Thomas D. Friedrich

Negative Regulation of Mitotic Promoting Factor by the Checkpoint Kinase Chk1 in Simian Virus 40 Lytic Infection

ABSTRACT Lytic infection of African green monkey kidney (CV-1) cells by simian virus 40 (SV40) is characterized by stimulation of DNA synthesis leading to bypass of mitosis and replication of cellular and viral DNA beyond a 4C DNA content. To define mechanisms underlying the absence of mitosis, the expression levels of upstream regulatory molecules of mitosis-promoting factor (MPF) were compared in parallel synchronized cultures of SV40-infected and uninfected CV-1 cells. The DNA replication/damage checkpoint kinase Chk1 was phosphorylated in both uninfected and SV40-infected cultures arrested at G1/S by mimosine, consistent with checkpoint activation. Following release of uninfected cultures from G1/S, Chk1 phosphorylation was lost even though Chk1 protein levels were retained. In contrast, G1/S-released SV40-infected cultures exhibited dephosphorylation of Chk1 in S phase, followed by an increase in Chk1 phosphorylation coinciding with entry of infected cells into >G2. Inhibitors of Chk1, UCN-01 and caffeine, induced mitosis and abnormal nuclear condensation and increased the protein kinase activity of MPF in SV40-infected CV-1 cells. These results demonstrate that SV40 lytic infection triggers components of a DNA damage checkpoint pathway. In addition, chemical inhibition of Chk1 activity suggests that Chk1 contributes to the absence of mitosis during SV40 lytic infection.

Heterobiaryl purine derivatives as potent antiproliferative agents: Inhibitors of cyclin dependent kinases. Part II

C-6 Biarylmethylamino purine derivatives of roscovitine (1) inhibit cyclin dependent kinases and demonstrate potent antiproliferative activity. Replacement of the aryl rings of the C-6 biarylmethylamino group with heterobiaryl rings has provided compounds with significantly improved activity. In particular, derivatives 18 g and 9 c demonstrated 1000-fold and 1250-fold improvements, respectively, in the growth inhibition of HeLa cells compared to roscovitine (1).

Distinct patterns of MCM protein binding in nuclei of S phase and rereplicating SV40‐infected monkey kidney cells

Simian Virus 40 (SV40) infection of growth‐arrested monkey kidney cells stimulates S phase entry and the continued synthesis of both viral and cellular DNA. Infected cells can attain total DNA contents as high as DNA Index, DI = 5.0–6.0 (10–12C), with host cell DNA representing 70–80% of the total. In this study, SV40‐infected and uninfected control cells were compared to determine whether continued DNA replication beyond DI = 2.0 was associated with rebinding of the minichromosome maintenance (MCM) hexamer, the putative replicative helicase, to chromatin.

OKADAIC ACID INDUCES APPEARANCE OF THE MITOTIC EPITOPE MPM-2 IN SV40-INFECTED CV-1 CELLS WITH A >G2-PHASE DNA CONTENT

Simian virus 40 (SV40) infection of quiescent monkey kidney cells stimulates two successive rounds of cellular DNA synthesis without an intervening mitosis. This uncoupling of S phase and mitosis indicates that SV40 modulates pathways regulating the G2-to-M phase transition. To examine the integrity of mitotic initiation pathways in infected cells that have bypassed mitosis, SV40-infected CV-1 cells were treated with okadaic acid (OA), a known inducer of premature mitosis in other cell types. OA treatment triggered the appearance of the mitotic marker MPM-2 in SV40-infected CV-1 cells progressing through either the first (diploid) or second (tetraploid) S phases. These results demonstrate that a subset of mitotic pathways are intact but inactive in SV40-infected cells that have bypassed mitosis and initiated tetraploid S phase.

5-Functionalized indazoles as glucocorticoid receptor agonists

An indazole based series of glucocorticoid receptor agonists is reported. The SAR exploration of this scaffold yielded compounds with nanomolar affinity for the glucocorticoid receptor with indications of selectivity for the preferred transrepression mechanism; in vivo efficacy was observed in the mouse LPS induced TNFalpha model for compound 28.

Reduced expression of p27kip1 and increased hepatocyte proliferation in p53-deficient mice

Livers from wild‐type and p53‐deficient mice were analyzed for the expression of cell‐cycle regulatory proteins in an attempt to determine the mechanism for the increased proliferation of liver cells in p53‐deficient mice associated with enhanced susceptibility to aflatoxin‐induced liver cancer. The most striking difference found was a significant reduction of the cyclin‐dependent kinase inhibitor p27kip1 in the livers of 3‐mo‐old p53−/− mice, whereas only small changes were found in the expression of cyclins, cyclin‐dependent kinases, and the inhibitors p21cip1 and p16ink4a. Relative to wild‐type liver, the amounts of p27kip1 mRNA were reduced at both 1 and 3 mo, whereas the levels of p27kip1 protein were decreased only at 3 mo. These results identify an uncharacterized link between the expression of p53 and p27kip1 that may involve both transcriptional and post‐transcriptional regulation and allow hepatocytes to continue to proliferate after 3 wk of age. We postulate that this increased proliferation leads to increased susceptibility to aflatoxin‐induced hepatocarcinogenesis.

INCREASE IN TOTAL PROTEIN FOLLOWING INFECTION OF CV-1 CELLS WITH SV40 VIRUS AS ASSAYED BY FLOW CYTOMETRY

SummaryThe changes in cell size and total protein were determined for G1-arrested, contact-inhibited CV-1 cells infected with Simian virus 40 (SV40). The assays used were the Biorad total protein assays (Bradford and DC protein assays) on a standard number of cells, total protein as assayed by fluorescein isothiocyanate (FITC) and SR101 by flow cytometry, orthoganol (90°) light scatter by flow cytometry, and direct microscopic measurement with an ocular micrometer. Uninfected CV-1 cells and two cell lines with variations in DNA content (diploid vs. tetraploid) were used as controls for the studies presented. The results demonstrated a 40–60% increase in total protein at 32 to 42 h postinfection. These increases were similar to values obtained as control cells progress through the cell cycle. At later times postinfection (>42 h), total protein decreased due to cellular changes resulting from viral replication and cell death.

Quantitation of Cellular Proteins by Laser Scanning Cytometry

Flow Cytometry (FC) is a popular method for the simultaneous quantitation of multiple specific proteins and other molecules in each cell of a single cell suspension (1). Laser Scanning Cytometry (LSC) is a closely related technology that provides many of the benefits of FC and offers additional features that allow morphological and biochemical analysis of a cell population (2,3). In both methods, quantitation of endogenous cellular proteins generally requires antibodies against the protein of interest. These antibodies must be either directly labeled with a fluorochrome or detected by a fluorescently-labeled secondary antibody. Using fluorescently-labeled antibodies in combination with fluorescent dyes that quantitatively bind to DNA, both FC and LSC have been valuable in measuring the quantities of specific proteins in relation to cell cycle position (4). In contrast to FC, where a single cell suspension is passed through a fixed-position laser beam, LSC analyzes cells fixed to a surface such as a microscope slide or cover slip. Since the position of the cell on the slide is part of the recorded data, it is possible to visualize the cell after the initial recording event or to subsequently stain the cell with another fluorescent probe and make a second measurement. LSC also allows analysis of cells following biochemical treatments that are incompatible with analysis by FC. In this chapter we describe the value of LSC in analyzing chromatin-associated proteins. Specifically, we describe an in situ fractionation procedure that allows measurement of total and chromatin-associated MCM2, a DNA helicase subunit, as a function of cell cycle position.

Analysis of Viral Infection and Viral and Cellular DNA and Proteins by Flow Cytometry

Viruses are obligate intracellular parasites that require the host cell replication, transcription, and translation machinery for reproduction. Each viral group provides a unique series of viral‐cellular interactions. Studies have provided insight not only into viral replication and control of host functions, but also into cellular functions such as eukaryotic replication, transcription, and translation as well as the regulation of these events. This unit presents a protocol for flow cytometric monitoring of viral infection and quantitating viral‐cellular events. The availability of monoclonal and/or polyclonal antibodies directed to both viral and cellular proteins offers the ability to assay a specific molecule in the intact fixed cell and the opportunity to correlate viral events with cellular processes such as progression through the cell cycle.

A competitive inhibitor assay for SV40 T/pRB complex formation employing extracts of SV40-transformed human lung cells

SummarySimian virus 40 (SV40) large T antigen (T), a potent dominant oncogene product, forms a specific complex with the human retinoblastoma protein (pRb), a cellular growth suppressor. We have used a recombinant pRb fusion protein (GST-Rb) in combination with extracts from a line of SV40-transformed human lung cells (WI-26 VA4) to develop a simple, non-radioactive assay to rapidly screen for competitive inhibitors of T/pRb binding. We illustrate the use of the assay by demonstrating that several short peptides containing the signature sequence, Leu-X-Cys-X-Glu, can inhibit T/pRb complex formation. In contrast, peptides containing the related motif, Leu-X-Glu-X-Glu, including two peptides derived from the transcription factor E2F, are inactive in this assay. These results show that Glu cannot substitute for Cys in the Leu-X-Cys-X-Glu motif. This assay will facilitate the identification of agents that are inhibitors of T/pRb complex formation and that might exert effects on cellular growth regulation.