DNA damage triggers diverse cancers, particularly hepatocellular carcinoma (HCC), but the intrinsic link between DNA damage and tumorigenesis remains unclear. Due to its role as an epigenetic and transcriptional regulator, histone deacetylase 3 (HDAC3) is essential for DNA damage control and is often aberrantly expressed in human HCC. In this study, we used individual class I HDAC member-deficient mice to demonstrate that K9 in histone H3 (H3K9), which is the critical site for the assembly of DNA damage response complexes, is exclusively targeted by HDAC3. Ablation of HDAC3 disrupted the deacetylation and consequent trimethylation of H3K9 (H3K9me3), the first step in double-strand break (DSB) repair, and led to the accumulation of damaged DNA. Simultaneously, hyperacetylated H3K9 (H3K9ac) served as a transcriptional activator and enhanced multiple signaling pathways to promote tumorigenesis. Together these results show that HDAC3 targets the H3K9ac/H3K9me3 transition to serve as a critical regulator that controls both DNA damage repair and the transcription of many tumor-related genes. Moreover, these findings provide novel insights into the link between DNA damage and transcriptional reprogramming in tumorigenesis.
Histone deacetylase 3 (HDAC3) plays pivotal roles in cell cycle regulation and is often aberrantly expressed in various cancers including hepatocellular carcinoma (HCC), but little is known about its role in liver regeneration and liver cancer cells proliferation. Using an inducible hepatocyte-selective HDAC3 knockout mouse, we find that lack of HDAC3 dramatically impaired liver regeneration and blocked hepatocyte proliferation in the G1 phase entry. HDAC3 inactivation robustly disrupted the signal transducer and activator of transcription 3 (STAT3) cascade. HDAC3 silencing impaired the ac-STAT3-to-p-STAT3 transition in the cytoplasm, leading to the subsequent breakdown of STAT3 signaling. Furthermore, overexpressed HDAC3 was further associated with increased tumor growth and a poor prognosis in HCC patients. Inhibition of HDAC3 expression reduced liver cancer cells growth and inhibited xenograft tumor growth. Our results suggest that HDAC3 is an important regulator of STAT3-dependent cell proliferation in liver regeneration and cancer. These findings provide novel insights into the HDAC3–STAT3 pathway in liver pathophysiological processes.
Histone deacetylases 1 and 2 (HDAC1 and HDAC2) are ubiquitously expressed in tissues, including the liver, and play critical roles in numerous physiopathological processes. Little is known regarding the role of HDAC1 and HDAC2 in liver regeneration. In this study we generated mice in which Hdac1, Hdac2 or both genes were selectively knocked out in hepatocytes to investigate the role of these genes in liver regeneration following hepatic injury induced by partial hepatectomy or carbon tetrachloride administration. The loss of HDAC1 and/or HDAC2 (HDAC1/2) protein resulted in impaired liver regeneration. HDAC1/2 inactivation did not decrease hepatocytic 5-bromo-2-deoxyuridine uptake or the expression of proliferating cell nuclear antigen, cyclins, or cyclin-dependent kinases. However, the levels of Ki67, a mitotic marker that is expressed from the mid-G 1 phase to the end of mitosis and is closely involved in the regulation of mitotic progression, were greatly decreased, and abnormal mitosis lacking Ki67 expression was frequently observed in HDAC1/2-deficient livers. The down-regulation of either HDAC1/2 or Ki67 in the mouse liver cancer cell line Hepa1-6 resulted in similar mitotic defects. Finally, both HDAC1 and HDAC2 proteins were associated with the Ki67 gene mediated by CCAAT/enhancer-binding protein b. Conclusion: Both HDAC1 and HDAC2 play crucial roles in the regulation of liver regeneration. The loss of HDAC1/2 inhibits Ki67 expression and results in defective hepatocyte mitosis and impaired liver regeneration. (HEPATOLOGY 2013;58:2089-2098
Temporal persistence is as important for nanocarriers as spatial accuracy. However, because of the insufficient aggreagtion and short retention time of chemotherapy drugs in tumors, their clinical application is greatly limited. A drug delivery approach dependent on the sensitivity to an enzyme present in the microenvironment of the tumor is designed to exhibit different sizes in different sites, achieving enhanced drug permeability and retention to improve tumor nanotherapy efficacy. In this work, we report a small-molecule peptide drug delivery system containing both tumor-targeting groups and enzyme response sites. This system enables the targeted delivery of peptide nanocarriers to tumor cells and a unique response to alkaline phosphatase (ALP) in the tumor microenvironment to activate morphological transformation and drug release. The amphiphilic peptide AYR self-aggregated into a spherical nanoparticle structure after encapsulating the lipid-soluble model drug doxorubicin (DOX) and rapidly converted to nanofibers via the induction of ALP. This morphological transformation toward a high aspect ratio allowed rapid, as well as effective drug release to tumor location while enhancing specific toxicity to tumor cells. Interestingly, this "transformer"-like drug delivery strategy can enhance local drug accumulation and effectively inhibit drug efflux. In vitro along with in vivo experiments further proved that the permeability and retention of antitumor drugs in tumor cells and tissues were significantly enhanced to reduce toxic side effects, and the therapeutic effect was remarkably improved compared with that of nondeformable drug-loaded peptide nanocarriers. The developed AYR nanoparticles with the ability to undergo morphological transformation in situ can improve local drug aggregation and retention time at the tumor site. Our findings provide a new and simple method for nanocarrier morphology transformation in novel cancer treatments.
Acute liver failure (ALF) is associated with high mortality, and a poor understanding of the underlying pathophysiology has resulted in a lack of effective treatments so far. Here, using an amatoxin‐induced rhesus monkey model of ALF, we panoramically revealed the cellular and molecular events that lead to the development of ALF. The challenged monkeys with toxins underwent a typical course of ALF including severe hepatic injury, systemic inflammation and eventual death. Adaptive immune was not noticeably disturbed throughout the progress of ALF. A systematic examination of serum factors and cytokines revealed that IL‐6 increase was the most rapid and drastic. Interestingly, we found that IL‐6 was mainly produced by circulating monocytes. Furthermore, ablation of monocyte‐derived IL‐6 in mice decreased liver injury and systemic inflammation following chemical injection. Our findings reveal a critical role of circulating monocytes in initiating and accelerating ALF, indicating a potential therapeutic target in clinical treatment for ALF.
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