SUMMARY
Embryonic stem cells (ESCs) repress the expression of exogenous proviruses and endogenous retroviruses (ERVs). Here, we systematically dissected the cellular factors involved in provirus repression in embryonic carcinomas (ECs) and ESCs by a genome-wide siRNA screen. Histone chaperones (Chaf1a/b), sumoylation factors (Sumo2/Ube2i/Sae1/Uba2/Senp6), and chromatin modifiers (Trim28/Eset/At-f7ip) are key determinants that establish provirus silencing. RNA-seq analysis uncovered the roles of Chaf1a/b and sumoylation modifiers in the repression of ERVs. ChIP-seq analysis demonstrates direct recruitment of Chaf1a and Sumo2 to ERVs. Chaf1a reinforces transcriptional repression via its interaction with members of the NuRD complex (Kdm1a, Hdac1/2) and Eset, while Sumo2 orchestrates the provirus repressive function of the canonical Zfp809/Trim28/Eset machinery by sumoylation of Trim28. Our study reports a genome-wide atlas of functional nodes that mediate proviral silencing in ESCs and illuminates the comprehensive, interconnected, and multi-layered genetic and epigenetic mechanisms by which ESCs repress retroviruses within the genome.
Abstract. It is being suggested that particle-bound or particle-induced
reactive oxygen species (ROS), which significantly contribute to the
oxidative potential (OP) of aerosol particles, are a promising metric
linking aerosol compositions to toxicity and adverse health effects.
However, accurate ROS quantification remains challenging due to the reactive
and short-lived nature of many ROS components and the lack of appropriate
analytical methods for a reliable quantification. Consequently, it remains
difficult to gauge their impact on human health, especially to identify how
aerosol particle sources and atmospheric processes drive particle-bound ROS
formation in a real-world urban environment. In this study, using a novel online particle-bound ROS instrument (OPROSI),
we comprehensively characterized and compared the formation of ROS in
secondary organic aerosols (SOAs) generated from organic compounds that
represent anthropogenic (naphthalene, SOANAP) and biogenic (β-pinene, SOAβPIN) precursors. The SOA mass was condensed onto
soot particles (SP) under varied atmospherically relevant conditions
(photochemical aging and humidity) to mimic the SOA formation from a mixing
of traffic-related carbonaceous primary aerosols and volatile organic compounds (VOCs). We systematically
analyzed the ability of the aqueous extracts of the two aerosol types
(SOANAP-SP and SOAβPIN-SP) to induce ROS production
and OP. We further investigated cytotoxicity and cellular ROS production
after exposing human lung epithelial cell cultures (A549) to extracts of the
two aerosols. A significant finding of this study is that more than 90 %
of all ROS components in both SOA types have a short lifetime, highlighting
the need to develop online instruments for a meaningful quantification of
ROS. Our results also show that photochemical aging promotes particle-bound
ROS production and enhances the OP of the aerosols. Compared to SOAβPIN-SP, SOANAP-SP elicited a higher acellular and cellular ROS
production, a higher OP, and a lower cell viability. These consistent results
between chemical-based and biological-based analyses indicate that
particle-bound ROS quantification could be a feasible metric to predict
aerosol particle toxicity and adverse human effects. Moreover, the cellular
ROS production caused by SOA exposure not only depends on aerosol type but
is also affected by exposure dose, highlighting a need to mimic the process
of particle deposition onto lung cells and their interactions as
realistically as possible to avoid unknown biases.
scite is a Brooklyn-based organization that helps researchers better discover and understand research articles through Smart Citations–citations that display the context of the citation and describe whether the article provides supporting or contrasting evidence. scite is used by students and researchers from around the world and is funded in part by the National Science Foundation and the National Institute on Drug Abuse of the National Institutes of Health.