Capillary electrophoresis Western blot using inkjet transfer to membrane.

Traditional Western blots are commonly used to separate and assay proteins; however, they have limitations including a long, cumbersome process and large sample requirements. Here, we describe a system for Western blotting where capillary gel electrophoresis is used to separate sodium dodecyl sulfate-protein complexes. The capillary outlet is threaded into a piezoelectric inkjetting head that deposits the separated proteins in a quasi-continuous stream of <100 pL droplets onto a moving membrane.

Fast Immunoassay for Microfluidic Western Blotting by Direct Deposition of Reagents onto Capture Membrane.

Western blotting is a widely used protein assay platform, but the technique requires long analysis times and multiple manual steps. Microfluidic systems are currently being explored for increased automation and reduction of analysis times, sample volumes, and reagent consumption for western blots. Previous work has demonstrated that proteins separated by microchip electrophoresis can be captured on membranes by dragging the microchip outlet across the membrane.

Electrophoresis of megaDalton proteins inside colloidal silica.

With the growth of the biopharmaceutical industry, there is a need for rapid size-analysis of proteins on the megaDalton scale. The large pore sizes needed for such separations cannot be easily reached by pushing the current limits of size-exclusion chromatography or gel electrophoresis. The concept detailed here is the formation of arbitrarily wide pores by packing nonporous colloidal silica in capillaries.

A near-infrared, surface-enhanced, fluorophore-linked immunosorbent assay.

The enzyme-linked immunosorbent assay is commonly used for research and clinical applications but typically suffers from a limited linear range and is difficult to multiplex. The fluorophore-linked immunosorbent assay is a closely related technique with good linear range and the ability to detect multiple antigens simultaneously but is typically less sensitive. Here, we demonstrate a near-infrared, surface-enhanced fluorophore-linked immunosorbent assay with sensitivity comparable to its enzyme-linked counterpart.

Fluorescent structural DNA nanoballs functionalized with phosphate-linked nucleotide triphosphates.

Highly labeled DNA nanoballs functionalized with phosphate-linked nucleotide triphosphates (dNTPs) were developed as a source of dNTPs for DNA polymerase. The particles were prepared by strand-displacement polymerization from a self-complementary circular template. Imaged by atomic force microscopy, these functionalized particles appear as condensed fuzzy balls with diameters between 50 and 150 nm.

Correlation between scattering properties of silver particle arrays and fluorescence enhancement.

We report on the nanofabrication of patterned silver particle arrays using electron-beam lithography and the evaluation of their optical properties using backscattering and fluorescence spectroscopy. The silver particles varied in size from 100 to 250 nm and were in the shape of circles, squares, and triangles. Three inter-particle separations, 40, 65, and 90 nm as measured from the side of one particle to the side of the next particle, were used.

An artificial processivity clamp made with streptavidin facilitates oriented attachment of polymerase-DNA complexes to surfaces.

Single molecule analysis of individual enzymes can require oriented immobilization of the subject molecules on a detection surface. As part of a technology development project for single molecule DNA sequencing, we faced the multiple challenges of immobilizing both a DNA polymerase and its DNA template together in an active, stable complex capable of highly processive DNA synthesis on a nonstick surface. Here, we report the genetic modification of the archaeal DNA polymerase 9 degrees N in which two biotinylated peptide 'legs' are inserted at positions flanking the DNA-binding cleft.

Synthesis and stability of novel terminal phosphate-labeled nucleotides.

Novel compounds consisting of a nucleotide triphosphate labeled with a PEG linker and various terminal groups attached to the gamma-phosphate of the nucleotide were constructed for use in efforts to produce a new class of DNA sequencer. The stability of these novel compounds was investigated to determine their utility as sequencing reagents. Hydrolysis rate constants were measured for both the natural nucleoside triphosphate dATP and novel dATP derivatives.

Mitochondrial DNA integrity is not dependent on DNA polymerase-beta activity.

Mutations in mitochondrial DNA (mtDNA) are involved in a variety of pathologies, including cancer and neurodegenerative diseases, as well as in aging. mtDNA mutations result predominantly from damage by reactive oxygen species (ROS) that is not repaired prior to replication. Repair of ROS-damaged bases occurs mainly via base excision repair (BER) in mitochondria and nuclei.

Incorporation of reporter-labeled nucleotides by DNA polymerases.

The incorporation of fluorescently labeled nucleotides into DNA by DNA polymerases has been used extensively for tagging genes and for labeling DNA. However, we lack studies comparing polymerase efficiencies for incorporating different fluorescently labeled nucleotides. We analyzed the incorporation of fluorescent deoxynucleoside triphosphates by 10 different DNA polymerases, representing a cross-section of DNA polymerases from families A, B, and reverse transcriptase.

Viral error catastrophe by mutagenic nucleosides.

Riboviruses and retroviruses have the highest rates of mutations of any known organism. Increasing the mutation rate of these viruses could exceed the error threshold for viability of a viral population within a host. Recent experiments with mutagenic nucleoside analogs validate this new approach to treating infection of RNA viruses.

Predicting demographic group structures based on DNA sequence data.

The ability to infer relationships between groups of sequences, either by searching for their evolutionary history or by comparing their sequence similarity, can be a crucial step in hypothesis testing. Interpreting relationships of human immunodeficiency virus type 1 (HIV-1) sequences can be challenging because of their rapidly evolving genomes, but it may also lead to a better understanding of the underlying biology. Several studies have focused on the evolution of HIV-1, but there is little information to link sequence similarities and evolutionary histories of HIV-1 to the epidemiological information of the infected individual.

Multiple mutations and cancer.

Most human tumors are highly heterogenous. We have hypothesized that this heterogeneity results from a mutator phenotype. Our premise is that normal mutation rates are insufficient to account for the multiple mutations found in human cancers, and, instead, that cancers must exhibit a mutator phenotype early during their evolution.

In vitro production and screening of DNA polymerase eta mutants for catalytic diversity.

Mutant DNA polymerases have become an increasingly important tool in biotechnology. The ability to examine the activity and specific properties of enzymes has a crucial role in the characterization of the enzyme. We have developed several systems for characterizing DNA polymerases that combine random mutagenesis with in vivo selection systems.