The above photo is of Apolemia lanosa a type of siphonophore belonging to phylum Cnidaria that also includes corals and jellies.  It’s basically the ocean’s way of celebrating Christmas all year long.  Like many other Cnidarians, siphonophores bud new individuals—exact clones themselves.  In a manner similar to Christmas elves although this is not proven by science. In the case of some Cnidarians, the clones never leave home so family never has to travel for the holidays.  In some Cnidarians, clones in the colony will specialize but among siphonophores the specialization is unrivaled. Clones will specialize for feeding, defense, locomotion or reproduction. The feeding clones catch food by tentacles equipped with cells that shoot out poisonous harpoons stinging and stunning their prey.  In the most popular of all siphonophores, the Portuguese man o’ war, with a large gas filled buoyant bladder adapted for catching the wind and sailing.  Interestingly, all the clones are attached via a single digestive and circulatory system.  Research is still needed on which clones are adapted for drinking eggnog, singing carols, and wrapping gifts.

Apolemia belongs to a special set physonect siphonophores. Recently Dr. Stefan Siebert at Brown University with Phil Pugh (NOC), Steven Haddock (MBARI), and Casey Dunn (Brown University) described two new species in the family Apolemiidae, for which only three species had been described previously.  The species of Apolemiidae may be record holders for the longest animals on earth.

Fragments of specimens of this family with a length of over 30 meters have been reported from the French Mediterranean coast in the bay of Villefranche-sur-Mer.

In most physonect siphonophores clones are arranged along a central stem, it itself the founding clone developed from a single egg.  At the front end, is a group of clones that are propulsion clones. Basically, Santa’s reindeer if Dasher, Dancer, Prancer, Vixen were all budded from and identical to Santa.  In the larger and remaining region of a physonect siphonophore, one can find the clones for engaging in the spirit of Christmas, eating and…  New clones are formed in special growth regions of the siphonophore.  As new clones are formed the old clones get pushed down the line. But Apolemia species are special.  In addition to other clones Apolemia can also add new feeding clones along the entire length of the stem.

This fact might be the reason why members of this particular family of siphonophores can grow to such tremendous length.

Research by Siebert in collaboration with others uses these as the perfect organism to understand how an organism develops (check out some of their work which features DSN’s Rebecca Helm). Basically Apolemia is the biological Christmas gift that keeps on giving.

From a developmental point of view siphonophores are a very interesting and promising system since collection of a single colony gives the researcher access to complete developmental series of particular bodies – from the youngest bud to a mature body in older parts of the colony. Our work aims at increasing our understanding on how these different bodies can evolve using the same genome.

Siebert’s work looks for when genes turn on and off to trigger the growth and specialization of all the clones.  But the road is not easy going

 The interesting questions to be answered are, how to we get from one body type to another? How are genes sets differentially utilized to make body A or body type B and what has happened on the molecular level when evolutionary novelties, i.e. a new body type, can be observed in a particular [group] of siphonophores.

 A special thanks to Stefan Siebert who provided the quotes and a lesson on siphonorphore biology to me.

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Like many jelly species, members of the group Hydra have a polyp stage that reproduces asexually by budding off little clones, and people have speculated this could last for thousands of years. So Daniel E. Martínez closely watched members of one species, Hydra vulgaris, for 4 years, and in that time very few animals died [3]. Dr. Martínez suggests that since animals that start reproducing only a few days after birth, such as Hydra, tend to kick the bucket earlier than animals that wait, 4 years is a pretty long time. But does that really mean they’re immortal?

More information is needed about Hydra, but it’s not the only species people keep for decades, nor the only species that could help us understand if some jellies may last forever. So, to get to the bottom of this I polled the experts.  I sent emails to some of the top jelly aquarists asking: do polyp clone populations change over time?

Most public aquaria display jellyfish, and to do this they take advantage of the peculiar jelly life cycle.  The life of jellies is broken into two parts: the polyp-type stage, which looks like Hydra and divides asexually, and the jelly stage, which grows from polyps and gets on with the busy act of sexual reproduction. To keep the number of exhibit jellies constant, aquarists use polyps as a literal clone bank, cueing them to produce more jellies as needed.

And do these clone banks ever change or grow old? The answer was a unanimous “yeah, kinda.” According to aquarists at both the Monterey Bay Aquarium and the New England Aquarium, over about six years clonal populations do get “tired.” They become more fragile, don’t produce healthy jellies, and stop responding to environmental signals. Many aquarists replace their polyp stocks with new baby polyps quite regularly, so that none of this fickleness gets in the way of jelly production. The whole colony may continue to kick, but it gets more and more fragile over time. To me, this sounds a lot like aging.

When humans die it’s not because a special gene turns on that shouts: “YOUR TIME IS UP!” Rather, little things start breaking all over, cells stop dividing and those that do accumulate mutations, this is why getting older is often accompanied by all sorts of biological issues. The truth is, accumulating mutations and cell gunk isn’t something special about aging people, even clone lines of E. coli bacteria accumulate harmful cellular products over time [4]. This is just the cost of being alive. So does the “immortal jellyfish” Turritopsis dohrnii really last forever, even with all this gunk slowly working its way into its cells and genomes?

I’m not convinced. Just because you can reverse your life cycle or clone yourself doesn’t mean you’ve got a get out of jail free card for all the consequences that come with being a living thing in the first place. You are still subject to that nasty gunk build up.  Some species like Hydra vulvaris may have evolved ways to clean this gunk and beat the system, but the jury is still out on how, and for how long. While the “immortal” jellyfish Turritopsis dohrnii may be able to turn back its life cycle, it may not escape the inevitable slowing down that comes with age. In other words, while reversing your fate and escaping death for a short while may be a neat trick, it doesn’t guarantee immortality.

Work Cited

[1] Stefano Piraino, Ferdinando Boero, Brigitte Aeschbach and Volker Schmid (1996). Reversing the Life Cycle: Medusae Transforming into Polyps and Cell Transdifferentiation in Turritopsis nutricula (Cnidaria, Hydrozoa). Biological Bulletin , Vol. 190, No. 3 (Jun., 1996), pp. 302-312

[2] Stefano Piraino, Ferdinando Boero, Brigitte Aeschbach and Volker Schmid (1996). Reversing the Life Cycle: Medusae Transforming into Polyps and Cell Transdifferentiation in Turritopsis nutricula (Cnidaria, Hydrozoa). Biological Bulletin vol. 190, no. 3  pp 302-312

[3] Martínez DE (1998). Mortality patterns suggest lack of senescence in hydra. Exp Gerontol. vol 33 no 3 pp 217-25.

[4] Ariel B. Lindner, Richard Madden, Alice Demarez, Eric J. Stewart and François Taddei (2008). Asymmetric segregation of protein aggregates is associated with cellular aging and rejuvenation. PNAS vol. 105 no. 8 pp 3076-3081 doi: 10.1073/pnas.0708931105

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