Why do cavefish lose their eyes?


It’s another Dawkins question!

Why do cave-dwellers lose their eyes? They’re useless, but are they harmful? Costly to make? Or eroded by rain of uncorrected mutations?

I thought I’d already addressed this in a blog post long ago, but I searched, and I didn’t — it was my inaugural column in sadly defunct Seed magazine, way back in the paleolithic, I think. Fortunately, I still have the copy I sent in to the editor, so I resurrect it here.


Degeneration and development
It’s not disuse that leads to loss of organs in evolution, but competitive genetic interactions

Reduced or degenerate organs, such as the evolution of flightless birds or eyeless cave dwelling animals, were a problem that Charles Darwin considered; his answer was that disuse would lead to their progressive reduction over time (we do not believe this is correct any more). Darwin’s confusion is shared by many even today, and Stephen Jay Gould, in his magnum opus, The Structure of Evolutionary Theory, listed three things that his readers found most confusing, as measured by the correspondence he received:

“I can testify that three items top the list of puzzlement: (1) evolution seen as anagenesis rather than branching (“if humans evolved from apes, why are apes still around”); (2) panselectionism (“what is the adaptive significance of male nipples”); and (3) Lamarckism and the failure of natural selection (“doesn’t the blindness of cave fishes imply a necessary space for Lamarckian evolution by disuse”).”

While all three are interesting questions, let’s consider just the third, which Darwin failed to answer. Why should animals living in total darkness lose their eyes? Gould described two good answers in his book, but recent work by W.R. Jeffery and his colleagues on the Mexican blind cavefish has supported a third. It’s an answer that highlights the importance of developmental biology in explaining some evolutionary phenomena…and it’s also an excellent way to introduce this new column, in which I’ll regularly be discussing the evo-devo way of thinking.

One possible answer is that it is an economical adaptation. It requires energy and effort to build something as intricate and fragile as an eye, so shutting off that pathway would be a sensible strategy in the embryo: the energy that would be used in constructing and maintaining the eye could instead be diverted to other growing organs. One analogy would be in building a house that will have one wall facing a brick wall; it would be sensible to not bother building a large and expensive picture window there. For the cave fish, those embryos that did not bother to build an eye that would never be used acquired some slight advantage over their fellows that did bear the burden of an eye, and so gradually came to dominate the cave population.

In the case of the Mexican blind cavefish, though, there is a striking observation against this explanation: the embryos make eyes! They initially develop, they form an eye cup, they develop the beginnings of neural circuitry, neurons proliferate…and then they stop. The rest of the skull continues to grow, overwhelming the budding eye with new tissue. It’s as if one paid to have that picture window built into the house, and then halfway through construction had it ripped out and a wall put in. This is hardly economical.

Another possible answer that loss of an eye in a cave fish does not impose any cost, and the eyes disappear in the population by random chance, and that without selection for sightedness, there is nothing to prevent the blind variants from competing equally with their sighted counterparts. This is a neutral theory of the loss of unused characters, which suggests that mutations that knocked out genes needed for development of the eye wouldn’t necessarily have any advantage, but they’d also have no cost. The eye is lost by harmless attrition, and would be represented by broken genes in the animal’s genome.

This explanation doesn’t seem to fit the facts, either. The genes involved in generating the eye all seem to be present and functional in the blind cave fish. Transplanting a lens from a cavefish species with eyes to the blind cavefish embryo is enough to rescue the eye—it then develops into a perfect and functional visual organ. The problem isn’t caused by outright broken genes, but by genes that are being regulated in a different way. Something is actively switching off lens formation and thereby removing a signal for eye development, and in fact, analysis of gene expression in the developing blind cavefish eye reveals that many genes are more active than they are in the sighted fish.

If neither the economical hypothesis or the neutral hypothesis adequately explain how cavefish lose their eyes, what is the answer? The evidence suggests a third alternative, an explanation based on pleiotropy and developmental interactions.

Pleiotropy is a common phenomenon in genetics: all it means is that a single gene may have many different effects on the organism. Two genes that interact with one another in this system are pax6, a ‘master gene’ controlling the development of the eye, and hedgehog, a signaling molecule that plays an important role in setting up the midline of the animal. pax6 is a transcription factor (a gene that regulates the expression of other genes) and is active in the region of the embryonic head where eyes will form, is expressed in the eye cup and lens, and regulates the development of the eye. hedgehog is a protein that is secreted at the midline and diffuses laterally to regulate many other processes. It’s function is complex, but one role is to inhibit and separate structures; one effect of mutations in hedgehog is midline defects, such as cyclopia, where the eyes fuse together in the absence of a hedgehog boundary. Among those effects is an inhibition of pax6.

hedgehog is also expressed in teeth, tastebuds, and the jaw. This is what we mean by pleiotropy — the gene is a midline gene that suppresses the eye gene pax6, but it’s also a jaw gene and a tooth gene and a tastebud gene. Now imagine a population of fish feeding and swimming in total darkness; which individuals will be most adapt at finding food, and therefore most likely to pass on their genes to the next generation? Those that are best at using senses other than vision, that can use the tactile senses of their lower jaw to probe the environment for a meal, and that can use taste instead of sight to discriminate among food choices. What this suggests is that animals with expanded hedgehog function would thrive best, and selection would work to increase the frequency of greater hedgehog expression in the population.

There is a side effect — pleiotropy at work — in that hedgehog also inhibits pax6 expression, which means that expanding jaws and tastebuds will lead to a concomitant reduction of the eyes. What we have is a perfect example of an evolutionary tradeoff. Because hedgehog and pax6 are negatively coupled to one another, one can be expanded only at the expense of the other, and what is going on in the blind cavefish is not selection for an economical reduction of the eyes, nor the accidental loss of an organ that has no effect: it is positive selection for a feature that is only indirectly related to the eyes.

Gould would have appreciated this discovery. The cause of the blindness is the interrelationship between two genes which have complementary roles in development in establishing the architecture of the face. This is not a necessary relationship — not all genes have to be coupled to one another in this way — but a result of the evolutionary history of the organism, and a different kind of economy. The lower part of the face can be expanded, but only at the expense of the upper half.

The general lesson from this analysis is that understanding selection is not enough. We also need to understand the developmental interactions present in an organism to understand how selection for one feature might lead to a surprising pleiotropic change in something completely different.


Just for completeness, I’ll include some bits that weren’t published, but passed along for the editor’s edification.

(Chris: for your fact checker, the reference to Gould is from page 204 of The Structure of Evolutionary Theory.

Darwin’s explanation for the eyelessness was this:

“By the time that an animal had reached, after numberless generations, the deepest recesses, disuse will on this view have more or less perfectly obliterated its eyes, and natural selection will often have effected other changes, such as an increase in the length of the antennae or palpi, as a compensation for blindness.”

That’s from Chapter 5, “Laws of Variation,” in his Origin of Species.

I don’t know how you want to include formal bibliographic citations. A good summary of the cavefish work is here:

Jeffery WR (2005) Adaptive evolution of eye degeneration in the Mexican blind cavefish. J Hered 96(3):185-196.

I notice these kinds of things weren’t explicitly listed in previous examples of the column.)

Comments

  1. darkrune says

    I lurk here often as it’s my favorite blog. I had to register to thank you for posting these biology explanations.

  2. Justin Opotzner says

    As Darkrune also said, I want to thank you for these biology lessons. I find them fascinating, and at a technical level I find comfortable, but ever so slightly above my head.

  3. David Wilford says

    Thanks for digging up this informative, yet succinct, explanation about cavefish eyes.

  4. unclefrogy says

    that is very interesting. To me that seems a little bit similar to the changes in foxes resulting from selecting for less aggression leading to other changes in characteristics that were not seem on the surface related to the selected traits.
    Are there other traits or genes and their interactions that are similar?
    uncle frogy

  5. williamhyde says

    A similar loss happened to algae in an experiment conducted by Collins and Bell of McGill.

    Be warned that the following is a physicist’s recollection of a seminar seen years ago.

    The authors conducted a series of experiments, growing hundreds of generations of algae at various high CO2 levels. This was mainly to investigate whether the “CO2 fertilization effect” would cause these algae to act as a sink for CO2 (as it happens, they did not).

    Bell and his co-workers then performed a followup experiment. Taking the strains that had best adapted to high CO2 levels, he conducted experiments in which he gradually lowered ambient CO2 to modern levels or below, again over hundreds of generations.

    As I understand it, some or all algae have a “carbon concentrating Mechanism” which allows them to survive if they find themselves in waters low in CO2. This mechanism was present in the strains used at the beginning of this work, but is was lost in the strains adapted to high CO2. They did not do at all well in the low CO2 environment.

    It was not clear at the time whether the CCM had been selected against, simply lost as it no longer conferred any advantage or whether something more complex had happened. I do not know if this question has been investigated further.

    Ah, here is the paper.

    Collins S. & Bell G. 2004. Phenotypic consequences of 1000 generations of selection at elevated CO2 in a green alga. Nature 431:566-569.

    I notice that the paper has been cited by creationists as evidence that evolution does not happen. But that is an honour that few escape.

  6. Ichthyic says

    As I understand it, some or all algae have a “carbon concentrating Mechanism” which allows them to survive if they find themselves in waters low in CO2. This mechanism was present in the strains used at the beginning of this work, but is was lost in the strains adapted to high CO2. They did not do at all well in the low CO2 environment.

    This reminds me more of the GLO mutation in humans and other primates.

  7. ChasCPeterson says

    Well, except that the usual version of the economic argument is about the costs of maintaining a useless organ, not building it in the first place. Very very difficult to disprove, since it would require very precise measurements of energetics over a lifetime.

  8. sugarfrosted says

    @10 Injury potential also would seem to be relevant, but I can’t imagine that really being enough of a selective pressure, since we still do have an appendix, which seems to most just increase the chance of illness.