Veronica Rodriguez-Bravo

The decision to enter mitosis: feedback and redundancy in the mitotic entry network

The decision to enter mitosis is mediated by a network of proteins that regulate activation of the cyclin B–Cdk1 complex. Within this network, several positive feedback loops can amplify cyclin B–Cdk1 activation to ensure complete commitment to a mitotic state once the decision to enter mitosis has been made. However, evidence is accumulating that several components of the feedback loops are redundant for cyclin B–Cdk1 activation during normal cell division. Nonetheless, defined feedback loops become essential to promote mitotic entry when normal cell cycle progression is perturbed. Recent data has demonstrated that at least three Plk1-dependent feedback loops exist that enhance cyclin B–Cdk1 activation at different levels. In this review, we discuss the role of various feedback loops that regulate cyclin B–Cdk1 activation under different conditions, the timing of their activation, and the possible identity of the elusive trigger that controls mitotic entry in human cells.

Plk1 self-organization and priming phosphorylation of HsCYK-4 at the spindle midzone regulate the onset of division in human cells

Self-regulated movement of Polo-like kinase 1 to the midzone of the mitotic spindle initiates a local signaling cascade that activates the cell division machinery at the cells equator.

Targeting cancer stem cells to suppress acquired chemotherapy resistance

Acquired resistance has curtailed cancer survival since the dawn of the chemotherapy age more than half a century ago. Although the application of stem cell (SC) concepts to cancer captured the imagination of scientists for many years, only the last decade has yielded substantial evidence that cancer SCs (CSCs) contribute to chemotherapy resistance. Recent studies suggest that the functional and molecular properties of CSCs constitute therapeutic opportunities to improve the efficacy of chemotherapy. Here we review how these properties have stimulated combination strategies that suppress acquired resistance across a spectrum of malignancies. The clinical implementation of these strategies promises to rejuvenate the effort against an enduring challenge.

Different S/M Checkpoint Responses of Tumor and Non–Tumor Cell Lines to DNA Replication Inhibition

Cell cycle checkpoint abrogation, especially the inhibition of Chk1 in combination with DNA-damaging treatments, has been proposed as a promising way of sensitizing cancer cells. However, less is known about the possibility to selectively affect tumor cells when they are treated with agents that block DNA synthesis in combination with replication checkpoint inhibitors. Here, we present clear insights in the different responses of tumor and non-transformed cells to the inhibition of DNA replication with hydroxyurea in combination with checkpoint abrogation via inhibition of Ataxia telangiectasia-mutated- (ATM) and Rad3-related/ATM (ATR/ATM) and Chk1 kinases. Interestingly, we find that non-transformed cell lines activate ATR/ATM- and Chk1-independent pathways in response to replication inhibition to prevent mitotic entry with unreplicated DNA. In contrast, tumor cell lines such as HCT116 and HeLa cells rely entirely on Chk1 activity for a proper response to replication inhibitors. Our results show that p38 is activated in response to hydroxyurea treatment and collaborates with Chk1 to prevent mitotic entry in non-transformed cell lines by maintaining cyclin B1/Cdk1 complexes inactive. Furthermore, DNA replication arrest down-regulates cyclin B1 promoter activity in non-transformed cells, but not in tumor cells in a Chk1- and p38-independent way. Thus, our data show that non-transformed cells present a more robust DNA replication checkpoint response compared with tumor cells that involves activation of the p38 pathway. We show that some of these responses to replication block can be lost in tumor cells, causing a defective checkpoint and providing a rationale for tumor-selective effects of combined therapies.

Chk1- and Claspin-Dependent but ATR/ATM– and Rad17-Independent DNA Replication Checkpoint Response in HeLa Cells

When DNA synthesis is inhibited, DNA replication checkpoint is activated to prevent mitosis entry without fully replicated DNA. In Xenopus, caffeine-sensitive kinases [ataxia telangiectasia mutated (ATM) and ATM-related protein (ATR)] are essential in this checkpoint response, but in mammal cells an ATR/ATM-independent checkpoint response to DNA synthesis inhibition exists. Using HeLa cells, which have a caffeine-insensitive checkpoint response, we have analyzed here which molecules known to be involved in the DNA replication checkpoint participate in the caffeine-insensitive response. When DNA synthesis was inhibited in the presence of UCN01 or after knocking down Chk1 expression [Chk1 small interfering RNA (siRNA)], HeLa cells entered into aberrant mitosis. Consequently, Chk1 is essential for both the ATR/ATM-dependent and ATR/ATM-independent checkpoint response in HeLa cells. Neither wortmannin, Ly294002, nor SB202190 abrogated the caffeine-insensitive checkpoint response, indicating that DNA-PK and p38 alpha,beta are not involved in the ATR/ATM-independent Chk1 activation upon DNA synthesis inhibition. Using siRNA to knock down Rad17 and claspin, two molecules involved in sensing stalled replication forks, we also showed that claspin but not Rad17 is essential for the ATR/ATM-independent checkpoint response. Inhibition of DNA synthesis in HeLa cells led to a decrease in cyclin B1 protein accumulation that was abrogated when UCN01 was added or when claspin was knocked down. We conclude that upon DNA synthesis inhibition, Chk1 can be activated in a claspin-dependent manner independently of ATR and ATM, leading to cyclin B1 down-regulation and providing the cells of an additional mechanism to inhibit mitosis entry.

The PP2AB56 phosphatase promotes the association of Cdc20 with APC/C in mitosis

ABSTRACT PP2A comprising B56 regulatory subunit isoforms (PP2AB56) is a serine/threonine phosphatase essential for mitosis. At the kinetochore, PP2AB56 both stabilizes microtubule binding and promotes silencing of the spindle assembly checkpoint (SAC) through its association with the SAC protein BubR1. Cells depleted of the B56 regulatory subunits of PP2A are delayed in activation of Cdc20-containing APC/C (APC/CCdc20), which is an essential step for mitotic exit. It has been hypothesized that this delay arises from increased production of the mitotic checkpoint complex (MCC), an APC/CCdc20 inhibitor formed at unattached kinetochores through SAC signaling. In contrast to this prediction, we show that depletion of B56 subunits does not increase the amount or stability of the MCC. Rather, delays in APC/CCdc20 activation in B56-depleted cells correlate with impaired Cdc20 binding to APC/C. Stimulation of APC/CCdc20 assembly does not require binding between PP2AB56 and BubR1, and thus this contribution of PP2AB56 towards mitotic exit is distinct from its functions at kinetochores. PP2AB56 associates with APC/C constitutively in a BubR1-independent manner. A mitotic phosphorylation site on Cdc20, known to be a substrate of PP2AB56, modulates APC/CCdc20 assembly. These results elucidate the contributions of PP2AB56 towards completion of mitosis. Highlighted Article: Cdc20-dependent activation of the APC/C is essential for chromosome segregation and exit from mitosis. We show that the PP2AB56 phosphatase is required for the assembly of APC/CCdc20.

The role of GATA2 in lethal prostate cancer aggressiveness

Advanced prostate cancer is a classic example of the intractability and consequent lethality that characterizes metastatic carcinomas. Novel treatments have improved the survival of men with prostate cancer; however, advanced prostate cancer invariably becomes resistant to these therapies and ultimately progresses to a lethal metastatic stage. Consequently, detailed knowledge of the molecular mechanisms that control prostate cancer cell survival and progression towards this lethal stage of disease will benefit the development of new therapeutics. The transcription factor endothelial transcription factor GATA-2 (GATA2) has been reported to have a key role in driving prostate cancer aggressiveness. In addition to being a pioneer transcription factor that increases androgen receptor (AR) binding and activity, GATA2 regulates a core subset of clinically relevant genes in an AR-independent manner. Functionally, GATA2 overexpression in prostate cancer increases cellular motility and invasiveness, proliferation, tumorigenicity, and resistance to standard therapies. Thus, GATA2 has a multifaceted function in prostate cancer aggressiveness and is a highly attractive target in the development of novel treatments against lethal prostate cancer.

Isolation of cancer stem cells from human prostate cancer samples.

The cancer stem cell (CSC) model has been considerably revisited over the last two decades. During this time CSCs have been identified and directly isolated from human tissues and serially propagated in immunodeficient mice, typically through antibody labeling of subpopulations of cells and fractionation by flow cytometry. However, the unique clinical features of prostate cancer have considerably limited the study of prostate CSCs from fresh human tumor samples. We recently reported the isolation of prostate CSCs directly from human tissues by virtue of their HLA class I (HLAI)-negative phenotype. Prostate cancer cells are harvested from surgical specimens and mechanically dissociated. A cell suspension is generated and labeled with fluorescently conjugated HLAI and stromal antibodies. Subpopulations of HLAI-negative cells are finally isolated using a flow cytometer. The principal limitation of this protocol is the frequently microscopic and multifocal nature of primary cancer in prostatectomy specimens. Nonetheless, isolated live prostate CSCs are suitable for molecular characterization and functional validation by transplantation in immunodeficient mice.

Generation of Prostate Cancer Cell Models of Resistance to the Anti-mitotic Agent Docetaxel

Microtubule targeting agents (MTAs) are a mainstay in the treatment of a wide range of tumors. However, acquired resistance to chemotherapeutic drugs is a common mechanism of disease progression and a prognostic-determinant feature of malignant tumors. In prostate cancer (PC), resistance to MTAs such as the taxane Docetaxel dictates treatment failure as well as progression towards lethal stages of disease that are defined by a poor prognosis and high mortality rates. Though studied for decades, the array of mechanisms contributing to acquired resistance are not completely understood, and thus pose a significant limitation to the development of new therapeutic strategies that could benefit patients in these advanced stages of disease. In this protocol, we describe the generation of Docetaxel-resistant prostate cancer cell lines that mimic lethal features of late-stage prostate cancer, and therefore can be used to study the mechanisms by which acquired chemoresistance arises. Despite potential limitations intrinsic to a cell based model, such as the loss of resistance properties over time, the Docetaxel-resistant cell lines produced by this method have been successfully used in recent studies and offer the opportunity to advance our molecular understanding of acquired chemoresistance in lethal prostate cancer.

Targeting sarcoma tumor-initiating cells through differentiation therapy

Human leukocyte antigen class I (HLA-I) down-regulation has been reported in many human cancers to be associated with poor clinical outcome. However, its connection to tumor-initiating cells (TICs) remains unknown. In this study, we report that HLA-I is down-regulated in a subpopulation of cells that have high tumor initiating capacity in different types of human sarcomas. Detailed characterization revealed their distinct molecular profiles regarding proliferation, apoptosis and stemness programs. Notably, these TICs can be induced to differentiate along distinct mesenchymal lineages, including the osteogenic pathway. The retinoic acid receptor signaling pathway is overexpressed in HLA-1 negative TICs. All-trans retinoic acid treatment successfully induced osteogenic differentiation of this subpopulation, in vitro and in vivo, resulting in significantly decreased tumor formation. Thus, our findings indicate down-regulated HLA-I is a shared feature of TICs in a variety of human sarcomas, and differentiation therapy strategies may specifically target undifferentiated TICs and inhibit tumor formation.