Horizontal gene transfer has occurred between E. chlorotica and its algae food, V. litorea, with gain of function for photosynthesis by E. chlorotica. This is an exception to the current idea of how evolution works. More than 50 years before Darwin’s theory of natural selection, there was another natural philosopher (the term “scientist” didn’t gain popularity until the 1850’s) who had his own ideas about inheritance.
|According to Lamarck, giraffes acquired their longer neck, then passed it on.|
Then came Charles Darwin. His voyage on the Beagle took place from 1831-1836 and he formulated his theory soon after that, but he found it hard to reconcile his religious beliefs with his scientific findings and theories. Therefore, he did not publish his work until 1859, when he learned that another scientist, Alfred Russell Wallace, had come to the same conclusion and was about to publish. After years of public debate and testing the theory, Darwin’s and Wallace’s theory of natural selection as the instrument of evolution won out over Lamarckism, and is now widely accepted.
The principle behind natural selection is that changes in organism characteristics are always occurring, but when changes in the environment result in a reproductive advantage for the organism that has a inherited a certain new characteristic, then that characteristic will be passed on to the next generation at a higher rate (the organism with that change is more likely to survive long enough to mate and produce offspring – if you don’t survive to mate, your genes aren’t passed on – duh!).
A prototypical example of natural selection and evolution is nylon eating bacteria. Nylon wasn’t invented until the 1940’s, so the ability to feed on it must be new as well. In the 1970’s, a strain of Flavobacterium was found producing enzymes to digest nylon. Even more amazing were the results of multiple experiments carried out with a non-nylon digesting bacterium, Pseudomonas aeruginosa. When this bug was placed in an environment where nylon was its only possible food source, it took only a few generations before every bacterium on the plate contained enzymes to metabolize nylon, and these were not the same enzymes as found in the Flavobacterium. It happened in trial after trial, showing that life can adapt to whatever the environment offers. There are many other concrete examples of natural selection in the scientific literature – it is one of the most solidly supported theories in all of science.
In an ironic twist of fate, scientists are now helping bacteria evolve the ability to process garbage into adipic acid, one of the two major chemicals in nylon. Man invented nylon, nylon-eating bacteria taught us about evolution, we used this knowledge to evolve bacteria to make nylon!
We know that natural selection takes place, causing species to diverge, converge, and move along ever changing paths. We have seen it take place and can follow the clues it has left behind. However, horizontal gene transfer has made following those paths more difficult. Using molecular methods, scientists have ways of tracking the rate of change in DNA over time. With this data they can put together family trees and charts (cladograms) to show the points at which different species diverged from one another. But if a certain organism can pick up one or more new traits in one horizontal transfer, it makes patterns for small changes harder to use in developing the evolutionary cladograms. Is a new trait the result of mutation and natural selection or horizontal gene transfer?
A simple cladogram for apes and hominids is on the left. It shows evolutionary relationships between species. The right cladogram shows things can be confusing when horizontal gene transfer (crossing arrows) takes place.
Other features have entered the debate on the nature of Darwinian evolution as well. Does natural selection proceed slowly, with very small changes over time adding up to a measurable change in some characteristic or species (called gradualism), or does a species remain stagnant for a long time, until a mutation brings some rapid, even instantaneous, change (called punctuated equilibrium)?
Gradualism has been the prevailing theory for decades now, but examples of horizontal gene transfer would argue for punctuated equilibrium, especially if it is occurring in higher eukaryotes. Instead of many small changes adding up to a measurable difference over time, horizontally transferred genes bring the potential for big changes from the time of transfer down through all subsequent generations.
Is the retention and function of chloroplasts in E. chlorotica an example of punctuated equilibrium? Definitely not - the instantaneous gain of photosynthetic ability is a sudden change, but remember, the chloroplasts themselves are not passed on to the next generation – this is not an example of horizontal gene transfer in itself. But the fact that photosynthesis-specific genes are found in the nucleus of the slug is evidence that horizontal gene transfer has taken place and that they are passed on vertically. This would argue for punctuated equilibrium over gradualism. So, could this be an exception to the commonly held idea of evolution?
What is more, the combination of heritable plant genes AND acquisition of photosynthetic ability in an already living individual smells a lot like evolution by acquired characteristic – Lamarckism! There is a change in the individual (kleptoplasty of chloroplasts) and this acquired ability is passed on to future generations (via germ line inheritance of the photosynthetic genes). That seems like a more complex, two-step version of Lamarck’s giraffes.
It would be nice if the story were this simple – O.K., it’s already not simple – but there has been a catch. Even though the genes for some photosynthesis elements are present in the slug’s nucleus, scientists had not been able to show that they were doing anything. Logic says they must be, since the chloroplasts are functional for so long. One could track this is based on the fact that DNA genes are converted to RNA messages before being translated into protein. If the nuclear genes are making proteins, you should be able to see their RNA transcripts - but scientists went a long time without seeing the transcripts. They surmised that the transcripts were short-lived or present in low amounts that couldn't be detected.
All this speculation has been put to rest by recent evidence from Case Western Reserve University. Investigators in late 2011 studied the transcriptosome of E. chlorotica. Whereas the genome is the sum of all genes present in an organism, a transcriptosome represents all the mRNAs present in an cell or organism, but only at a specific point in time or under a specific set of conditions.
This is real difference between genomes and transcriptosomes; genomes are basically the same in all somatic cells under all conditions. But different cell types need different gene products, and reacting to different conditions will call for changes in which genes are transcribed to mRNAs and then translated into proteins. Therefore, the transcriptosome will be different for different cells and at different times
The scientists in the Case Western study isolated mRNA from whole E. chlorotica organisms afaer they had been starved for 2 months and then exposed to sunlight for two hours. Using starved animals ensured that the dose of sunlight would stimulate expression of as many photosynthesis genes as possible.
In all 111 chloroplast transcripts from 52 different genes were identified, many encoded by the stolen cholorplasts, but many others that represent nuclear genes - once found only in the nucleus of the E. chlorotica's algal food, but now found in the nucleus of the sea slug.
This is the first direct evidence of functional lateral gene transfer in a kleptoplastic organism - and think, they only had to study a mere 98,238,204 separate sequences and 8.9 billion nucleotides of code in order to make this discover. This suggests that the copy number and the transcription rate of laterally transferred genes are low, but who cares. We now have proof of horizontal gene transfer and the production of a true plant/animal hybrid!
Pierce, S., Fang, X., Schwartz, J., Jiang, X., Zhao, W., Curtis, N., Kocot, K., Yang, B., & Wang, J. (2011). Transcriptomic Evidence for the Expression of Horizontally Transferred Algal Nuclear Genes in the Photosynthetic Sea Slug, Elysia chlorotica Molecular Biology and Evolution, 29 (6), 1545-1556 DOI: 10.1093/molbev/msr316
For more information on Jean Baptiste Lamarck, Charles Darwin, gradualism and punctuated equilibrium or pangenesis, as well as web-based activities and experiments, go to:
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Gradualism and punctuated equilibrium –