Classical population genetical theory predicts that selection will be less efficient when population sizes are small as in these cases random events play a more important role. We noticed however that if selection is less effective error rates (meaning mutation rates, errors in gene processing) also go up. As such we might expect selection for control of errors to be stronger in small populations. We have found evidence that population size is indeed associated with genome bloating and high errors rates but also in turn that for some errors selection appeared to be stronger when populations are small.
One of these errors is missplicing – the way we cut up our RNAs before making proteins. One curiosity of our genes is that we have lots more sequence that helps the system to stop making errors than species with larger populations. A consequence of this is that some mutations that are often assumed to be irrelevant are, as we showed, under strong selection. This strong selection against what otherwise are innocuous mutations when populations are small is what the novel framework predicted but was counter to the classical model.
We have also used this same information to predict new disease-causing mutations, improve artificial genes used in gene therapy and to make vaccines, while all the time preserving the protein product. We also redirected our efforts to understand mutation and selection on these “silent” changes in SARS-CoV-2. In addition, in understanding how control of when a gene is turned on and off, affected by the on/off switches of neighbouring genes we have understood both how much gene expression evolves and where in the genome to put artificial genes for gene therapy where they are least likely to be subject to such errors. The same analyses allowed us to extract what have been called the holy grail of human stem cells, naïve cells.
But errors aren’t always bad: they can also make the raw material for novelty. We have looked at several cases of this looking at how new genes evolve and in the process discovered a new type of cell in the human early embryo that is a waste-bin for error laden cells.
The project has resulted, to date, in 32 publications, one patent and one web resource.