Atomic layer deposition and abrupt wetting transitions on nonwoven polypropylene and woven cotton fabrics.

Atomic layer deposition (ALD) of aluminum oxide on nonwoven polypropylene and woven cotton fabric materials can be used to transform and control fiber surface wetting properties. Infrared analysis shows that ALD can produce a uniform coating throughout the nonwoven polypropylene fiber matrix, and the amount of coating can be controlled by the number of ALD cycles. Upon coating by ALD aluminum oxide, nonwetting hydrophobic polypropylene fibers transition to either a metastable hydrophobic or a fully wetting hydrophilic state, consistent with well-known Cassie-Baxter and Wenzel models of surface wetting of roughened surfaces.

Parallel analysis of tetramerization domain mutants of the human p53 protein using PCR colonies.

A highly-parallel yeast functional assay, capable of screening approximately 100-1,000 mutants in parallel and designed to screen the activity of transcription activator proteins, was utilized to functionally characterize tetramerization domain mutants of the human p53 transcription factor and tumor suppressor protein. A library containing each of the 19 possible single amino acid substitutions (57 mutants) at three positions in the tetramerization domain of the human p53 protein, was functionally screened in Saccharomyces cerevisiae. Amino acids Leu330 and Ile332, whose side chains form a portion of a hydrophobic pocket that stabilizes the active p53 tetramer, were found to tolerate most hydrophobic amino acid substitutions while hydrophilic substitutions resulted in the inactivation of the protein.

Detecting changes in the relative expression of KRAS2 splice variants using polymerase colonies.

Because splice variants of a gene with multiple isoforms give rise to proteins with different functions, it seems plausible that changes in the expression levels of the splice variants could be a contributing factor to disease. In fact, recent examples in the literature clearly illustrate that altered expression levels of splice variants may play an important role in disease. Furthermore, these works demonstrate that changes in expression levels could potentially be used to (1) monitor disease progression, (2) diagnose disease, and/or (3) determine disease state.