Given its aliases as “Hawaiian Strombus” and “Strombus maculatus,” the Collumbellid euplica snail may not have its nomenclature, especially to the species level, all settled. But that doesn’t change how awesome of a snail it is. As shown below, they reproduce faster than rabbits (or for that matter, faster than my Stomatella hitchhiker snails!) They stay small, graze over rocks, and fit into the smallest nooks and crannies. As the algal population waxes and wanes, so, too, does their population for a harmonized tank. Back when Collumbellid snails were covering my tank, I decided to join the Marine Breeding Initiative. This was my journal entry documenting the breeding. Some of it may be a bit repetitive, but it was required for the breeding documentation.
Collumbellid Snail, also known as Hawaiian Strombus Snail
General Information:
GeneralSpecies:Columbellid euplica
Social Structure: Group
Size of Individuals: 1/2″ long
Age of Individuals: Unknown
Date added to Tank: May 2009
Collumbellid Snail, also known as Hawaiian Strombus Snail
Broodstock Tank Details:
Size of Tank: 40g Substrate Details: Bare bottom Filtration Details: Live Rock, Skimmer, Carbon/GFO Reactor Water Changes: 10% Weekly Water Temperature: 76 degrees Lighting: 6 x 39W T-5 Lighting Cycle: 8 hours on Other Tank Inhabitants: Blue legged crabs, nerites, corals
Broodstock Tank Feeding Details:
Food Types: Formula Two Pellets and DIY Frozen Blended Seafood Feeding Schedule: 2x/week
Spawning Details:
Date of First Spawn: Within days after introduction to the aquarium Spawn Time of Day: Unknown
Dates of Consecutive Spawns: Constantly?
Courtship Details: None apparent yet
Egg Size: <1mm
Egg Color: White
Egg Count: 6-7 in each packet
Collumbellid Snail Egg Masses laid on 1/27/2012
Collumbellid Snail Egg Masses laid on 1/27/2012 – closeup
Collumbellid Snail Egg Masses status on 2/2/2012 – closeup
Collumbellid Snail Egg Masses status on 2/6/2012 – closeup
Hatch Details:
Hatch Date: 2/6/2012
Hatch Time of Day: Unknown
# Days after Spawn: ~28 days
Larvae Description: Adult-like
Hatching Collumbellid snails (from a different spawn)
Larval Tank Details:
Temperature: 76 Size of Larval Tank: 40g Substrate Details: Bare Bottom Other Tank Decor: Live Rock Filtration Details: Live Rock, Skimmer, GFO/Carbon Media Reactor Lighting: 6 x 39W T-5 Lighting Cycle: 8 on Water Changes: 10% weekly
Larval Tank Feeding Details:
Food Types: Algae Feeding Schedule: Constant
Metamorphosis/Settlement:
Date of Settlement Start: N/A Days after Hatch: N/A Date of Settlement End: N/A Description of Fry: Appear as small adults
Juvenile Collumbellid Snail Size Reference with Hydroid
Week-old Juvenile Collumbellid Snail
Grow-Out Tank Details:
Temperature: 76 Size of Grow-Out Tank: 40g Substrate Details: Bare Bottom Other Tank Decor: Live Rock Filtration Details: Live Rock, Skimmer, GFO/Carbon Media Reactor Lighting: 6 x 39W T-5 Lighting Cycle: 8 hr on Water Changes: 10% weekly Size at Transfer: N/A Age at Transfer: N/A
Grow-Out Feeding Details:
Food Types: Algae Feeding Schedule: Constant
Additional Information:
Update 14 June 2012: I’ve found that these snails are able to make some sort of mucus thread that they are able to slide down in order to drop themselves lower in the tank. I also got to watch a snail glide across the top of the water surface, make a thread (only held by the surface tension), and then drop down to the bottom of the tank. It’s quite fascinating to watch!
When I started in the hobby in 2008, there was a legitimate problem with dyed corals and anemones. Sadly, this was not a new problem at that time either. Bleached corals (or even healthy corals) were subjected to dye baths in a dizzying variety of colors, especially in rare shades, such as yellow and blue. Unfortunately, that practice had unsurprisingly deleterious effects on the animals, as the dye interfered with their photosynthesis via zooxanthallae. Fast forward over a decade, and the frequency of dyed corals showing up in local fish stores for sale substantially decreased. So, imagine my shock when a fellow reefkeeper sent me a message about a potentially dyed blue sun coral. The earliest reporting of blue sun corals in the hobby I could find dated back to 2017.
Panic Hits – Artificially Dyed Corals in a Pandemic:
In June 2020, right in the middle of a global pandemic, I was appalled to see reports popping up all over multiple reefkeeping forums and other social media sites claiming that there was a sudden influx of dyed corals. Rehabilitating dyed corals is no picnic; it takes daily feedings, lots of carbon to absorb any free dye, and fast removal of necrotic tissue. Even then, I have never had success with them long-term. Panic started to hit me, as my aquariums were severely neglected thanks to trying to telework and homeschool young children simultaneously. Not only were my tanks ill-prepared, but I couldn’t get the supplies necessary for rehabilitating dying coral. Chlorine bleach and hydrogen peroxide are two of my main staples to keep clean equipment, and they were nonexistent on shelves at the time.
Assessing Blue Sun Coral Health:
Then, on 8 July 2020, a fellow local reefkeeper posted on Facebook that she had just received one of these (on 18 June) and suspected it was dyed and dying. She was concerned that it was affecting her yellow sun coral too, as it seemed to be losing color. So, it was time for me to do some research!
Although I had a lot of questions, my first question was on how to stabilize the coral. Since the owner believed it was dyed, I needed to determine what dyes could have been used so I could figure out how to remove it. Sun corals are often various shades of orange or yellow, so the idea of getting a solid blue coral seemed a bit crazy to me. In other words, I thought that just adding blue dye to a yellow coral would likely result in a greenish coral. However, I’ve used methylene blue extensively, and I know its staining power! It seemed a plausible dye to overcome the yellow.
While researching the various dyes, I found research suggesting that anemones could safely tolerate methylene blue dye, as it did not affect the anemones’ growth or survival. Additionally, the research found that the anemones only retained the methylene blue for approximately six weeks. This gave me hope. Maybe the sun coral was dyed with methylene blue, so it might live if I could feed it adequately (as a non-photosynthetic coral, there is no zooxanthellae interference). I was also prepared with activated carbon to absorb any leaching dye (although this research on using dragonfruit skin was super interesting!)
Bringing the Coral Home:
Only three days later, on 11 July, we met in a mall parking lot, while wearing masks and maintaining social distancing. Even in the hot mid-day sun, the coral was a shocking blue color. I quickly took both the blue and yellow corals home. I followed my standard coral assessment procedure, and several things concerned me.
Determining the Coral’s Condition:
First, I’ve never previously had my hands or equipment get any sort of coloration on them while fragging. Was this the “dye?” I could see blue, yellow, and green colors on this while towel.
Second, the yellow sun coral had a case of “brown jelly disease” starting. This was not good.
Although the tissue appeared dyed, the skeleton of the coral was white as usual. This was not what I expected, especially if the coral was submerged in dye. However, the anemone research referenced above suggests a dye method that may work on just the tissues. At this point, I wasn’t convinced either way on if it was dyed.
Quarantining the Blue Sun Coral:
After initial treatments, I placed the corals into my quarantine tank for observation. I started them on small pellet food, as sometimes that seems easy for corals to digest. Once the coral was regularly eating, I switched it to a varied diet of Roti-Feast, Oyster-Feast, Phyto-Feast, Reef-Roids, and baby mysis shrimp.
Unfortunately, the “brown jelly” spread to my other corals in quarantine, but I was able to keep it from progressing on the yellow sun coral or to the blue sun coral.
About a week after arrival, I was once again convinced that this coral was dyed, as the healing fragmented portion was a dark greenish-yellow. Ah ha!
But this coral decided to just keep me guessing. Wouldn’t the tentacles be blue as well if it was dyed?
Blue Sun Coral Grow-out:
By a month after arrival, I was sure it was natural, as it was just becoming more blue with bright yellowish green polyps. How was that possible?! Methylene blue should’ve mostly dissipated by that point. It had to be natural, right??
Oh but wait… This coral just wants to keep us on the edge of our seats! After four months in my tank, the shadowed areas were turning yellowish green! But, notice the baby polyp – it’s blue! My head was starting to hurt. (And yes, unfortunately I was not feeding the coral as much as necessary, so it was receding. My tanks were quite neglected during COVID-19, as you’ll see by the algae and aiptasia.)
In reviewing the 2017 post photo, the shaded regions display similar coloration.
Spawning of the Blue Sun Coral!
On 12 December 2020, five months after getting the coral, I woke up to find this blue sun coral spawning! And, the planulae were orange (not blue) – suggesting the coloration was natural (and reproduction hopefully not affected).
One of the planulae immediately settled onto the glass, where I watched it eagerly (until it disappeared about three days later).
Blue Sun Coral Spawning
Here are some of the planulae. Unfortunately, none of them survived, or maybe they weren’t even fertilized in the first place.
According to username, “Tennyson,” on Nano-Reef, the dark orange/ brown ones are “duds” while the more yellowish planulae are viable (assuming this is consistent across all sun coral colorations).
(For more reading on sun coral reproduction, please see the references below.)
Although the tank wasn’t exactly clean, both sun corals were appreciating the high nutrient levels!
Final Thoughts:
Although I took this photo under actinic lighting, the blue of the sun coral is very similar to the blue of the Oregon Blue Tort Acropora coral. This amazes me as one is photosynthetic while the other is not. In advertising the Oregon Blue Tort, there are plenty of websites that describe the blue as “so vivid it makes you wonder whether it was injected with an artificial blue pigment,” “often considered the bluest Acropora coral you can buy,” “one of the bluest of the blues,” and “so blue it almost looks fake.” I can see why this blue sun coral was also believed to be dyed!
Conclusion:
Over 13 months later, here it is (under actinics again, so the yellowish green polyps are hard to capture on the camera). I lost four polyps, and a few polyps shrank but are now re-growing. The coloration hasn’t changed a bit. The tissue is brilliant blue, the tentacles are yellowish-green, the oral cavity is yellowish-green, and the center of the polyp is blue. Shaded areas turn yellowish-green, but they regain the brilliant blue color once exposed to light again. This makes me believe it’s a structural blue versus a pigment.
Although I lost four polyps, this gives me an opportunity to clean the skeleton to help identify the coral (to be included at a future point). I am convinced that this coral is not dyed, but I have no explanation for its coloration, especially as blue is rare in nature.
So, let’s celebrate this amazing coral with a happy ending. It was fate that on 25 July 2021, the Washington D.C. Area Marine Aquarist Society (WAMAS) hosted a virtual meeting with guest speaker, Matt Wandell, from the Monterey Bay Aquarium. His topic was on “Use and Care of NPS Corals.” Of course, I had to chat with him about this unusual beauty. I am happy to report that we have made arrangements for at least half of the coral to go on display at the Monterey Bay Aquarium in the fall of 2021 (once the weather cools down).
Mizrahi, D., Navarrete, S. A., and Flores, A. A. V., “Groups travel further: pelagic metamorphosis and polyp clustering allow higher dispersal potential in sun coral propagules”, Coral Reefs, vol. 33, no. 2, pp. 443–448, 2014. https://core.ac.uk/download/pdf/37522324.pdf
Wells, CD, Sebens, KP, “Individual marking of soft-bodied subtidal invertebrates in situ – A novel staining technique applied to the giant plumose anemone Metridium farcimen (Tilesius, 1809),” PLOS ONE 12(11): e0188263, 21 November 2017. https://doi.org/10.1371/journal.pone.0188263
