Positive selection acted upon cetacean ion channels during the aquatic transition

The transition of cetaceans (whales, dolphins, and porpoises) from terrestrial to aquatic lifestyles is a striking example of natural selection driving major phenotypic changes (Figure 1). For instance, cetaceans have evolved the ability to withstand high pressure and to store oxygen for long periods, among other adaptations (Das et al. 2023). Many phenotypic changes, such as shifts in organ structure, have been well-characterized through fossils (Thewissen et al. 2009). Although such phenotypic transitions are now well understood, we have only a partial understanding of the underlying genetic mechanisms. Scanning for signatures of adaptation in genes related to phenotypes of interest is one approach to better understand these mechanisms. This was the focus of Uribe and colleagues’ (2024) work, who tested for such signatures across cetacean protein-coding genes.

license, visit https://creativecommons.org/licenses/by/4.0/ The transition of cetaceans (whales, dolphins, and porpoises) from terrestrial to aquatic lifestyles is a striking example of natural selection driving major phenotypic changes (Figure 1).For instance, cetaceans have evolved the ability to withstand high pressure and to store oxygen for long periods, among other adaptations (Das et al. 2023).Many phenotypic changes, such as shifts in organ structure, have been well-characterized through fossils (Thewissen et al. 2009).Although such phenotypic transitions are now well understood, we have only a partial understanding of the underlying genetic mechanisms.Scanning for signatures of adaptation in genes related to phenotypes of interest is one approach to better understand these mechanisms.This was the focus of Uribe and colleagues' (2024) work, who tested for such signatures across cetacean proteincoding genes.The authors were specifically interested in investigating the evolution of ion channels, as these proteins play fundamental roles in physiological processes.An important aspect of their work was to develop a bioinformatic pipeline to identify orthologous ion channel genes across a set of genomes.After applying their bioinformatic workflow to 18 mammalian species (including nine cetaceans), they conducted tests to find out whether these genes showed signatures of positive selection in the cetacean lineage.For many ion channel genes, elevated ratios of non-synonymous to synonymous substitution rates were detected (for at least a subset of sites, and not necessarily the entire coding region of the genes).The genes concerned were enriched for several functions, including heart and nervous system-related phenotypes.
One top gene hit among the putatively selected genes was SCN5A, which encodes a sodium channel expressed in the heart.Interestingly, the authors noted a specific amino acid replacement, which is associated with sensitivity to the toxin tetrodotoxin in other lineages.This substitution appears to have occurred in the common ancestor of toothed whales, and then was reversed in the ancestor of bottlenose dolphins.The authors describe known bottlenose dolphin interactions with toxin-producing pufferfish that could result in high tetrodotoxin exposure, and thus perhaps higher selection for tetrodotoxin resistance.Although this observation is intriguing, the authors emphasize it requires experimental confirmation.
The authors also recapitulated the previously described observation (Yim et al. 2014;Huelsmann et al. 2019) that cetaceans have fewer protein-coding genes compared to terrestrial mammals, on average.This signal has previously been hypothesized to partially reflect adaptive gene loss.For example, specific gene loss events likely decreased the risk of developing blood clots while diving (Huelsmann et al. 2019).Uribe and colleagues also considered overall gene turnover rate, which encompasses gene copy number variation across lineages, and found the cetacean gene turnover rate to be three times higher than that of terrestrial mammals.Finally, they found that cetaceans have a higher proportion of ion channel genes (relative to all protein-coding genes in a genome) compared to terrestrial mammals.Similar investigations of the relative non-synonymous to synonymous substitution rates across cetacean and terrestrial mammal orthologs have been conducted previously, but these have primarily focused on dolphins as the sole cetacean representative (McGowen et al. 2012;Nery et al. 2013;Sun et al. 2013).These projects have also been conducted across a large proportion of orthologous genes, rather than a subset with a particular function.Performing proteome-wide investigations can be valuable in that they summarize the genome-wide signal, but can suffer from a high multiple testing burden.More generally, investigating a more targeted question, such as the extent of positive selection acting on ion channels in this case, or on genes potentially linked to cetaceans' increased brain sizes (McGowen et al. 2011) or hypoxia tolerance (Tian et al. 2016), can be easier to interpret, as opposed to summarizing broader signals.However, these smaller-scale studies can also experience a high multiple testing burden, especially as similar tests are conducted across numerous studies, which often is not accounted for (Ioannidis 2005).In addition, integrating signals across the entire genome will ultimately be needed given that many genetic changes undoubtedly underlie cetaceans' phenotypic diversification.As highlighted by the fact that past genome-wide analyses have produced some differing biological interpretations (McGowen et al. 2012;Nery et al. 2013;Sun et al. 2013), this is not a trivial undertaking.
Nonetheless, the work performed in this preprint, and in related research, is valuable for (at least) three reasons.First, although it is a challenging task, a better understanding of the genetic basis of cetacean phenotypes could have benefits for many aspects of cetacean biology, including conservation efforts.In addition, the remarkable phenotypic shifts in cetaceans make the question of what genetic mechanisms underlie these changes intrinsically interesting to a wide audience.Last, since the cetacean fossil record is especially welldocumented (Thewissen et al. 2009), cetaceans represent an appealing system to validate and further develop statistical methods for inferring adaptation from genetic data.Uribe and colleagues' (2024) analyses provide useful insights relevant to each of these points, and have generated intriguing hypotheses for further investigation.

Figure 1 :
Figure 1: The skeletons of Ambulocetus (an early whale; top) and Pakicetus (the earliest known cetacean, which lived about 50 million years ago; bottom).Copyright: J. G. M. Thewissen.Displayed here with permission from the copyright holder.