Jia Liu Wolfe

Whole Genome Amplification of DNA from Laser Capture-Microdissected Tissue for High-Throughput Single Nucleotide Polymorphism and Short Tandem Repeat Genotyping

Genome-wide screening of genetic alterations between normal and cancer cells, as well as among subgroups of tumors, is important for establishing molecular mechanism and classification of cancer. Gene silencing through loss of heterozygosity is widely observed in cancer cells and detectable by analyzing allelic loss of single nucleotide polymorphism and/or short tandem repeat markers. To use minute quantities of DNA that are available through laser capture microdissection (LCM) of cancer cells, a whole genome amplification method that maintains locus and allele balance is essential. We have successfully used a ø29 polymerase-based isothermal whole genome amplification method to amplify LCM DNA using a proteinase K lysis procedure coupled with a pooling strategy. Through single nucleotide polymorphism and short tandem repeat genotype analysis we demonstrate that using pooled DNA from two or three separate amplification reactions significantly reduces any allele bias introduced during amplification. This strategy is especially effective when using small quantities of source DNA. Although a convenient alkaline lysis DNA extraction procedure provided satisfactory results from using 1500 to 3000 LCM cells, proteinase K digestion was superior for lower cell numbers. Accurate genotyping is achieved with as few as 100 cells when both proteinase K extraction and pooling are applied.

A genotyping strategy based on incorporation and cleavage of chemically modified nucleotides

Aiming to facilitate the analysis of human genetic variations in the context of disease susceptibility and varied drug response, we have developed a genotyping method that entails incorporation of a chemically labile nucleotide by PCR followed by specific chemical cleavage of the resulting amplicon at the modified bases. The identity of the cleaved fragments determines the genotype of the DNA. This method, termed Incorporation and Complete Chemical Cleavage, utilizes modified nucleotides 7-deaza-7-nitro-dATP, 7-deaza-7-nitro-dGTP, 5-hydroxy-dCTP, and 5-hydroxy-dUTP, which have increased chemical reactivity but are able to form standard Watson–Crick base pairs. Thus one analog is substituted for the corresponding nucleotide during PCR, generating amplicons that contain nucleotide analogs at each occurrence of the selected base throughout the target DNA except for the primer sequences. Subsequent treatment with an oxidant followed by an organic base results in chemical cleavage at each site of modification, which produces fragments of different lengths and/or molecular weights that reflect the genotype of the original DNA sample at the site of interest. This incorporation and cleavage chemistry are widely applicable to many existing nucleic acid analysis platforms, including gel electrophoresis and mass spectrometry. By combining DNA amplification and analog incorporation into one step, this strategy eliminates preamplification, DNA-strand separation, primer extension, and purification procedures associated with traditional chain-termination chemistry and therefore presents significant advantages in terms of speed, cost, and simplicity of genotyping.

STAT6 phosphorylation inhibitors block eotaxin-3 secretion in bronchial epithelial cells

The STAT6 (signal transducer and activator of transcription 6) protein facilitates T-helper cell 2 (Th2) mediated responses that control IgE-mediated atopic diseases such as asthma. We have identified compounds that bind to STAT6 and inhibit STAT6 tyrosine phosphorylation induced by IL-4. In the bronchial epithelial cell line BEAS-2B, compound (R)-84 inhibits the secretion of eotaxin-3, a chemokine eliciting eosinophil infiltration. (R)-84 appears to prevent STAT6 from assuming the active dimer configuration by directly binding the protein and inhibiting tyrosine phosphorylation.

Optimization of hammerhead ribozymes for the cleavage of S100A4 (CAPL) mRNA.

Previously, suppression of the S100A4 mRNA by an endogenously expressed ribozyme in osteosarcoma cells was shown to inhibit their metastasis in rats. As a prelude to performing similar studies with exogenous, synthetic ribozymes, we compared a series of hammerhead ribozymes targeted against different sites in the mRNA. The ribozymes differed only in the 7-base flanking sequences complementary to the substrate and were protected against nucleases by chemical modification. Cleavage efficiency varied widely and was not obviously related to the predicted secondary structure of the target RNA. The most active ribozyme of the series was chosen for further optimization. Lengthening its flanking sequences was counterproductive and reduced cleavage even when using excess ribozyme. Using excess substrate (multiple-turnover kinetics), cleavage was fastest with the (6+8) ribozyme having 6 nucleotides (nt) in stem III and 8 nt in stem I. Although these stems strongly influence ribozyme performance, their optimization is still empirical. Faster cleavage was obtained by adding facilitator oligonucleotides to ribozymes with shorter stems of (6+6) and (5+5) nt. Stimulation was particularly strong in the case of the (5+5) ribozyme, which was poorly active by itself. The enhancement caused by different facilitator oligonucleotides paralleled their expected ability to hybridize to RNA as a function of length and chemical modification.

Synthesis and Polymerase Incorporation of 5′‐Amino‐2′,5′‐Dideoxy‐5′‐N‐Triphosphate Nucleotides

This unit presents synthetic procedures for the preparation of 5′‐amino‐2′,5′‐dideoxy analogs of adenosine, cytidine, guanosine, and thymidine, as well as corresponding 5′‐N‐triphosphate nucleotides, using commercially available reagents. The modified nucleosides are prepared in high yields from naturally occurring 2′‐deoxynucleosides using robust chemical reactions including tosylation, azide exchange, and the Staudinger reaction. Efficient conversion of these 5′‐amino nucleosides to corresponding 5′‐N‐triphosphate nucleotides is achieved through a one‐step reaction with trimetaphosphate in Tris‐buffered aqueous solution. The 5′‐amino modification renders these nucleoside and nucleotide analogs markedly increased reactivity, which is useful for a variety of biochemical, pharmaceutical, and genomic applications. Also included in this unit are protocols for polymerase incorporation of the 5′‐amino nucleotides, either partially or completely replacing their naturally occurring counterparts, and subsequent sequence‐specific cleavage at the modified nucleotides under mildly acidic conditions.