WHY FIVE? Mysteries in Symmetry!

It is May 5, 2015 as I write this. Thanks to a recent question from my Twitter followers (thanks @MissMolaMola!) I got it in my head that this month and indeed TODAY would be a great day to address one of the great fundamental questions in the evolution of echinoderms 

WHY DO Echinoderms have FIVE PART (pentameral) SYMMETRY???

Adult echinoderms have one of the more unusual features among "higher" metazoans in that adults have a form of radial symmetry called 5 part or pentameral symmetry. So, not only is the body radiating from a central axis but it does so in increments of five. This is in stark contrast to most other animals which show bilateral symmetry: two sides with paired limbs on either side as well as a head with centralized sensory apparatus. 

Most times, non-bilateral symmetry (radial and absence of symmetry) is associated with "lower" or simpler metazoans. Mainly sponges and cnidiarians (jellyfishes, corals, etc.). And indeed in much of the 19th Century echinoderms were considered as PART of this lower "grade" of animals called the Radiata (more here).  

But subsequent data over the centuries, first from development and later from DNA has verified without a doubt that echinoderms have complex tissues, organs and are actually more closely related to chordates (e.g., humans, fishes, etc.) than they are to "simple" animals. ALL adult echinoderms display radial symmetry (although as we'll see there is some modification).

So, therein begs the question: WHY go "back" to have a body type that is seen primarily in simpler animals??  and why five? 

(and in science "why" means what is the evolutionary reason, there is no metaphysics at play..)

The answer to this question is... elusive. But here are some facts. 

1. Larval Forms are Bilateral

thanks to Dr. Allison Gong for the pic

This is a fundamental part of echinoderm biology and part of what classifies them among the more complex animals. 

ALL living echinoderms have a larval stage which is bilateral. These bilateral forms settle onto the sea bottom (or wherever) and develop pentameral symmetry as adults. 

This is an important part of understanding their evolution, since life modes observed at these early stages can sometimes be reflective of the early evolutionary stages of these animals. 

In this case, it shows that it shares the same morphology as other complicated animals in that it has bilateral symmetry in the same way that worms, arthropods, mollusks, and other "complicated" animals do. 

Thus, pentameral symmetry is a SECONDARY characteristic "on top of" the "basic" bilateral symmetry. It had to acquire this feature during its evolutionary development.  And so when we ask WHY do they have pentameral symmetry? We are also asking HOW/WHY did this unusual symmetry evolve in echinoderms??? Figuratively speaking, it adds an additional step to its evolution by appearing with this body form. What's the deal with that??

2. Are all adult echinoderms purely pentameral? 
You may suddenly realize "AHA! I GOT YOU!  SOME echinoderms show kind of BILATERAL SYMMETRY AS ADULTS!" Don't they???

Um. Well, yes and no.

Two notable exceptions: "irregular" urchins and sea cucumbers. Both are unusual in that most are detritivores or process sediment for food.  Therefore requiring movement in one direction.

                             

Bilateral symmetry is associated with directed movement and so, its presence is often associated with organisms which show some kind of single-directed motion.

I've written about "irregular" urchins here.. basically a bunch of skeletal modifications that are part of the morphology in sea urchins that live/feed on sediment...(again, motion in a single direction)

What happens in "irregular urchins is that yet ANOTHER "symmetry" is overlain/"added" over the radial symmetry.. So, these animals go from bilateral (as larvae)

and eventually develop bilateral symmetry IN ADDITION to pentameral symmetry...  This is called SECONDARY bilateral symmetry.
                                         
Sea cucumbers  show bilateral symmetry (right and left sides) along their worm-like bodies. Presumably, again because they have a life mode which requires them to show directed movement in order to feed.

But you can see this five-part symmetry along the longitudinal axis of the body.. down the mouth or looking up the anus! Here we have anal teeth nicely showing pentameral symmetry!! (what are anal teeth? go here to find out)

So, all adult modern echinoderms show SOME kind of 5-part or pentameral symmetry. Even if it doesn't always look like it.

BUT was that ALWAYS the case????

3. Not all echinoderms were pentameral...
I've mentioned in past blogs that the echinoderms of the Paleozoic were mostly NOTHING like they
are today. 

Some such as this helicoplacoid (which I wrote about here) were actually asymmetrical! 

Others, such as this carpoid echinoderm laid on the bottom with one side...

Belemnocystites wetherbyi by avancna on DeviantArt

and indeed some of the fossils which have been proposed as among of the oldest known echinoderms (e.g. Tribrachidium) show three-part symmetry...

So, based on fossils like these, much of the older traditional paleontology suggested that echinoderms were evolving from different "grades" of symmetry.. 3-part to 5-part, etc. 

Modern approaches including  cladistics and more intensive scrutiny to characters were applied... and it turned out the "family tree" of echinoderm evolution was much more complicated than simply being different "grades" of symmetry....

Here are some phylogenetic trees from Mooi (2001)-a review of fossil echinoderm phylogeny... which show just how complicated the relationships can be. And that the question of symmetry in Paleozoic forms can be quite complicated.

Some of the oldest lineages look like they don't have pentameral symmetry but in some trees, asymmetry is an acquired characteristic. Something that evolves later rather than a feature of early echinoderms..

One of the lesssons from paleontology though: symmetry in echinoderms might be part of a changing/evolving body form through time rather than some discrete, adaptive event.

4. A crystalographic/developmental explanation? 

from Nichols 1967

Perhaps one of the most involved explanations of pentameral symmetry which was applied to LIVING echinoderms came from a series of papers outlined by echinoderm biologist Dave Nichols in the late 1960s. He followed up on an original notion by a previous worker who pursued crystallographic arguments:  

The pentagon is the only regular polygon for which the number of sides equals the number of diagonals...In all echinoderms whose development has been studied, the first plates to form include those at the apex of the animal-that is, at the pole opposite to the mouth. These plates are required to produce a body with basically a circular cross-section, and in order to reduce the planes of potential weakness across them, the sutures between them must be as few and as short as possible. Only with a pentamerous arrangement are these requirements satisfied.  from Nichols 1967, New Scientist 14, pg. 547 (italics mine). 

So, basically during development, Nichols arguments that the arrangement as seen above in "b"the theoretical  development of these plates that this is essentially the strongest arrangement of these plates. Four or six plate arrangements (a or c) presents a clear breakage plane whereas the 5-plate arrangement does not.

He goes on to apply this structural explanation to various living echinoderms, but unfortunately, even Nichols admits, that this idea was experimentally untestable.

5. Some insight from Evo-Devo! 
Some of the more intriguing clues into the "How did pentameral symmetry evolve?" are almost certainly going to be found from the field of "Evo-Devo", which is short for "Evolution & Development". A multidisciplinary field which integrates genetics and developmental biology. Which genes "turn on" or express certain characters??

One paper by Arenas-Mena et al. (2000) from Andy Cameron's lab at the California Institute of Technology in Development  shows expression of the Hox cluster of genes in the purple sea urchin, Strongylocentrotus purpuratus.

Basically, what this colorful digram shows is the gene represented by color and what part of the larval form is being "expressed" or developing in the larvae. So, there is easily a LONG description of how each gene triggers a different body cavity or other structure to be expressed or to be formed but long story short: These are all features "tracked" from a bilateral larvae which are observed in the pentameral body form.

There has undoubtedly been more work on this topic, but honestly, this was about all I was going to gather in the time I had and its a VERY involved field!

So, developmental perspectives give us SOME perspective into the process and its a start, but ultimately there remain a LOT of questions.

1. Is pentameral symmetry evolutionarily adaptive?
2. How is it relevant to the calcium carbonate skeleton? If at all? 
3. Under what conditions does pentameral symmetry evolve from an ancestral form with bilateral symmetry?
4. How would this shift/expression be observed in early echinoderms? Like crinoids? 
5. Does the "5 part crystal stability" theory have any support?

Another fundamental aspect of echinoderms we know practically NOTHING about! Understanding of these types of evolutionary changes has important ramifications for many fields.. ecology, paleontology, developmental biology and even astrobiology! 

Echinoderms..So What Good Are They?

Image by John White

A typical conversation I've had with interested parties:

me: ...and THAT is why echinoderms are cool!
other: So?
me: What do you mean?
other: What good are they? Why should I care? How do people use them?

Between this fun little exchange and it bein' the summer grant for writing NSF grants, the whole notion of importance has been a lot on my mind. The answer to the question above, obviously is A LOT.

But for good or bad, echinoderms do not evoke the same need for study that say, various pesty mammals or scavenging, nocturnal insects seem to generate. They do not attack people with rabies nor do echinoderms reside in your sink waiting for your dinner to go bad.
So, aside from their intrinsic interest, what makes echinoderms "worth" studying in the professional world? 

1. Ecology
Far and away the most important reason. A great many near-shore echinoderms have demonstrated critical roles in marine ecosystems. Echinoderms occupy critical roles in those systems, without them those ecosystems would be radically altered. Potentially with very deleterious affects on human systems. Examples:

• Pisaster ochraceus-keystone species in intertidal ecosystems-feeding on and interacting with mollusks of various types.
• Asterias amurensis. Introduced from the North Pacific to Southern Australia, where it is currently running amok and apparently wreaking havok with Australian shellfish.
• Strongylocentrotus and/or Diadema. Purple sea urchins in kelp forests or Black needle urchins in coral reefs. Remove them or increase their numbers and the balance of food is lost.
• Acanthaster planci. I've written about these earlier. But the short version? They eat coral. A LOT of it.

(from New Scientist)

• Biomass. Echinoderms are also probably very important in deep-sea and other cold-water ecosystems. But that role remains poorly studied. The presence of deep-sea echinoderms: sea cucumbers, ophiuroids, etc. is substantial and can constitute a majority (up to 90%) of the TOTAL deep-sea biomass. You don't see them, but by the pound, there's a LOT of them spread out on the ocean floor!
• Plus, they process the benthic biomatter like giant deep-sea earthworms. apparently quite a bit of it.

2. Geology: Index Fossils

Image by Paul Lamble

In geology, echinoderms are important as index fossils. These are fossil members of a particular kind that are used to determine or indicate a specific strata/age of rock. Helicoplacoids, for example occur only in the Cambrian.

 These fossils correlate with occurrence for specific types of organisms in the fossil record and are usually common enough that they can be found readily and make immediate identifiers for the age/layer you are attempting to identify.

 MANY echinoderms find their way towards use in this fashion: sea urchins (including sand dollars, sea biscuits, and "regular" sea urchins), crinoids, blastoids, and even asteroid ossicles can be useful at specific horizons. Fossils can also be used to help reconstruct the paleoecology of a specific area.

Some could only have lived in unconsolidated sandy bottoms. Others only on hard bottoms. Paleozoic fossils can be surprisingly data rich.

3. Food Its always weird for me to think that ANY echinoderms are eaten as food.
But there they are.

Really, only two groups of echinoderms have ANY kind of real market.
To my knowledge, people don't eat crinoids or ophiuroids and only marginally devour asteroids... 

Sea Cucumbers. aka trepang, gamat, or beche-de-mer. Eaten throughout Asia and believed by some to have various medicinal qualities, including tissue repair (some support) and as an aphrodesiac (not well supported).

Holothurians from several different regions, including Alaska, British Columbia, Australia, Madagascar and areas throughout the Indo-Pacific tropics are supported. An update can be found here. Sea cucumber fishery politics can be very contentious. and sustainability of the fishery remains a hot button issue with several species perceived as potentially endangered from overfishing.

Image by Wyld Ginger

Image by Photobat

Sea Urchins. Sea urchin gonads are eaten by the Japanese and now throughout the world. Several taxa, including Strongylocentrotus, are sought out for their tasty innards... Sea urchin fisheries appear to have organization. The North Pacific Strongylocentrotus is represented by the Pacific Urchin Harvesters Association.

Image by goodbyesunday

Image by Yusheng

4. Genetics & Development Recent years have found echinoderms occupying increasingly important roles as experimental animals throughout biology. 
Although nearly all of the classes have been studied in minor ways , three conspicuous taxa have emerged at the forefront.

The Purple Sea Urchin-Strongylocentrotus purpuratus. 

By far one of the MOST heavily studied echinoderms in the world. A search on Google Scholar revealed 8,730 hits for "Strongylocentrotus" and "development" with only some 2,740 hits for "Strongylocentrotus" and "genetics". All that plus a recent issue of Science from 2006 which announced the 814 megabase genome of the purple sea urchin (Strongylocentrotus purpuratus). Honestly, how many single echinoderm SPECIES get a whole FRAKKIN' issue of Science devoted to them????? The Asterinidae (Cl. Asteroidea)-particularly Asterina miniata. This odd little group of starfish occurs quite commonly in several nearshore and easily collected habitats. That, plus the keen developmental patterns observed have made several bat star species VERY heavily studied.

When last I checked Google Scholar..some 1850 citations were recorded from JUST "Asterina" (in part a synonym of Patiria) and "development" and some 940 for "Patiria" and "development" with only some 524 for "Asterina" and "genetics". If the "development" hits are combined, that makes some 2790 total.

Asterias spp. (Asteriidae). While not quite in the league of the two groups above. Running "Asterias" and "development" scores an impressive 5, 110 hits but only 979 if run against "genetics" but still....