Phototoxic aptamers selectively enter and kill epithelial cancer cells

Jen presented this paper on 4/23/09

Nucleic Acids Research, 2009, 37, 866

The majority of cancers arise from malignant epithelial cells. We report the design of synthetic oligonucleotides (aptamers) that are only internalized by epithelial cancer cells and can be precisely activated by light to kill such cells. Specifically, phototoxic DNA aptamers were selected to bind to unique short O-glycan-peptide signatures on the surface of breast, colon, lung, ovarian and pancreatic cancer cells. These surface antigens are not present on normal epithelial cells but are internalized and routed through endosomal and Golgi compartments by cancer cells, thus providing a focused mechanism for their intracellular delivery. When modified at their 5′ end with the photodynamic therapy agent chlorin e6 and delivered to epithelial cancer cells, these aptamers exhibited a remarkable enhancement (>500-fold increase) in toxicity upon light activation, compared to the drug alone and were not cytotoxic towards cell types lacking such O-glycan-peptide markers. Our findings suggest that these synthetic oligonucleotide aptamers can serve as delivery vehicles in precisely routing cytotoxic cargoes to and into epithelial cancer cells.

Identification of an aptamer targeting hnRNP A1 by tissue slide-based SELEX

Journal of Pathology, 2009

We report a new in situ tissue slide-based SELEX strategy targeting neoplastic tissues from breast cancer patients. The methodology, using the molecular differences between clinical specimens, can evolve aptamers to all fractions of tissue. The aptamers may be used as new molecular probes for pathological diagnosis and tumour imaging, and also to reveal the molecular differences that are responsible for the diseases. The specific aptamers were enriched by unequal length strand PCR employing a structured (-) strand primer. After 12 rounds of selection, using the paraffin tissue sections from infiltrating ductal carcinomas as targets, and using the adjacent normal tissue from the same case as controls, one of the enriched ssDNA aptamers, BC15, was selected from a nucleic acid library and characterized as recognizing breast cancer cells either within the tissue sections or from the culture medium, but only weakly binding to adjacent normal cells or immortalized breast cell line MCF10A. The calculated equilibrium dissociation constants (Kd) of BC15 bound to MCF7 cells was 111.0 ± 36.9 nM. Through streptavidin magnetic beads mediated affinity purification assay followed by mass spectrometry identification and western blot confirmation, the target of BC15 was characterized to be hnRNP A1, which was further verified to be specifically and highly expressed in cancerous tissues of breast by hnRNP A1 antibody immunostaining as well as western blot. BC15 aptamer was also used to probe cancer cells in tissues from other pathological types of breast cancers including lobular carcinoma, ductal carcinoma complicated with lobular carcinoma, comedo carcinoma, and lymph node metastasis of breast ductal carcinoma origin or breast lobular carcinoma origin. Therefore, tissue slide-based SELEX holds promise in identifying tumour markers and developing specific molecular probes for cancer diagnosis.

RNA Aptamer Blockade of Osteopontin Inhibits Growth and Metastasis of MDA-MB231 Breast Cancer Cells

Dalia presented this paper on 3/6/09

Molecular Therapy, 2009, 17, 153

Osteopontin (OPN) is a secreted phosphoprotein which mediates tumorigenesis, local growth, and metastasis in a variety of cancers. It is a potential therapeutic target for the regulation of cancer metastasis. RNA aptamer technology targeting OPN may represent a clinically viable therapy. In this study, we characterize the critical sequence of an RNA aptamer, termed OPN-R3, directed against human OPN. It has a Kd of 18 nmol/l and binds specifically to human OPN as determined by RNA electrophoretic mobility assays. In MDA-MB231 human breast cancer cells examined under fluorescence microscopy, OPN-R3 ablates cell surface binding of OPN to its cell surface CD44 and v3 integrin receptors. Critical enzymatic components of the OPN signal transduction pathways, PI3K, JNK1/2, Src and Akt, and mediators of extracellular matrix degradation, matrix metalloproteinase 2 (MMP2) and uroplasminogen activator (uPA), are significantly decreased following exposure to OPN-R3. OPN-R3 inhibits MDA-MB231 in vitro adhesion, migration, and invasion characteristics by 60, 50, and 65%, respectively. In an in vivo xenograft model of breast cancer, OPN-R3 significantly decreases local progression and distant metastases. On the basis of this “proof-of-concept” study, we conclude that RNA aptamer targeting of OPN has biologically relevance for modifying tumor growth and metastasis.

One-step DNA-programmed growth of luminescent and biofunctionalized nanocrystals

Nature Nanotechnology, 4, 2009, 121-125

Kang presented this article on 02/26/09

Colloidal semiconductor nanocrystals are widely used as lumiphores in biological imaging because their luminescence is both strong and stable, and because they can be biofunctionalized. During synthesis, nanocrystals are typically passivated with hydrophobic organic ligands1, so it is then necessary either to replace these ligands or encapsulate the nanocrystals with hydrophilic moieties to make the lumiphores soluble in water. Finally, biological labels must be added to allow the detection of nucleic acids, proteins and specific cell types2, 3, 4, 5, 6, 7, 8. This multistep process is time- and labour-intensive and thus out of reach of many researchers who want to use luminescent nanocrystals as customized lumiphores. Here, we show that a single designer ligand—a chimeric DNA molecule—can controllably program both the growth and the biofunctionalization of the nanocrystals. One part of the DNA sequence controls the nanocrystal passivation and serves as a ligand, while another part controls the biorecognition. The synthetic protocol reported here is straightforward and produces a homogeneous dispersion of nanocrystal lumiphores functionalized with a single biomolecular receptor. The nanocrystals exhibit strong optical emission in the visible region, minimal toxicity and have hydrodynamic diameters of 6 nm, which makes them suitable for bioimaging4. We show that the nanocrystals can specifically bind DNA, proteins or cells that have unique surface recognition markers.