Changes in gene activity through epigenetic alterations induced by early environmental challenges during the embryogenesis are known to impact the phenotype, health and disease risk of animals. The epigenome is therefore an essential contributor to phenotypic plasticity, and learning how environmental exposures translate into persisting epigenetic changes may open new doors to improve robustness and resilience of developing animals. Birds are agronomic species of choice to directly manipulate the embryonic environment and study its consequences on the developing animal. We previously showed that the heat tolerance of male commercial chickens was improved by cyclically elevating the egg incubation temperature. This treatment named embryonic heat conditioning (HC) was associated with changes in gene expression that persisted during the development of chickens and enhanced gene expression response in case of heat challenge at slaughter age, 35 days post-hatch. To further explore the molecular basis of heat acclimation, we took advantage of an inbred line of japanese quails (Coturnix japonica) to investigate the impact of HC on bird methylome. Among other advantages, quail generation cycle is 3-4 time faster than chicken and the use of an inbred genotype should reduce the phenotype variations associated with genetic variability. We performed a characterization of HC on quail phenotype in interaction with a post-hatch heat stress at the onset of sexual maturity. Several parameters such as weight of the animals, temperature, egg laying for females, hormone levels and blood gas characteristics were measured. Concomitantly we investigated the impact of HC on quail transcriptome by RNA-seq and methylome by a whole genome bisulfite sequencing (WGBS) on brain tissues sampled at hatch. Analysis of the results is ongoing and preliminary data will be presented.