8 research outputs found

    DNA methylation: insights into human evolution

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    A fundamental initiative for evolutionary biologists is to understand the molecular basis underlying phenotypic diversity. A long-standing hypothesis states that species-specific traits may be explained by differences in gene regulation rather than differences at the protein level. Over the past few years, evolutionary studies have shifted from mere sequence comparisons to integrative analyses in which gene regulation is key to understanding species evolution. DNA methylation is an important epigenetic modification involved in the regulation of numerous biological processes. Nevertheless, the evolution of the human methylome and the processes driving such changes are poorly understood. Here, we review the close interplay between Cytosine-phosphate-Guanine (CpG) methylation and the underlying genome sequence, as well as its evolutionary impact. We also summarize the latest advances in the field, revisiting the main literature on human and nonhuman primates. We hope to encourage the scientific community to address the many challenges posed by the field of comparative epigenomics.TMB is supported by ICREA (www.icrea.cat), EMBO YIP (www.embo.org) 2013, MICINN BFU2014-55090-P (www.mecd.gob.es), BFU2015-7116-ERC and BFU2015-6215-ERC. AJS is supported by NIH (www.nih.gov) grants DA033660, HG006696, HD073731, and MH097018, and research grant 6-FY13-92 from the March of Dimes Foundation. IHH is supported by AGAUR (Generalitat de Catalunya, Spain; www.gencat.cat/agaur/) and RGP by a fellowship from MICINN (www.mecd.gob.es). We also acknowledge the Barcelona Zoo (Ajuntament de Barcelona) for an award to IHH

    Measurement of branching ratio and Bs0 lifetime in the decay Bs0 -> J/psi f0(980) at CDF

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    We present a study of Bs0 decays to the CP-odd final state J/psi f0(980) with J/psi -> mu+ mu- and f0(980) -> pi+ pi-. Using ppbar collision data with an integrated luminosity of 3.8/fb collected by the CDF II detector at the Tevatron we measure a Bs0 lifetime of tau(Bs0 -> J/psi f0(980)) = 1.70 -0.11+0.12(stat) +-0.03(syst) ps. This is the first measurement of the Bs0 lifetime in a decay to a CP eigenstate and corresponds in the standard model to the lifetime of the heavy Bs0 eigenstate. We also measure the product of branching fractions of Bs0 -> J/psi f0(980) and f0(980) -> pi+ pi- relative to the product of branching fractions of Bs0 -> J/psi phi and phi -> K+ K- to be R_f0/phi = 0.257 +_0.020(stat) +-0.014(syst), which is the most precise determination of this quantity to date

    A second update on mapping the human genetic architecture of COVID-19

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