Measurement of cetuximab and panitumumab-unbound serum EGFR extracellular domain using an assay based on slow off-rate modified aptamer (SOMAmer) reagents.

BACKGROUND: Response to cetuximab (Erbitux®) and panitumumab (Vectibix®) varies among individuals, and even those who show response ultimately gain drug resistance. One possible etiologic factor is differential interaction between the drug and target. We describe the development of an assay based on Slow Off-rate Modified Aptamer (SOMAmer(™)) reagents that can distinguish drug-bound from unbound epidermal growth factor receptor (EGFR). METHODS: This quantitative assay uses a SOMAmer reagent specific for EGFR extracellular domain (ECD) as a capturing reagent. Captured SOMAmer is quantitated using PCR. Linearity and accuracy (recovery) of the assay were assessed using normal sera and purified EGFR ECD. RESULTS: This EGFR ECD assay showed linearity between 2.5 and 600 ng/mL. Average recovery was 101%. The assay detected EGFR but showed little cross-reactivity to other ErbB proteins: 0.4% for ErbB2, 6.9% for ErbB3, and 1.3% for ErbB4. Preincubation of normal serum with either cetuximab or panitumumab resulted in a dose-dependent decrease in EGFR ECD levels measured using the SOMAmer assay; preincubation did not affect measurement with an ELISA. CONCLUSIONS: This SOMAmer-based serum EGFR ECD assay accurately and specifically measures EGFR in serum. Detection of significant amounts of drug-unbound EGFR in patients undergoing cetuximab or panitumumab treatment could be an indicator of poor drug response. Further studies are needed to evaluate the utility of the assay as an indicator of drug efficacy or as a guide to dosing.

From SOMAmer-based biomarker discovery to diagnostic and clinical applications: a SOMAmer-based, streamlined multiplex proteomic assay.

Recently, we reported a SOMAmer-based, highly multiplexed assay for the purpose of biomarker identification. To enable seamless transition from highly multiplexed biomarker discovery assays to a format suitable and convenient for diagnostic and life-science applications, we developed a streamlined, plate-based version of the assay. The plate-based version of the assay is robust, sensitive (sub-picomolar), rapid, can be highly multiplexed (upwards of 60 analytes), and fully automated. We demonstrate that quantification by microarray-based hybridization, Luminex bead-based methods, and qPCR are each compatible with our platform, further expanding the breadth of proteomic applications for a wide user community.

Expanding the chemistry of DNA for in vitro selection.

Six new 5-position modified dUTP derivatives connected by a unique amide linkage were synthesized and tested for compatibility with the enzymatic steps of in vitro selection. Six commercially available DNA polymerases were tested for their ability to efficiently incorporate each of these dUTP derivatives during PCR. It was not possible to perform PCR under standard conditions using any of the modified dUTP derivatives studied. In contrast, primer extension reactions of random templates, as well as defined sequence templates, were successful. KOD XL and D. Vent DNA polymerases were found to be the most efficient at synthesizing full-length primer extension product, with all of the dUTP derivatives tested giving yields similar to those obtained with TTP. Several of these modified dUTPs were then used in an in vitro selection experiment comparing the use of modified dUTP derivatives with TTP for selecting aptamers to a protein target (necrosis factor receptor superfamily member 9, TNFRSF9) that had previously been found to be refractory to in vitro selection using DNA. Remarkably, selections employing modified DNA libraries resulted in the first successful isolation of DNA aptamers able to bind TNFRSF9 with high affinity.

Charge-transfer excited state dynamics in DNA hairpins substituted with an ethylenylpyrenyl-dU electron source and halo-dU traps.

In this work nine DNA hairpins (HPs) are studied at room temperature to observe their pyrene(*+)/dU(*-) CT excited-state dynamics following photoexcitation at 355 nm with a 25 ps laser pulse. The HPs are 18-24 bases long, have a central tetra-T loop, and have a single U(PE) (5-(2-pyren-1-yl-ethylenyl)-2'-deoxyuridine) substitution in the central region of their stems. Three of the HPs are also substituted with 5-XdU traps, where X = Br or F, to learn about the effects of these traps on CT excited-state lifetimes and emission quantum yields in U(PE) substituted HPs. The combination of lengthened average CT lifetime and enhanced CT emission quantum yield in HPs with excess electron traps compared to HPs lacking traps strongly suggests that excess electrons are injected into the DNA stem at pyrimidine sites external to U(PE) as well via charge separation within U(PE) itself. Furthermore, the increased CT emission quantum yield in HPs with traps compared to HPs without traps implies that externally injected electrons can migrate to uracil in U(PE) (i.e., Py(*+)dU) and thus indirectly form the emissive Py(*+)dU(*-) CT state of U(PE).

T7 RNA polymerase transcription with 5-position modified UTP derivatives.

Seven UTP derivatives modified at the 5-position through an amide linkage were tested as substrates for T7 RNA polymerase (T7 RNAP) transcription. All UTP derivatives gave good yields of full-length transcript even from DNA templates that showed a significant number of abortive transcripts using unmodified UTP. A kinetic assay to determine the relative K(m) and V(max) for T7 RNAP transcription gave surprisingly similar values for UTP and the 5-position hydrophobic modifications phenyl, 4-pyridyl, 2-pyridyl, indolyl, and isobutyl. The 5-position modifications imidazole and amino, which could both be positively charged, gave K(m) values significantly higher than UTP. All seven UTP derivatives gave relative V(max) values similar to UTP, indicating that insertion of these modified bases into the transcript did not impede its elongation.