Abstract
The adaptation of proteins for novel functions often requires changes in their kinetics via amino acid replacement. This process can require multiple mutations, and therefore extended periods of selection. The transfer of genes among distinct species might speed up the process, by providing proteins already adapted for the novel function. However, this hypothesis remains untested in multicellular eukaryotes. The grass Alloteropsis is an ideal system to test this hypothesis due to its diversity of genes encoding phosphoenolpyruvate carboxylase, an enzyme that catalyzes one of the key reactions in the C4 pathway. Different accessions of Alloteropsis either use native isoforms relatively recently co-opted from other functions or isoforms that were laterally acquired from distantly related species that evolved the C4 trait much earlier. By comparing the enzyme kinetics, we show that native isoforms with few amino acid replacements have substrate KM values similar to the non-C4 ancestral form, but exhibit marked increases in catalytic efficiency. The co-option of native isoforms was therefore followed by rapid catalytic improvements, which appear to rely on standing genetic variation observed within one species. Native C4 isoforms with more amino acid replacements exhibit additional changes in affinities, suggesting that the initial catalytic improvements are followed by gradual modifications. Finally, laterally acquired genes show both strong increases in catalytic efficiency and important changes in substrate handling. We conclude that the transfer of genes among distant species sharing the same physiological novelty creates an evolutionary shortcut toward more efficient enzymes, effectively accelerating evolution.
Highlights
The evolution of novel traits usually involves the co-option of pre-existing genes, which were previously used for different functions (True and Carroll 2002; Jiggins et al 2017; Fernández and Gabaldón 2020)
It is clear from other studies that not all C4 phosphoenolpyruvate carboxylase (PEPC) have the exact same properties (Ting and Osmond 1973; Moody et al unpublished), and we suggest that the clustering of properties reflects a bias in the genes that successfully transferred into Alloteropsis
In the case of PEPC, the massive upregulation in expression of the non-C4 copies was followed by amino acid replacements that rapidly increased the catalytic efficiency and sensitivity to inhibitors of the enzyme
Summary
The evolution of novel traits usually involves the co-option of pre-existing genes, which were previously used for different functions (True and Carroll 2002; Jiggins et al 2017; Fernández and Gabaldón 2020). Mutations required to trigger certain new functions are often restricted to a subset of codon positions, and epistasis can restrict the order in which they can occur (Weinreich et al 2006; Blount et al 2012; Studer et al 2014; Kumar et al 2017; Yang et al 2019) Because of these complexities, the modification of genes for a new function can require protracted periods of selection, the length of which depends on the mutation rate and demography of the species (Desai et al 2007; Neher et al 2010). The impact of interspecific gene transfer on the speed of adaptation is difficult to directly compare with the iterative adaptation of co-opted native genes in complex multicellular organisms
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