Lack of RB protein correlates with increased sensitivity to UV-radiation-induced apoptosis in human breast cancer cells

The Role of RB in Prostate Cancer Progression

The RB tumor suppressor is one of the most commonly deleted/mutated genes in human cancers. In prostate cancer specifically, mutation of RB is most frequently observed in aggressive, metastatic disease. As one of the earliest tumor suppressors to be identified, the molecular functions of RB that are lost in tumor development have been studied for decades. Earlier work focused on the canonical RB pathway connecting mitogenic signaling to the cell cycle via Cyclin/CDK inactivation of RB, thereby releasing the E2F transcription factors. More in-depth analysis revealed that RB-E2F complexes regulate cellular processes beyond proliferation. Most recently, "non-canonical" roles for RB function have been expanded beyond its E2F interactions, which may play a particular role in advanced prostate cancer. For example, in mouse models of prostate cancer, loss of RB has been shown to induce lineage plasticity, which enables resistance to androgen deprivation therapy. This increased understanding of the potential downstream functions of RB in prostate cancer may lead the way to identifying therapeutic vulnerabilities in cells following RB loss.

Radiation induces premature chromatid separation via the miR-142-3p/Bod1 pathway in carcinoma cells

Radiation-induced genomic instability plays a vital role in carcinogenesis. Bod1 is required for proper chromosome biorientation, and Bod1 depletion increases premature chromatid separation. MiR-142-3p influences cell cycle progression and inhibits proliferation and invasion in cervical carcinoma cells. We found that radiation induced premature chromatid separation and altered miR-142-3p and Bod1 expression in 786-O and A549 cells. Overexpression of miR-142-3p increased premature chromatid separation and G2/M cell cycle arrest in 786-O cells by suppressing Bod1 expression. We also found that either overexpression of miR-142-3p or knockdown of Bod1 sensitized 786-O and A549 cells to X-ray radiation. Overexpression of Bod1 inhibited radiation- and miR-142-3p-induced premature chromatid separation and increased resistance to radiation in 786-O and A549 cells. Taken together, these results suggest that radiation alters miR-142-3p and Bod1 expression in carcinoma cells, and thus contributes to early stages of radiation-induced genomic instability. Combining ionizing radiation with epigenetic regulation may help improve cancer therapies.

[Aberrant Expression of Rb and pRb-780, pRb-795 in Lung Adenocarcinoma Patients with EGFR Mutations and Their Clinical Significance]

背景与目的

Rb作为重要的抑癌基因，调控细胞周期的进程。各种原因导致的Rb功能异常均可导致细胞的持续过度增殖从而导致肿瘤的发生。Rb蛋白表达缺失或减弱及过度磷酸化是Rb功能异常的重要机制。具有突变的表皮生长因子受体（epidermal growth factor receptor, EGFR）基因是肺腺癌重要的驱动基因，在肺癌的发生发展中起着重要的作用。本研究目的在于探讨Rb在EGFR突变的肺腺癌中的存在状态。

方法

取23例具有EGFR突变的肺腺癌标本，用免疫组化的方法分析Rb、pRb-780、pRb-795表达状态及临床特征。

结果

在23例EGFR突变的肺腺癌患者中Rb蛋白表达缺失/减弱频率为69.6%，pRb-780、pRb-795过表达的频率分别为73.9%、69.6%。23例患者均存在Rb表达缺失/减弱或Rb过度磷酸化。进一步分析发现，pRb-780过表达在晚期患者中发生更多（P=0.022）；pRb-795过表达在晚期患者中发生更多，但无统计学差异（P=0.074）。

结论

在EGFR突变的肺腺癌患者中，频繁发生Rb的表达缺失/减弱或过度磷酸化，Rb功能异常是EGFR突变肺腺癌患者重要的发病机制。

Down-regulation of BTG1 by miR-454-3p enhances cellular radiosensitivity in renal carcinoma cells

BACKGROUND

B cell translocation gene 1 (BTG1) has long been recognized as a tumor suppressor gene. Recent reports demonstrated that BTG1 plays an important role in progression of cell cycle and is involved in cellular response to stressors. However, the microRNAs mediated regulatory mechanism of BTG1 expression has not been reported so far. MicroRNAs can effectively influence tumor radiosensitivity by preventing cell cycle progression, resulting in enhancement of the cytotoxicity of radiotherapy efficacy. This study aimed to demonstrating the effects of microRNAs on the BTG1 expression and cellular radiosensitivity.

METHODS

The human renal carcinoma 786-O cells were treated with 5 Gy of X-rays. Expressions of BTG1 gene and miR-454-3p, which was predicted to target BTG1 by software algorithm, were analyzed by quantitative polymerase chain reaction. Protein expressions were assessed by Western blot. Luciferase assays were used to quantify the interaction between BTG1 3'-untranslated region (3'-UTR) and miR-454-3p. The radiosensitivity was quantified by the assay of cell viability, colony formation and caspase-3 activity.

RESULTS

The expression of the BTG1 gene in 786-O cells was significantly elevated after treatments with X-ray irradiation, DMSO, or serum starvation. The up-regulation of BTG1 after irradiation reduced cellular radiosensitivity as demonstrated by the enhanced cell viability and colony formation, as well as the repressed caspase-3 activity. In comparison, knock down of BTG1 by siRNA led to significantly enhanced cellular radiosensitivity. It was found that miR-454-3p can regulate the expression of BTG1 through a direct interaction with the 3'-UTR of BTG1 mRNA. Decreasing of its expression level correlates well with BTG1 up-regulation during X-ray irradiation. Particularly, we observed that over-expression of miR-454-3p by transfection inhibited the BTG1 expression and enhanced the radiosensitivity. In addition, cell cycle analysis showed that over-expression of miR-454-3p shifted the cell cycle arrest from G2/M phase to S phase.

CONCLUSIONS

Our results indicate that BTG1 is a direct target of miR-454-3p. Down-regulation of BTG1 by miR-454-3p renders tumor cells sensitive to radiation. These results may shed light on the potential application in tumor radiotherapy.

αB-crystallin promotes oncogenic transformation and inhibits caspase activation in cells primed for apoptosis by Rb inactivation

The retinoblastoma (Rb) tumor suppressor gene is frequently inactivated in cancer, resulting in deregulated activation of E2F transcription factors, which promote S-phase entry, p53-dependent and p53-independent apoptosis. Transformed cells evade p53-dependent apoptosis initiated by Rb inactivation by TP53 mutation. However, the mechanisms by which cancer cells circumvent p53-independent apoptosis in this context are poorly understood. Because Rb inactivation primes cells for apoptosis by p53-independent induction of procaspases, we postulated that αB-crystallin, an inhibitor of procaspase-3 activation, would suppress caspase activation in cells with combined Rb and p53 inactivation. Notably, αB-crystallin is commonly expressed in ER/PR/HER2 "triple-negative" breast carcinomas characterized by frequent Rb loss and TP53 mutation. We report that αB-crystallin (-/-) knock out (KO) MEFs immortalized by dominant negative (DN) p53 are resistant to transformation by the adenovirus E1A oncoprotein, which inactivates Rb, while wild-type (WT) MEFs are readily transformed by DN p53 and E1A. αB-crystallin (-/-) KO MEFs stably expressing DN p53 and E1A were more sensitive to chemotherapy-induced caspase-3 activation and apoptosis than the corresponding WT MEFs, despite comparable induction of procaspases by E1A. Similarly, silencing Rb in WT and αB-crystallin (-/-) KO MEFs immortalized by DN p53 increased procaspase levels and sensitized αB-crystallin (-/-) KO MEFs to chemotherapy. Furthermore, silencing αB-crystallin in triple-negative breast cancer cells, which lack Rb and express mutant p53, enhanced chemotherapy sensitivity compared to non-silencing controls. Our results indicate that αB-crystallin inhibits caspase activation in cells primed for apoptosis by Rb inactivation and plays a novel oncogenic role in the context of combined Rb and p53 inactivation.

Inhibition of DNA damage-induced apoptosis through Cdc7-mediated stabilization of Tob

BACKGROUND

Preventing unnecessary cell death is essential for DNA-damaged cells to carry out the DNA repair process.

RESULTS

Cdc7 inhibits the Cul4-DDB1(Cdt2)-dependent Tob degradation.

CONCLUSION

Cdc7 enables mild DNA-damaged cells to keep their viability by competing with the Tob degradation system.

SIGNIFICANCE

Cells deal with moderate DNA damage not only by cessation of the cell cycle but also through direct mediated pro-survival signaling. Cells respond to DNA damage by activating alternate signaling pathways that induce proliferation arrest or apoptosis. The correct balance between these two pathways is important for maintaining genomic integrity and preventing unnecessary cell death. The mechanism by which DNA-damaged cells escape from apoptosis during DNA repair is poorly understood. We show that the DNA replication-initiating kinase Cdc7 actively prevents unnecessary death in DNA-damaged cells. In response to mild DNA damage, Tob levels increase through both a transcriptional mechanism and protein stabilization, resulting in inhibition of pro-apoptotic signaling. Cells lacking Cdc7 expression undergo apoptosis after mild DNA damage, where Cul4-DDB1(Cdt2) induces Tob ubiquitination and subsequent degradation. Cdc7 phosphorylates and interacts with Tob to inhibit the Cul4-DDB1(Cdt2)-dependent Tob degradation. Thus, Cdc7 defines an essential pro-survival signaling pathway by contributing to stabilization of Tob, thereby the viability of DNA-damaged cells being maintained.

p38MAPK-activated AKT in HER-2 overexpressing human breast cancer cells acts as an EGF-independent survival signal

BACKGROUND

HER-2 is an epidermal growth factor receptor (EGFR) family receptor tyrosine kinase that is overexpressed in about 30% of human breast cancers correlating with a poor prognosis. Previous work in our laboratory has found that HER-2 overexpression plays a role in growth factor independence, anchorage independence, motility, and invasion of naturally occurring basement membranes. We also found that AKT was activated by p38MAPK in these cells, but this activation did not play a role in invasion. Since AKT has been shown in other systems to be a survival factor, we hypothesized that HER-2 mediated activation of AKT is necessary for growth factor independence.

METHODS

Human mammary epithelial cells transduced to overexpress HER-2, HER-2, PTEN, and Myr-AKT and the primary breast cancer cell lines SUM-149 and SUM-225 were used to dissect the signaling pathways leading to growth factor independence and anchorage-independent growth in HER-2 overexpressing cells.

RESULTS

We found that, in the absence of EGF, p38MAPK-activated AKT is necessary for HER-2 overexpressing cells to survive and to form colonies in soft agar. We show that EGF works as a survival signal in the absence of p38MAPK-mediated activation of AKT. We also show that human mammary epithelial cells expressing a constitutively active AKT do not require EGF for growth or colony formation in soft agar.

CONCLUSIONS

The data presented here indicate that AKT activation can compensate for EGF-mediated cell survival signals leading to growth factor independence and anchorage-independent growth.

The methyl-CpG-binding protein MECP2 is required for prostate cancer cell growth

The incidence of prostate cancer is increasing in western countries because of population aging. Prostate cancer begins as an androgen-dependent disease, but it can become androgen independent at a later stage or in tumors recurring after an antihormonal treatment. Although many genetic events have been described to be involved in androgen-dependent and/or -independent prostate cancer growth, little is known about the contribution of epigenetic events. Here we have examined the possibility that the methyl-CpG-binding protein MECP2 might play a role in controlling the growth of prostate cancer cells. Inhibition of MECP2 expression by stable short hairpin RNA stopped the growth of both normal and cancer human prostate cells. In addition, ectopic expression of the MECP2 conferred a growth advantage to human prostate cancer cells. More importantly, this expression allowed androgen-dependent cells to grow independently of androgen stimulation and to retain tumorigenic properties in androgen-depleted conditions. Analysis of signaling pathways showed that this effect is independent of androgen receptor signaling. Instead, MECP2 appears to act by maintaining a constant c-myc level during antihormonal treatment. We further show that MECP2-expressing cells possess a functional p53 pathway and are still responsive to chemotherapeutic drugs.

BRCA1-associated complexes: new targets to overcome breast cancer radiation resistance

Since BRCA1 was cloned a decade ago, significant progress has been made in defining its biochemical and biological functions, as well as its role in breast and ovarian cancers. BRCA1 has been implicated in many cellular processes, including DNA repair, cell cycle checkpoint control, protein ubiquitination and chromatin remodeling. This review examines the role(s) of BRCA1 in mediating these cellular processes, and discusses its potential involvement in the resistance of breast cancer to radiation-based therapies. Finally, the possibility that BRCA1-associated proteins may serve as new targets for breast cancer radiation therapy is explored. The activation or inactivation of these BRCA1-associated proteins may modify both the risk of developing cancers in BRCA1 mutation carriers and the efficacy of breast cancer therapy, including radiation.

17β-Estradiol modulates UVB-induced cellular responses in estrogen receptors positive human breast cancer cells

Genotoxic agents produce numerous cellular responses that are principally dedicated to maintain or restore DNA integrity. In human cells, nucleotide excision repair (NER) is one of the major pathways for the repair of DNA damage such as ultraviolet (UV) radiation-induced lesions. Endocrine disrupting compounds are environmental contaminants that interfere with the function of the endocrine system. Among them, the natural estrogen 17beta-estradiol (E(2)) exhibits the most potent activity. Some proteins directly or indirectly involved in NER also fulfill other functions such as transcription, DNA damage checkpoints or cell cycle. Moreover, steroids such as E(2) are believed to interact with a large number of proteins including some involved in NER and DNA damage checkpoint control. We therefore investigated the potential modulation of genotoxic stress-cells responses by E(2) treatment. Estrogen receptor (ER)-positive human breast cancer cells were submitted to E(2) before and/or after UVB irradiation and thereafter the repair kinetics of UV-induced DNA damage were evaluated. We report here that the repair rate of UVB-induced DNA damage is enhanced when cells are submitted to an estrogenic stimulation. Moreover, our results suggest that this response could be mediated by cell cycle regulatory proteins in a p53-independent manner.

Negative regulation of the expressions of cytokeratins 8 and 19 by SLUG repressor protein in human breast cells

Invasiveness of tumor cells is often determined by the profile of their expressed genes. To determine the gene expression differences between an invasive and a non-invasive human breast tumor cells, we selected BT-549 (invasive) and MDA-MB-468 (non-invasive) cells, and compared their transcriptomes by cDNA microarray analysis. Among the significant differences in gene expressions, notable are the up-regulation of cytokeratins 8 and 19, and down-regulation of metallothioneins 1G and IL in MDA-MB-468 cells. Since MDA-MB-468 cells do not express SLUG, a member of a small family of E2-box-binding zinc finger silencer proteins, we studied whether the cytokeratin gene overexpressions in these cells are due to the absence of SLUG. Inducible expression of SLUG in MDA-MB-468 cells inhibited the expressions of the cytokeratin 8 and 19 but not others as was revealed by microarray analysis. Similarly, siRNA knock down of SLUG in BT-549 cells increased the expressions of those cytokeratin mRNAs. SLUG levels in the cell regulated the function of cytokeratins 8 and 19 gene promoters. We conclude that the expressions of cytokeratins and metallothioneins may be associated with the differential invasive behaviors of these breast tumor cells and SLUG may have regulatory roles in this process.

Lack of functional pRb results in attenuated recovery of mRNA synthesis and increased apoptosis following UV radiation in human breast cancer cells

Lack of functional pRb results in attenuated recovery of mRNA synthesis and increased apoptosis following UV radiation in human breast cancer cells. We have previously demonstrated that a human breast cancer cell line, MDA-MB-468, which lacks the retinoblastoma protein (pRb), is particularly sensitive to low doses of ultraviolet (UV) radiation. These cells are 15-20-fold more sensitive to UV radiation than cells with wild-type pRb. In order to understand the mechanisms of the high apoptotic response of MDA-MB-468 cells to UV radiation, we examined the effects of UV on these cells with regards to both membrane-mediated events and DNA damage. We found that MDA-MB-468 cells were resistant to all ligand-induced death receptor signaling. In addition, although UV activated caspase 8 in MDA-MB-468 cells, a peptide inhibitor of caspase 8 failed to inhibit UV-induced apoptosis. We then tested the possibility that nuclear events mediated the enhanced sensitivity to UV-induced apoptosis in these cells. Unlike UV-resistant cells, MDA-MB-468 cells were unable to recover mRNA synthesis after 5 J/m2 UVC. We also found that the pRb-null DU-145 cells similarly had attenuated recovery of mRNA synthesis after UV radiation. In UV-resistant cells with wild-type pRb, the inactivation of pRb with HPV-16 E7 resulted in significant inhibition in their ability to recover mRNA synthesis and increased levels of apoptosis following UV radiation. Furthermore, pRb-null cells were deficient in repair of UV radiation-induced DNA damage. These data suggest that the sensitivity of MDA-MB-468 cells to UV radiation is due to defects in repair of DNA damage and recovery of mRNA synthesis rather than to membrane death receptor pathways. Inactivation of pRb may contribute to an increased sensitivity to UV radiation by attenuating repair of DNA lesions and recovery of mRNA synthesis following UV radiation.