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DNA damage signaling, impairment of cell cycle progression, and apoptosis triggered by 5-ethynyl-2'-deoxyuridine incorporated into DNA.
The "click chemistry" approach utilizing 5-ethynyl-2'-deoxyuridine (EdU) as a DNA precursor was recently introduced to assess DNA replication and adapted to flow- and imaging-cytometry. In the present study, we observed that EdU, once incorporated into DNA, induces DNA damage signaling (DDS) such as phosphorylation of ATM on Ser1981, of histone H2AX on Ser139, of p53 on Ser15, and of Chk2 on Thr68. It also perturbs progression of cells through the cell cycle and subsequently induces apoptosis. These effects were observed in non-small cell lung adenocarcinoma A549 as well as in B-cell human lymphoblastoid TK6 and WTK1 cells, differing in the status of p53 (wt versus mutated). After 1 h EdU pulse-labeling, the most affected was cells progression through the S phase subsequent to that at which they had incorporated EdU. This indicates that DNA replication using the template containing incorporated EdU is protracted and triggers DDS. Furthermore, progression of cells having DNA pulse-labeled with EdU led to accumulation of cells in G2 , likely by activating G2 checkpoint. Consistent with the latter was activation of p53 and Chk2. Although a correlation was observed in A549 cells between the degree of EdU incorporation and the extent of γH2AX induction, such correlation was weak in TK6 and WTK1 cells. The degree of perturbation of the cell cycle kinetics by the incorporated EdU was different in the wt p53 TK6 cells as compared to their sister WTK1 cell line having mutated p53. The data are thus consistent with the role of p53 in modulating activation of cell cycle checkpoints in response to impaired DNA replication. The confocal microscopy analysis of the 3D images of cells exposed to EdU for 1 h pulse and then grown for 24 or 48 h revealed an increased number of colocalized γH2AX and p53BP1 foci considered to be markers of DNA double-strand breaks and enlarged nuclei.
Document Type:

Reference

Product Catalog Number:

05-636
Product Catalog Name:

Anti-phospho-Histone H2A.X (Ser139) Antibody, clone JBW301
Histone H3 lysine 4 methylation marks postreplicative human cytomegalovirus chromatin.
In the nuclei of permissive cells, human cytomegalovirus genomes form nucleosomal structures initially resembling heterochromatin but gradually switching to a euchromatin-like state. This switch is characterized by a decrease in histone H3 K9 methylation and a marked increase in H3 tail acetylation and H3 K4 methylation across the viral genome. We used ganciclovir and a mutant virus encoding a reversibly destabilized DNA polymerase to examine the impact of DNA replication on histone modification dynamics at the viral chromatin. The changes in H3 tail acetylation and H3 K9 methylation proceeded in a DNA replication-independent fashion. In contrast, the increase in H3 K4 methylation proved to depend widely on viral DNA synthesis. Consistently, labeling of nascent DNA using "click chemistry" revealed preferential incorporation of methylated H3 K4 into viral (but not cellular) chromatin during or following DNA replication. This study demonstrates largely selective epigenetic tagging of postreplicative human cytomegalovirus chromatin.
Document Type:

Reference

Product Catalog Number:

Multiple
Product Catalog Name:

Multiple
Optimization of activity-based probes for proteomic profiling of histone deacetylase complexes.
Histone deacetylases (HDACs) are key enzymatic regulators of the epigenome and serve as promising targets for anticancer therapeutics. Recently, we developed a photoreactive clickable probe, SAHA-BPyne, to report on HDAC activity and complex formation in native biological systems. Here, we investigate the selectivity, sensitivity, and inhibitory properties of SAHA-BPyne and related potential activity-based probes for HDACs. While we identified several probes that are potent HDAC inhibitors and label HDAC complex components in native proteomic preparations, SAHA-BPyne was markedly superior for profiling HDAC activities in live cells. Interestingly, the enhanced performance of SAHA-BPyne as an in situ activity-based probe could not be solely ascribed to potency in HDAC binding, implying that other features of the molecule were key to efficient active site-directed labeling in living systems. Finally, we demonstrate the value of in situ profiling of HDACs by comparing the activity and expression of HDAC1 in cancer cells treated with the cytotoxic agent parthenolide. These results underscore the utility of activity-based protein profiling for studying HDAC function and may provide insight for the future development of click chemistry-based photoreactive probes for the in situ analysis of additional enzyme activities.
Document Type:

Reference

Product Catalog Number:

06-720
Product Catalog Name:

Anti-HDAC1 Antibody