Anne L. Burkhardt

Substrate-assisted inhibition of ubiquitin-like protein-activating enzymes: the NEDD8 E1 inhibitor MLN4924 forms a NEDD8-AMP mimetic in situ.

The NEDD8-activating enzyme (NAE) initiates a protein homeostatic pathway essential for cancer cell growth and survival. MLN4924 is a selective inhibitor of NAE currently in clinical trials for the treatment of cancer. Here, we show that MLN4924 is a mechanism-based inhibitor of NAE and creates a covalent NEDD8-MLN4924 adduct catalyzed by the enzyme. The NEDD8-MLN4924 adduct resembles NEDD8 adenylate, the first intermediate in the NAE reaction cycle, but cannot be further utilized in subsequent intraenzyme reactions. The stability of the NEDD8-MLN4924 adduct within the NAE active site blocks enzyme activity, thereby accounting for the potent inhibition of the NEDD8 pathway by MLN4924. Importantly, we have determined that compounds resembling MLN4924 demonstrate the ability to form analogous adducts with other ubiquitin-like proteins (UBLs) catalyzed by their cognate-activating enzymes. These findings reveal insights into the mechanism of E1s and suggest a general strategy for selective inhibition of UBL conjugation pathways.

Genome-Wide siRNA Screen for Modulators of Cell Death Induced by Proteasome Inhibitor Bortezomib

Multiple pathways have been proposed to explain how proteasome inhibition induces cell death, but mechanisms remain unclear. To approach this issue, we performed a genome-wide siRNA screen to evaluate the genetic determinants that confer sensitivity to bortezomib (Velcade (R); PS-341). This screen identified 100 genes whose knockdown affected lethality to bortezomib and to a structurally diverse set of other proteasome inhibitors. A comparison of three cell lines revealed that 39 of 100 genes were commonly linked to cell death. We causally linked bortezomib-induced cell death to the accumulation of ASF1B, Myc, ODC1, Noxa, BNIP3, Gadd45alpha, p-SMC1A, SREBF1, and p53. Our results suggest that proteasome inhibition promotes cell death primarily by dysregulating Myc and polyamines, interfering with protein translation, and disrupting essential DNA damage repair pathways, leading to programmed cell death.

Valosin-Containing Protein Phosphorylation at Ser784 in Response to DNA Damage

The response of eukaryotic cells to DNA damage includes the activation of phosphatidylinositol-3 kinase-related kinases (PIKK), such as ATM, ATR, and DNA-dependent protein kinase (DNA-PK). These three kinases have very similar substrate specificities in vitro, but in vivo, their substrates overlap only partially. Several in vivo substrates of ATM and ATR have been identified and almost all of them are involved in DNA damage-induced cell cycle arrest and/or apoptosis. In contrast, few in vivo substrates of DNA-PK have been identified. These include histone H2AX and DNA-PK itself. We identify here valosin-containing protein (VCP) as a novel substrate of DNA-PK and other PIKK family members. VCP is phosphorylated at Ser784 within its COOH terminus, a region previously shown to target VCP to specific intracellular compartments. Furthermore, VCP phosphorylated at Ser784 accumulated at sites of DNA double-strand breaks (DSBs). VCP is a protein chaperone that unfolds and translocates proteins. Its phosphorylation in response to DNA damage and its recruitment to sites of DNA DSBs could indicate a role of VCP in DNA repair.

Analysis of two pharmacodynamic biomarkers using acoustic micro magnetic particles on the ViBE bioanalyzer.

Pharmacodynamic responses to drug treatment are often used to confirm drug-on-target biological responses. Methods ranging from mass spectrometry to immunohistochemistry exist for such analyses. By far, the most extensively used methodologies employ antigen-specific antibodies for detection (at a minimum) and, in some cases, target quantitation as well. Using a novel frequency-modulating technology from BioScale called acoustic micro magnetic particle (AMMP) detection, two pathway biomarkers were chosen for pharmacodynamic analysis and compared with either AlphaScreen or LI-COR Western blot assays. For these studies, pharmacodynamic biomarkers for both proteasome and phosphoinositol 3-kinase inhibition were used. Our results show clearly that the BioScale technology is a robust and rapid method for measuring recombinant standards or endogenously derived proteins from both tissue culture and mouse xenograft tumor lysates. Moreover, the sensitivity obtained with the BioScale platform compares favorably with LI-COR Western blot and AlphaScreen technologies. Furthermore, the use of the ViBE Bioanalyzer eliminates the labor-intensive effort of Western blot analysis and is devoid of the optical and other endogenous interfering substances derived from lysates of xenograft tumors typically observed with AlphaScreen.

A Fully Synthetic and Biochemically Validated Phosphatidyl Inositol-3-Phosphate Hapten via Asymmetric Synthesis and Native Chemical Ligation

We report the synthesis and biochemical validation of a phosphatidyl inositol-3 phosphate (PI3P) immunogen. The inositol stereochemistry was secured through peptide-catalyzed asymmetric phosphorylation catalysis, and the subsequent incorporation of a cysteine residue was achieved by native chemical ligation (NCL). Conjugation of the PI3P hapten to maleimide-activated keyhole limpet hemocyanin (KLH) provided a PI3P immunogen, which was successfully used to generate selective PI3P antibodies. The incorporation of a sulfhydryl nucleophile into a phosphoinositide hapten demonstrates a general strategy to reliably access phosphoinositide immunogens.

Determination of complementary antibody pairs using protein A capture with the AlphaScreen assay format.

The utility of antibody reagents for the detection of specific cellular targets for both research and diagnostic applications is widespread and continually expanding. Often it is useful to develop specific antibodies as reagent pairs that distinguish different epitopes of the target such that sandwich enzyme-linked immunosorbent assay can be used for selective and specific detection. However, the identification of pairing antibodies is often cumbersome and labor-intensive even with the use of designed peptide-specific epitopes as antigens. We have developed a robust and high-throughput method for identifying pairing complementary antibodies derived either from commercial sources or during a rabbit hybridoma monoclonal screening and selection process using protein A capture with the AlphaScreen bead-based assay format. We demonstrate the value and effectiveness of this assay with three protein targets: Akt2, ATF3, and NAEβ (the β-subunit of the neddylation activation enzyme).

Quantifiable analysis of cellular pathway inhibition of a Nedd8-activating enzyme inhibitor, MLN4924, using AlphaScreen.

Cellular effects of a Nedd8-activating enzyme (NAE) inhibitor, MLN4924, using the AlphaScreen format were explored. MLN4924 acts as a substrate-assisted inhibitor of NAE by forming a tight binding Nedd8-MLN4924 adduct. The inhibited enzyme can no longer transfer Nedd8 downstream to modify and activate the E3 cullin-RING ligases. This results in the stabilization of proteins regulated by the proteasome, leading to cell death. These studies monitored the endogenous cellular changes to NAE∼Nedd8 thioester, the formation of the Nedd8-MLN4924 adduct, and the reduction in the Cul1-Nedd8. Lysates derived from MLN4924-treated HCT116 cells showed that whereas the β-subunit of NAE remained constant, reductions of both NAE∼Nedd8 thioester and Cul1-Nedd8 levels occurred with a concomitant rise of the adduct. Moreover, the formation of the Nedd8-MLN4924 adduct was approximately stoichiometric with the concentration of NAEβ. Higher density 384-well cell-based assays illustrated the kinetics of enzyme inactivation across a wider range of MLN4924 concentrations, showing a rapid loss of NAE∼Nedd8 thioester and Cul1-Nedd8. The reduction of NAE∼Nedd8 thioester precedes the loss of Cul1-Nedd8 at twice the rate. Finally, these results clearly demonstrate the utility of the homogeneous assay for quantitative assessment of these endogenous cellular components in a 384-well plate in response to inhibition of NAE by MLN4924.

Abstract A70: A genome‐wide siRNA screen for modulators of cell death induced by the proteasome inhibitor bortezomib

Multiple pathways have been proposed as the mechanism by which proteasome inhibition induces cell death. To clarify their relative importance, we performed a genome‐wide siRNA screen to evaluate the genetic determinants that confer sensitivity of the HCT‐116 colon cancer cell line to bortezomib (VELCADE®, PS‐341). The screen identified 100 genes whose knock‐down affects the lethality of bortezomib. From this list, the accumulation of the proteins ASF1B, Myc, ODC1, PMAIP1 (Noxa), BNIP3, Gadd45α, p‐SMC1A, SREBF1, and p53 by proteasome inhibition was linked to the induction of cell death. Fifty‐nine genes in the A375 melanoma cell line and 56 genes in the HeLa cervical cancer cell line showed similar interactions with bortezomib to those seen in HCT‐116 and a subset of 39 genes were common to all three cell lines. Finally, knockdown of these 100 genes in HCT‐116 cells similarly affected their responsiveness to a structurally diverse set of proteasome inhibitors. Our results suggest that proteasome inhibition promotes cell death primarily by dysregulating Myc and polyamines, interfering with protein translation, and disrupting essential DNA damage repair pathways, leading to programmed cell death. Citation Information: Mol Cancer Ther 2009;8(12 Suppl):A70.