The chromatin structure of DNA determines genome compaction and activity
in the nucleus. On the basis of in vitro structures and electron microscopy (EM)
studies, the hierarchical model is that 11-nanometer DNA-nucleosome polymers
fold into 30- and subsequently into 120- and 300-to 700-nanometer fibers and
mitotic chromosomes. To visualize chromatin in situ, we identified a fluorescent
dye that stains DNA with an osmiophilic polymer and selectively enhances its
contrast in EM. Using ChromEMT (ChromEM tomography), we reveal the
ultrastructure and three-dimensional (3D) organization of individual chromatin
polymers, megabase domains, and mitotic chromosomes. We show that chromatin is a
disordered 5- to 24-nanometer-diameter curvilinear chain that is packed together
at different 3D concentration distributions in interphase and mitosis. Chromatin
chains have many different particle arrangements and bend at various lengths to
achieve structural compaction and high packing densities.
Preface
The 4D Nucleome Network aims to develop and apply approaches to map the structure and dynamics of the human and mouse genomes in space and time with the goal of gaining deeper mechanistic understanding of how the nucleus is organized and functions. The project will develop and benchmark experimental and computational approaches for measuring genome conformation and nuclear organization, and investigate how these contribute to gene regulation and other genome functions. Validated experimental approaches will be combined with biophysical modeling to generate quantitative models of spatial genome organization in different biological states, both in cell populations and in single cells.
ONYX-015 is an adenovirus that lacks the E1B-55K gene product for p53 degradation. Thus, ONYX-015 was conceived as an oncolytic virus that would selectively replicate in p53-defective tumor cells. Here we show that loss of E1B-55K leads to the induction, but not the activation, of p53 in ONYX-015-infected primary cells. We use a novel adenovirus mutant, ONYX-053, to demonstrate that loss of E1B-55K-mediated late viral RNA export, rather than p53 degradation, restricts ONYX-015 replication in primary cells. In contrast, we show that tumor cells that support ONYX-015 replication provide the RNA export function of E1B-55K. These data reveal that tumor cells have altered mechanisms for RNA export and resolve the controversial role of p53 in governing ONYX-015 oncolytic selectivity.
There is currently much interest in the idea of restoring p53 activity in tumor cells by inhibiting Hdm2/Mdm2. However, it has remained unclear whether this would also activate p53 in normal cells. Using a switchable endogenous p53 mouse model, which allows rapid and reversible toggling of p53 status between wild-type and null states, we show that p53 is spontaneously active in all tested tissues of mdm2-deficient mice, triggering fatal pathologies that include ablation of classically radiosensitive tissues. In apoptosis-resistant tissues, spontaneous unbuffered p53 activity triggers profound inhibition of cell proliferation. Such acute spontaneous p53 activity occurs in the absence of any detectable p53 posttranslational modification, DNA damage, or p19ARF signaling and triggers rapid p53 degradation.
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