Aptamer-guided gene targeting in yeast and human cells.

Gene targeting is a genetic technique to modify an endogenous DNA sequence in its genomic location via homologous recombination (HR) and is useful both for functional analysis and gene therapy applications. HR is inefficient in most organisms and cell types, including mammalian cells, often limiting the effectiveness of gene targeting. Therefore, increasing HR efficiency remains a major challenge to DNA editing. Here, we present a new concept for gene correction based on the development of DNA aptamers capable of binding to a site-specific DNA binding protein to facilitate the exchange of homologous genetic information between a donor molecule and the desired target locus (aptamer-guided gene targeting). We selected DNA aptamers to the I-SceI endonuclease. Bifunctional oligonucleotides containing an I-SceI aptamer sequence were designed as part of a longer single-stranded DNA molecule that contained a region with homology to repair an I-SceI generated double-strand break and correct a disrupted gene. The I-SceI aptamer-containing oligonucleotides stimulated gene targeting up to 32-fold in yeast Saccharomyces cerevisiae and up to 16-fold in human cells. This work provides a novel concept and research direction to increase gene targeting efficiency and lays the groundwork for future studies using aptamers for gene targeting.

Real-Time PCR-Coupled CE-SELEX for DNA Aptamer Selection.

Aptamers are short nucleic acid or peptide sequences capable of binding to a target molecule with high specificity and affinity. Also known as "artificial antibodies," aptamers provide many advantages over antibodies. One of the major hurdles to aptamer isolation is the initial time and effort needed for selection. The systematic evolution of ligands by exponential enrichment (SELEX) is the traditional procedure for generating aptamers, but this process is lengthy and requires a large quantity of target and starting aptamer library. A relatively new procedure for generating aptamers using capillary electrophoresis (CE), known as CE-SELEX, is faster and more efficient than SELEX but requires laser-induced fluorescence (LIF) to detect the aptamer-target complexes. Here, we implemented an alternative system without LIF using real-time- (RT-) PCR to indirectly measure aptamer-target complexes. In three rounds of selection, as opposed to ten or more rounds common in SELEX protocols, a specific aptamer for bovine serum albumin (BSA) was obtained. The specificity of the aptamer to BSA was confirmed by electrophoretic mobility shift assays (EMSAs), an unlabeled competitor assay, and by a supershift assay. The system used here provides a cost effective and a highly efficient means of generating aptamers.

Abundance of a distinct cluster of telomere t-stumps in advanced breast cancer cell line.

Breast tumors are the second major cause of cancer-related death in women worldwide. These tumors are aggressive, leading to metastatic cancers that are heterogeneous in nature, with numerous subtypes. The basal-like tumor subtype invariably shows unfavorable prognosis and is often characterized by the lack of estrogen, progesterone and HER2 receptors. These cancer types do not respond to the current targeted therapies. Therefore, the need for the discovery of novel diagnostic markers/therapeutic targets is of paramount importance. Immortalization of breast tumor cells leading to advanced stage cancer is one of the pivotal steps in breast cancer and telomeres/telomerase play a critical role in this process. Using single telomere length analysis, cell lines with a basal-like phenotype encompassing immortalized/non-tumorigenic MCF10A and invasive/metastatic MCF10CA1 along with the MCF-7 cell line were examined for the presence of a unique class of telomere t-stumps. Telomerase activity, protein levels of telomerase and bulk telomere lengths were assessed in the above-mentioned cell lines. This is the first study describing the existence of a distinct class of extremely short telomeres termed 't-stumps' in breast cancer cell lines. The cell lines MCF10A and MCF10CA1 showed distinct telomeric bands in the molecular size range of 100-1,000 bp, whereas the MCF-7 cell line showed very low levels of t-stumps. Of note is that only the highly invasive/metastatic cancer cell line MCF10CA1 exhibited an abundance of a cluster of t-stumps with a size distribution range of 500-700 bp. These unique t-stumps observed in the advanced breast cancer cell line may serve as a novel diagnostic marker and also form a key molecular target for novel anticancer therapy.

Characterization of hepatitis B virus inhibition by novel 2'-fluoro-2',3'-unsaturated beta-D- and L-nucleosides.

The clinical emergence of lamivudine and adefovir resistance mutations on prolonged therapy further necessitates the development of additional drugs for the treatment of hepatitis B virus (HBV) infections. We have evaluated a number of novel 2'-fluoro-2',3'-unsaturated D- and L-nucleosides for their anti-HBV activity in the HepG2-2.2.15 cell system. The most potent nucleosides were beta-L-2'-fluoro-2',3'-dideoxy-2',3'-didehydrocy-tidine (L-2'-Fd4C) and beta-L-2'-fluoro-2',3'-dideoxy-2',3'-didehydro-5-fluorocytidine (L-2'-Fd4FC) with median effective concentrations (EC50) of 0.002 microM and 0.004 microM, respectively. The D-enantiomers of the 2'-fluoro-substituted cytidine analogues in this series showed activity, with the 5-fluorocytidine (D-2'-Fd4FC) being the most potent (EC50 = 0.05 microM). The active compounds were not cytotoxic to a number of cell lines or to bone marrow progenitor cells. Furthermore, mitochondrial DNA synthesis and function were not affected by these nucleosides. L-2'-Fd4C did not affect viral transcription, implying that it does not inhibit cellular RNA polymerase II. Studies with the HBV polymerase in core particles revealed that the 5'-triphosphates of L-2'-Fd4C and D-2'-Fd4FC produced a dose-dependent inhibition of the incorporation of 32P-dCTP into the HBV DNA, indicating that the mechanism of action of these compounds is through specific inhibition of viral DNA synthesis. This class of nucleosides, which exhibit potent antiviral activity and a favourable safety profile, have potential for the treatment of HBV infections and warrant further development.

Emergence of a novel mutation in the FLLA region of hepatitis B virus during lamivudine therapy.

The emergence of resistance to lamivudine has been one of the major stumbling blocks to successful treatment and control of hepatitis B virus (HBV) infections. The major mechanism of resistance has been attributed to the alteration in the YMDD motif of the HBV polymerase due to an amino acid change of rtM204 to V/I and an accompanying rtL180M conversion. A novel mutation pattern in a patient having clinical breakthrough under lamivudine therapy was discovered. The mutant had a rtL180C/M204I genotype and was detected after 2 years of therapy with lamivudine. To characterize this novel variant, site-directed mutagenesis was performed using a vector construct containing the HBV genome. Transient transfection studies in human hepatoma cells with HBV carrying the new mutant demonstrated that the rtL180C/M204I mutant was resistant to lamivudine up to 10 microM. The resistance profile was comparable to that of the previously reported rtL180 M/M204I-containing virus. These observations were further confirmed by generation of stable cultures transfected with the mutant virus.