Three months ago, if I had
seen this article about the ctenophore genome, I would have moved right passed
it without a second look. What is a
ctenophore and why would I care about the sequence of its DNA? But then I taught Bio 2 this spring and
learned about animal diversity and the evolutionary tree (a day before I taught
it). This is a great example that the
more you learn, the more interested you become in the subject. Today’s article by Moroz et al. was published
recently online in Nature (this one is open access, so take a look). The results totally change the roots of the
animal tree and invalidate what we taught to our students this semester. Before we get into the paper, let me answer
my own questions:
What is a ctenophore?
Ctenophores are also known
as comb jellies, because they look like jellyfish and have a comb-like
structure that they wiggle around to move through the water. They have sensory organs to sense light and
gravity. They have tentacles that they
move with their nervous system in order to catch prey.
Comb jelly (from Wikimedia Commons) |
Why should we care about
ctenophores?
Ctenophores, along with
cnidarians and sponges, represent some of the most ancient lineages of
animals. Studying them can give us a
clue about how animals evolved. All the
rest of the animals are in the large taxonomic group called Bilateria, because
they have bilateral symmetry (which is symmetry across a single axis). This includes humans, insects, crustaceans,
worms, fish, molluscs, etc. Think about
a jellyfish or a sea anemone; they have radial symmetry, which means they can
be bisected in lots of different axes and you would still have symmetrical
halves. The bilateral animals are more
complicated in lots of other ways, such as having a greater variety of tissues
and more complex physiology.
The phylogenetic tree
according to the biology textbook
Sponges don’t have organized
tissues and they don’t have a nervous system, so based on that, researchers
have considered them to be the most ancient lineage (i.e. the “basal”
animals). So if we are building a
phylogenetic tree based on morphological characteristics, we are going to put
them as the first branch.
Cnidarians and ctenophores
look very similar, so it would make sense to put them right next to each other,
followed by the bilateral animals. Thus,
based on morphological observations, the tree should look something like this:
No one ever explained to me
why cnidarians get to be closer to the bilaterals than ctenophores. Perhaps this is because the cnidarians come
in so many different body plans, so maybe they are considered to be more
complex and thus, an evolutionarily “newer” animal.
We told our students over
and over: “Sponges are the most basal animals”.
But like many phylogenetic theories that have come before, new DNA
sequencing data is challenging this view.
What does the ctenophore
genome tell us?
First off, for the
non-biologists out there, you need to understand one fundamental thing about
gene evolution. Two species that are
highly related will have very similar DNA sequences. The further apart two species are in
evolutionary time, the more time there is for mutations to change the DNA
sequences and the gene functions.
Moroz et al. sequenced one
of the ctenophore genomes and then compared it with the genomes of sponges and
cnidarians. One of the main findings was
that there are many missing animal-specific genes that are involved in animal
development (Hox genes), regulating gene expression (no miRNAs!) and innate
immunity. Although some animal-specific
genes are absent, the ctenophores have many unique genes that are not found in
other animals, indicating that these genes evolved independently in the
ctenophore lineage.
The researchers devoted a
lot of the paper to looking at genes involved in nervous system function. Ctenophores, like cnidarians, have neural
nets, as opposed to organized bundles of nerves. Bilateral animals have many different
neurotransmitters, which are the signals that get sent between nerve
cells. The ctenophores only have genes
for making the neurotransmitter glutamate (and GABA), but they have a ton of
glutamate receptors, more than other animals.
All of these findings led
the authors to conclude that ctenophores are the most basal animals, not
sponges. Alternatively, it is still
possible to keep the same phylogenetic tree, but there would need to have been massive
gene loss in the ctenophore lineage. The
most parsimonious explanation is shown here:
The main difference between
these two trees is that the sponges and ctenophores have swapped
positions. Note that this would require
a nervous system to have developed twice independently. That’s totally insane. The ctenophores and the cnidarians “needed” a
method of controlling their body to capture prey and both lineages “came up”
with the same solution (of course evolution is random and doesn’t have a
particular goal in mind). When similar
structures evolve independently, this is known as convergent evolution.
Next year, instead of
devoting half a lecture to sponges and tossing in a single slide on
ctenophores, I think I’ll have to give ctenophores their due, as potentially
the most ancient lineage of animals still in existence.
Carl Zimmer always beats me
to the punch, so here’s his take on the same article. Better writing, but fewer trees!