Quad Screen Test, A Multiplexed Biomarker Assay for Prenatal Screening to Assess Birth Defects: The Columbia University Experience Using the Beckman Access2 Immunoassay Analyzer and Benetech PRA.

In the prenatal quad screen, the levels of four analytes in maternal serum are used to calculate the risk of serious birth defects. The Beckman Access2 Immunoassay System is an automated analyzer that enables rapid measurement of alpha-fetoprotein, unconjugated estriol, human chorionic gonadotropin, and dimeric inhibin A. The Benetech PRA software package is used to convert maternal serum analyte concentrations to multiples of the median (MoM) and calculates the risks of particular birth defects. The results from this simple and minimally invasive screen determine the need for more sensitive, specific, and usually riskier diagnostic procedures. We present herein some recent data from our experience at Columbia University Medical Center in New York, NY, using the Beckman Access2 immunoassay analyzer and Benetech PRA software package.

Ral GTPase down-regulation stabilizes and reactivates p53 to inhibit malignant transformation.

Ral GTPases are critical effectors of Ras, yet the molecular mechanism by which they induce malignant transformation is not well understood. In this study, we found the expression of K-Ras, RalB, and sometimes RalA, but not AKT1/2 and c-Raf, to be required for maintaining low levels of p53 in human cancer cells that harbor mutant K-Ras and wild-type p53. Down-regulation of K-Ras, RalB, and sometimes RalA increases p53 protein levels and results in a p53-dependent up-regulation of the expression of p21(WAF). K-Ras, RalA, and RalB depletion increases p53 stability as demonstrated by ataxia telangiectasia-mutated kinase activation, increased Ser-15 phosphorylation, and a significant (up to 6-fold) increase in p53 half-life. Furthermore, depletion of K-Ras and RalB inhibits anchorage-independent growth and invasion and interferes with cell cycle progression in a p53-dependent manner. Depletion of RalA inhibits invasion in a p53-dependent manner. Thus, expression of K-Ras and RalB and possibly RalA proteins is critical for maintaining low levels of p53, and down-regulation of these GTPases reactivates p53 by significantly enhancing its stability, and this contributes to suppression of malignant transformation.

Discovery of PI-1840, a novel noncovalent and rapidly reversible proteasome inhibitor with anti-tumor activity.

The proteasome inhibitor bortezomib is effective in hematologic malignancies such as multiple myeloma but has little activity against solid tumors, acts covalently, and is associated with undesired side effects. Therefore, noncovalent inhibitors that are less toxic and more effective against solid tumors are desirable. Structure activity relationship studies led to the discovery of PI-1840, a potent and selective inhibitor for chymotrypsin-like (CT-L) (IC50 value = 27 ± 0.14 nm) over trypsin-like and peptidylglutamyl peptide hydrolyzing (IC50 values >100 µm) activities of the proteasome. Furthermore, PI-1840 is over 100-fold more selective for the constitutive proteasome over the immunoproteasome. Mass spectrometry and dialysis studies demonstrate that PI-1840 is a noncovalent and rapidly reversible CT-L inhibitor. In intact cancer cells, PI-1840 inhibits CT-L activity, induces the accumulation of proteasome substrates p27, Bax, and IκB-α, inhibits survival pathways and viability, and induces apoptosis. Furthermore, PI-1840 sensitizes human cancer cells to the mdm2/p53 disruptor, nutlin, and to the pan-Bcl-2 antagonist BH3-M6. Finally, in vivo, PI-1840 but not bortezomib suppresses the growth in nude mice of human breast tumor xenografts. These results warrant further evaluation of a noncovalent and rapidly reversible proteasome inhibitor as potential anticancer agents against solid tumors.

Depletion of K-Ras promotes proteasome degradation of survivin.

Mutant K-Ras and survivin both contribute to oncogenesis, but little is known about K-Ras requirement for the maintenance of the high levels of survivin in human tumors. Here we demonstrate that K-Ras depletion significantly decreases survivin levels in human cancer cells that harbor mutant but not wild type K-Ras. K-Ras depletion attenuates both basal and drug-induced survivin levels. The mechanism by which K-Ras depletion decreases survivin levels is through ubiquitination and proteasomal degradation of survivin and is independent of survivin-Thr-34 phosphorylation. Depletion of RalA and RalB, but not Raf-1, Akt1 and Akt2, decreases survivin levels, suggesting that K-Ras may regulate survivin stability through its RalGDS/Ral but not PI3K/Akt and Raf-1/Mek effector pathways. Furthermore, the ability of mutant K-Ras to induce anchorage-independent growth, invasion and survival is compromised by depletion of survivin. These studies suggest that mutant K-Ras contributes to the maintenance of the aberrantly high levels of survivin in tumors by regulating its stability, and that the ability of mutant K-Ras to induce malignant transformation is, at least in part, dependent on these high levels of survivin.