Identification of an RNA aptamer binding hTERT-derived peptide and inhibiting telomerase activity in MCF7 cells.

Human telomerase reverse transcriptase is an essential rate-limiting component of telomerase complex. hTERT protein in association with other proteins and the human telomerase RNA (hTR) shows telomerase activity, essential for maintaining genomic integrity in proliferating cells. hTERT binds hTR through a decapeptide located in the RID2 (RNA interactive domain 2) domain of N-terminal region. Since hTERT is essential for telomerase activity, inhibitors of hTERT are of great interest as potential anti-cancer agent. We have selected RNA aptamers against a synthetic peptide from the RID2 domain of hTERT by employing in vitro selection protocol (SELEX). The selected RNAs could bind the free peptide, as CD spectra suggested conformational change in aptamer upon RID2 binding. Extracts of cultured breast cancer cells (MCF7) expressing this aptamer showed lower telomerase activity as estimated by TRAP assay. hTERT-binding RNA aptamers hold promise as probable anti-cancer therapeutic agent.

Non-coding RNAs: biological functions and applications.

Analyses of the international human genome sequencing results in 2004 converged to a consensual number of ~20,000 protein-coding genes, spanning over <2% of the total genomic sequence. Therefore, the developmental and physiological complexity of human beings remains unaccounted if viewed only in terms of the number of protein-coding genes; the epigenetic influences involving chromatin remodelling and RNA interference and alternative precursor messenger RNA splicing of functional protein-coding transcripts as well as post-translational modifications of proteins increase the diversity and the functionality of the proteome and likely explain the increased complexity. In addition, there has been an explosion of research addressing possible functional roles for the other 98% of the human genome that does not encode proteins. In fact, >90% of the human genome is likely to be transcribed yielding a complex network of overlapping transcripts that include tens of thousands of long RNAs with little or no protein forming capacity; they are collectively called non-coding RNA. This review highlights the fundamental concepts of biological roles of non-coding RNA and their importance in regulation of cellular physiology under disease conditions like cancer.

Nucleic acid aptamers: research tools in disease diagnostics and therapeutics.

Aptamers are short sequences of nucleic acid (DNA or RNA) or peptide molecules which adopt a conformation and bind cognate ligands with high affinity and specificity in a manner akin to antibody-antigen interactions. It has been globally acknowledged that aptamers promise a plethora of diagnostic and therapeutic applications. Although use of nucleic acid aptamers as targeted therapeutics or mediators of targeted drug delivery is a relatively new avenue of research, one aptamer-based drug "Macugen" is FDA approved and a series of aptamer-based drugs are in clinical pipelines. The present review discusses the aspects of design, unique properties, applications, and development of different aptamers to aid in cancer diagnosis, prevention, and/or treatment under defined conditions.

Global expression profile of telomerase-associated genes in HeLa cells.

Telomerase is a specialized nucleoprotein enzyme complex that maintains the telomere length. The telomerase reverse transcriptase (TERT) is the catalytically active component of the telomerase complex. In humans, the protein component (hTERT) and RNA component (hTR) are found to differentially express in cancer cells. In contrast to differentiated cells, most of the cancer cells overexpress hTERT, which is needed to maintain the proliferative potential of cells. The overexpression of telomerase is not proportionate to telomere length in cancer cells, suggesting that the immortalizing phenotype can be mediated through other factors in addition to telomere length. To investigate the role of hTERT in immortalizing process, loss of gene function studies were carried out. Short interfering RNA (siRNA) and short hairpin RNA (shRNA) against hTERT showed the reduction of hTERT transcript, reduction of telomerase activity and alteration of gene expression in HeLa cells. The molecular basis of proliferative capacity of hTERT was investigated by gene expression microarray. Analysis of microarray data for HeLa cells following siRNA and shRNA mediated knockdown of hTERT showed that 80 genes were upregulated and 73 genes downregulated. Out of these, 37 genes are known to be involved in cancer. Further analyses of previously known genes involved in cancer like KLF4, FGF2, IRF-9 and PLAU by Real Time PCR showed their upregulation. We are documenting for the first time the effect of knocking down hTERT on expression of KLF4 and FGF2. Interestingly, it has been earlier reported that KLF4 and FGF2 up-regulate the expression of hTERT in cancer cells. This suggests that hTERT may be subject to its own auto-regulatory effects.