Our lab is interested in epigenetic gene regulation in mammalian development and in ageing. Global epigenetic reprogramming occurs at fertilisation and fundamentally remodels the epigenomes of sperm and egg. We are working to understand the mechanisms of reprogramming and also how it may be linked with zygotic genome activation, the sudden transcriptional springing to life of the genome in the early embryo.
Soon after implantation of the embryo in the maternal uterus there is a major programme of cell fate decisions which establishes the three primary germ layers, the ectoderm (which gives rise to brain and skin), the mesoderm (giving rise to muscle and heart), and the endoderm (which gives rise to the gut amongst other tissues).
These three lineages are the foundations of all organs in the adult body and we are interested in the transcriptional and epigenetic events that underlie their emergence from the undifferentiated epiblast. Finally, we are studying how the epigenome degrades during ageing potentially in a programmed fashion, and whether there are approaches by which this degradation can be slowed down or reversed.
Biological systems have the capacity to not only build and robustly maintain complex structures but also to rapidly break up and rebuild such structures. Here, using primitive societies of Polistes wasps, we show that both robust specialization and rapid plasticity are emergent properties of multi-scale dynamics. We combine theory with experiments that, after perturbing the social structure by removing the queen, correlate time-resolved multi-omics with video recordings. We show that the queen-worker dimorphism relies on the balance between the development of a molecular queen phenotype in all insects and colony-scale inhibition of this phenotype via asymmetric interactions. This allows Polistes to be stable against intrinsic perturbations of molecular states while reacting plastically to extrinsic cues affecting the whole society. Long-term stability of the social structure is reinforced by dynamic DNA methylation. Our study provides a general principle of how both specialization and plasticity can be achieved in biological systems. A record of this paper's transparent peer review process is included in the supplemental information.
The pre-conceptual, intrauterine, and early life environments can have a profound and long-lasting impact on the developmental trajectories and health outcomes of the offspring. Given the relatively low success rates of Assisted Reproductive Technologies (ART; ~25%), additives and adjuvants, such as glucocorticoids, are utilized to improve the success rate. Considering the dynamic developmental events that occur during this window, these exposures may alter blastocyst formation at a molecular level, and as such, affect not only the viability of the embryo and ability of the blastocyst to implant, but also the developmental trajectory of the first three cell lineages, ultimately influencing the physiology of the embryo. In this study we present a comprehensive single-cell transcriptome, methylome and small RNA atlas in the day 7 human embryo. We demonstrate that, despite no change in morphology and developmental features, preimplantation glucocorticoid exposure reprograms the molecular profile of the TE lineage and these changes are associated with an altered metabolic and inflammatory response. Our data also suggest that glucocorticoids can precociously mature the TE sub-lineages, supported by the presence of extravillous trophoblast markers in the polar sub-lineage and presence of X Chromosome dosage compensation. Further, we have elucidated that epigenetic regulation (DNA methylation and microRNAs (miRNAs)) likely underlie the transcriptional changes observed. This study suggests that exposures to exogenous compounds during preimplantation may unintentionally reprogram the human embryo, possibly leading to suboptimal development and longer-term health outcomes.
Gastrulation controls the emergence of cellular diversity and axis patterning in the early embryo. In mammals, this transformation is orchestrated by dynamic signalling centres at the interface of embryonic and extraembryonic tissues. Elucidating the molecular framework of axis formation in vivo is fundamental for our understanding of human development and to advance stem-cell-based regenerative approaches. Here, we illuminate early gastrulation of marmoset embryos in utero by spatial transcriptomics and stem cell-based embryo models. Gaussian process regression-based 3D-transcriptomes delineate the emergence of the anterior visceral endoderm, which is hallmarked by conserved (HHEX, LEFTY2, LHX1) and primate-specific (POSTN, SDC4, FZD5) factors. WNT signalling spatially coordinates primitive streak formation in the embryonic disc and is counteracted by SFRP1/2 to sustain pluripotency in the anterior domain. Amnion specification occurs at the boundaries of the embryonic disc through ID1/2/3 in response to BMP-signalling, providing a developmental rationale for amnion differentiation of primate pluripotent stem cells (PSCs). Spatial identity mapping demonstrates that primed marmoset PSCs exhibit highest similarity to the anterior embryonic disc, while naïve PSCs resemble the preimplantation epiblast. Our 3D-transcriptome models reveal the molecular code of lineage specification in the primate embryo and provide an in vivo reference to decipher human development.
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