Analysis of DNA strand cleavage at abasic sites.

Abasic sites in DNA arise under a variety of circumstances, including destabilization of bases through oxidative stress, as an intermediate in base excision repair, and through spontaneous loss. Their persistence can yield a blockade to RNA transcription and DNA synthesis and can be a source of mutations. Organisms have developed an enzymatic means of repairing abasic sites in DNA that generally involves a DNA repair pathway that is initiated by a repair protein creating a phosphodiester break ("nick") adjacent to the site of base loss.

Making flow happen: the effects of being recovered on work-related flow between and within days.

This article examines variations of work-related flow both between and within days. On the basis of the effort-recovery model (Meijman & Mulder, 1998), we hypothesized that a person's relative day-specific state of being recovered (i.e.

Thermodynamic model for uranium release from hanford site tank residual waste.

A thermodynamic model of U solid-phase solubility and paragenesis was developed for Hanford Site tank residual waste that will remain in place after tank closure. The model was developed using a combination of waste composition data, waste leach test data, and thermodynamic modeling of the leach test data. The testing and analyses were conducted using actual Hanford Site tank residual waste.

Ribosomal protein S3: A multi-functional protein that interacts with both p53 and MDM2 through its KH domain.

The p53 protein responds to cellular stress and regulates genes involved in cell cycle, apoptosis, and DNA repair. Under normal conditions, p53 levels are kept low through MDM2-mediated ubiquitination and proteosomal degradation. In search for novel proteins that participate in this regulatory loop, we performed an MDM2 peptide pull-down assay and mass spectrometry to screen for potential interacting partners of MDM2.

DNA repair efficiency in transgenic mice over expressing ribosomal protein S3.

Human ribosomal protein S3 (RPS3) has previously been shown to have alternative roles beyond its participation in protein synthesis. For example, our in vitro studies have shown that RPS3 has an extraordinarily high binding affinity for 7,8-dihydro-8-oxoguanine (8-oxoG). Notably, in cells exposed to oxidative stress RPS3 translocates to the nucleus where it co-localizes with foci of 8-oxoG.