Highly modular genomic architecture underlies combinatorial mechanism of speciation and adaptive radiation

Adaptive radiation is a key modulator of biodiversity when new adaptive zones become available. Some of the largest and most diverse adaptive radiations have evolved from hybrid populations in the absence of geographic isolation. While phenotypic differentiation among their species is stunning, little is known about the genetics underpinning it. In Lake Victoria more than 500 cichlid fish species representing nearly as many different combinations of morphological and colouration phenotypes have evolved in 16,000 years. Analysing phenotypes and genomes of 107 of these species we show that the genetic basis of recurrently diverging traits associated with speciation and ecological adaptation is generally polygenic, often redundant, and dispersed across the genome. Up to 50% of alleles associated with variation in these traits were amassed during ancestral hybridisation, which may explain the low pleiotropy we find among traits. Such independent trait modules act like Lego pieces, permitting many trait combinations to evolve by recombining a finite set of elements. We argue that modular trait architectures emerging from admixture variation are key to combinatorial speciation happening often, making adaptive radiation ultrafast and species rich.