Disconnecting bones within the jaw-otic network modules underlies mammalian middle ear evolution

The origin of the mammalian middle ear ossicles from the craniomandibular articulation of their synapsid ancestors is a key event in the evolution of vertebrates. The richness of the fossil record and the multitude of developmental studies have provided a stepwise reconstruction of this evolutionary innovation, highlighting the homology between the quadrate, articular, pre-articular and angular bones of early synapsids with the incus, malleus, gonial and ectotympanic bones of derived mammals, respectively. There are several aspects involved in this functional exaptation: (i) an increase of the masticatory musculature; (ii) the separation of the quadrate bone from the cranium; and (iii) the disconnection of the post-dentary bones from the dentary. Here, we compared the jaw-otic complex for 43 synapsid taxa using anatomical network analysis, showing that the disconnection of mandibular bones was a key step in the mammalian middle ear evolution, changing the skull anatomical modularity concomitant to the acquisition of new functions. Furthermore, our analysis allows the identification of three types of anatomical modules evolving through five evolutionary stages during the anatomical transformation of the jawbones into middle ear bones, with the ossification and degradation of Meckel's cartilage in mammals as the key ontogenetic event leading the change of anatomical modularity.This project was funded by the Spanish Ministerio de Economía y Competitividad (BFU2015‐70927‐R) to DR‐G. BE‐A has received financial support through the Postdoctoral Junior Leader Fellowship Programme from ‘la Caixa’ Banking Foundation (LCF/BQ/LI18/11630002) and thanks the support of the Unidad de Excelencia María de Maeztu (MDM‐2014‐0370)

Developmental plasticity, epigenetics and human health

The unrelenting rise in global rates of non-communicable disease has necessitated a thorough re-evaluation of the current use of adult- and lifestyle-based strategies to curb the growing epidemic. There is a rapidly emerging set of epidemiological, experimental and clinical data suggesting that developmental factors play a considerable role in determining individual disease risk later in life. This phenomenon is known as the Developmental Origins of Health and Disease (DOHaD). Developmental factors, such as maternal and paternal nutrition, gestational diabetes mellitus, and even the normative range of developmental experiences, may evoke the processes of developmental plasticity which enable an organism to change its developmental trajectory in response to environmental cues. However in the event of a mismatch between the early and mature environment, such anticipatory responses may become maladaptive and lead to elevated risk of disease. The evo-devo and eco-evo-devo framework for DOHaD has more recently been supported by mechanistic insights enabled by rapid advances in epigenetic research. Increasing evidence suggests that developmental plasticity may be effected by epigenetically mediated modulation of the expression of specific genes. These mechanisms include DNA methylation, histone modifications and noncoding RNA activity. A growing number of animal studies also point towards the transgenerational inheritance of epigenetic marks, which may have implications for the perpetuation of ill-health. However early-life epigenotyping may find utility as a prognostic marker of metabolic dysfunction for identification and treatment of at-risk individuals