual coral polyp shells all stuck one on top of the other. When coral polyps die, new ones land and grow right on top of the old empty shells. There are over 500 different species of coral. Some look like brains and some like fans and some like the antlers of deer, but they are all made up of tiny coral polyps.


References

  1. Freiwald, A. et al. 2004. Cold-water Coral Reefs: Out of Sight - No Longer Out of Mind. UNEP-WCMC, Cambridge, UK. URL: http://www.unep-wcmc.org/medialibrary/2010/09/10/29fefd54/CWC.pdf
  2. World Register of Marine Species. URL: http://www.marinespecies.org/aphia.php?p=taxdetails&id=267930
  3. Marine Species Identification Portal. URL: http://species-identification.org/species.php?species_group=corals&id=38&menuentry=groepen
  4. Borneman, E. 1997. Tubastraea The Striking Sunflower Coral. URL:http://www.reefs.org/library/aquarium_net/0797/0797_3.html
  5. Fossa, S. and A. Nilsen. 1998. The Modern Coral Reef Aquarium, Volume 2. Birgit Schmettkamp Velag, Bornheim, Germany. 479pp.
  6. Delbeek, J.C. and J. Sprung. 1994. The Reef Aquarium: Volume One. Ricordea Publishing, Coconut Grove, FL. 544pp.
  7. Veron, J.E.N. 2000. Corals of the World, Vol. 2. Australian Institute of Marine Science, Townsville, Australia. 429pp.
  8. Blank, B. 2011. Uhuru's Stellar Azoox Nano Reef. URL: http://reefbuilders.com/2011/04/25/uhurus-azoox-nano-reef/
  9. Cao, M. 2011. Feature Aquarium: Mike Cao's Non-Photosynthetic Reef. URL:http://www.advancedaquarist.com/2011/1/aquarium
  10. Borneman, E. 2001. Aquarium Corals - Selection, Husbandry, and Natural History. T.F.H. Publications, Neptune City, NJ. 464pp.
  11. Glynn, P.W., et al. 2008. Reproductive ecology of the azooxanthellate coral Tubastraea coccinea in the equatorial eastern Pacific: Part V. Dendrophylliidae. Marine Biology 153: 529-544.
  12. Ayre, D.J. and J.M. Resing. 1986. Sexual and asexual production of planulae in reef corals. Marine Biology90:187-190.
  13. Vermeij, M.J.A. 2005. A novel growth strategy allows Tubastrea coccinea to escape small-scale adverse conditions and start over again. Coral Reefs 24:442.

Friday, November 28, 2014

White Spotted Bamboo Shark ~ Reef dwellers ~ EGG

White Bamboo Shark

White Bamboo Shark Egg


Scientific classification
Kingdom:Animalia
Phylum:Chordata
Class:Chondrichthyes
Subclass:Elasmobranchii
Order:Orectolobiformes
Family:Hemiscylliidae
Genus:Chiloscyllium
Species:C. plagiosum

FAST FACTS
Scientific Name: Chiloscyllium plagiosum Size: Up to 33 inches long, Males.  Up to 37 inches, Females
Range: Indo-Pacific West Oceans, Madagascar to Japan to Philippines  
Prey: Small fish and marine invertebrates
Predators: Larger fish, marine mammals and humans
Conservation status: Least Concern

Features

Dorsal fins with convex posterior margins. Color pattern of white and dark spots, with dark bands and a brown body. The coloration is unique in this family making it very simple for identification. The teeth of bamboo sharks are not strongly differentiated. Each tooth has a medial cusp and weak labial root lobes with 26–35 teeth on the upper jaw and 21–32 teeth on the lower jaw. Bamboo Sharks commonly rest on the bottom of their habitat with their head and trunk propped up by resting on their bent and depressed pectoral fins. Whitespotted bamboo sharks have a very distinct dorsal fin that can alter or effect where they choose to live, as well as their mobility methods. 

Feeding

These sharks feed at night, preying on small fish and invertebrates. They have small teeth that can be used for grasping or crushing prey. Soft prey is grasped when the tips of the teeth sink into the flesh, but the teeth pivot backwards when biting hard prey. This protects the tooth tip and allows the flattened front surface of the teeth to form a continuous plate for crushing crabs. Juvenile sharks need a higher intake of carbon than adults sharks, especially during the wet seasons. White spotted bamboo sharks have an advantage in finding carbon sources because they are benthic predators (meaning they prey on fish near the sea-bottom), as opposed to pelagic sharks like the spadenose shark. That, combined with the fact that these species of sharks have, like most sharks, electroreceptors (ampulae of lorenzini) along their snout to help them locate prey that is buried in the sand and mud, makes them very efficient users of detrital carbon resources.


Size:

Male white spotted bamboo sharks can reach up to 33 inches long but typically average between 27-31 inches; females can reach slightly larger sizes of up to 37 inches long, although average between 27-31 inches. 

Range/Distribution:

White Spotted Bamboo sharks are found in the Indo-Pacific West Oceans, as far west as Madagascar, as far north as Japan and as far east as the Philippines.

Habitat:

These sharks make their homes among the shallow waters of coral reef ecosystems.

Prey:

Their diet consists primarily of small fish and marine invertebrates.

Predators:

Predators of this shark species include larger fish, marine mammals, and humans.

Reproduction:
Reaching sexual maturity at approximately 25 inches in length, mating season for these sharks occur between December and January.  Females are oviparous (meaning these sharks lay eggs) and will lay eggs among the coral area between March and May.  The shark pup will hatch after a little over 100 days after the egg is laid.

Whitespotted bamboo sharks are oviparous (egg laying). The eggs are approximately five inches long and hatch after 14 or 15 weeks. The young hatch out at approximately 6 inches in length.  Doug Sweet, curator of fishes at the Belle Isle Aquarium in Detroit reports that in July 2002 a clutch of eggs from a female whitespotted bamboo shark hatched without any apparent fertilization.  This appears to be the first reported example of parthenogenesis in this species.

Virgin Birth

A female Chiloscyllium plagiosum that had no contact with a male for 6 years, gave birth to 3 young at the Belle Isle Aquarium in Detroit, Michigan. There are many theories for this incident but none are confirmed. The species have been found and collected at Ternate Island, Halmahera Island, Indonesia and generally the palearctic region in Asia. Among these theories, the three most likely would be that the female contains both the male and the female reproductive organs; the female has the ability to store sperm for that long; and lastly that the female has somehow stimulated the eggs without sperm, process called parthenogenesis.

White Spotted Bamboo Shark Egg
Threats:
Pressures affecting the white spotted bamboo sharks include fisheries for human consumption and the aquarium trade as well as habitat destruction due to harmful fishing practices, pollution and changes in climate.
Aquarium Conservation:
Some of the White Spotted Bamboo Sharks you see in the Shark Encounters Tank have been born and raised right here at the Mystic Aquarium. Our experienced aquarists breed and raise these species for exhibits as a sustainable way to inspire you to care for and protect our ocean planet while doing the same.