Kavli Affiliate: Erich Jarvis
| Authors: Jonathan Fenn, Jessica C Edge, Vladimir Ovchinnikov, Olga Amelkina, Melea Sinclair, Tiago H C De Bem, Alessandra Bridi, Irene Malo-Estepa, Angela Gonella-Diaza, Felipe Perecin, Juliano C da Silveira, Guilherme Pugliesi, Flavio Vieira Meirelles, Zenab Butt, Haidee Tinning, Giulio Formenti, Erich Jarvis, Bastian Fromm, James O McInerney, Niamh Forde and Mary J O’Connell
| Summary:
Similar placental morphologies evolved multiple times independently in the history of mammal evolution1,2. Yet the genetic architecture that repeatedly guides distinct mammal lineages towards similar complex placental phenotypes has remained elusive. MicroRNAs (miRNAs), despite their diversity in mammals3–7 and known roles as developmental regulators8–10, remain under-examined as drivers of morphological innovation. We identified presence-absence patterns for 429 miRNA gene families across 398 mammalian genomes and discovered that placental phenotype is highly predictable from genomic miRNA repertoires (classification accuracy 74.5-95.8%). We identified 42 miRNA gene families significantly associated with placentation type, whose gene targets are enriched for developmental processes. Notably, convergent placental morphologies consistently involve identical miRNA families, revealing that evolution of this trait is constrained to predictable genetic pathways. We demonstrate that MIR-11986, uniquely associated with cotyledonary placentation, has tissue-specific expression in key reproductive tissues. MiRNA-mediated regulation therefore constrains placental morphological diversification into reproducible programs, offering insights into how genetic architecture shapes the predictability of convergent evolution. This striking pattern reveals a fundamental principle of evolution: that the miRNA regulatory networks available to control and guide complex placental morphological innovation are constrained and predictable.