Viral hepatitis, as an international public health concern, seriously affects communities and health system. In recent years, great strides have been taken for development of new potential tools against viral hepatitis. Among these efforts, a valuable strategy introduced new molecules called “aptamers”. Aptamers as potential alternatives for antibodies could be directed against any protein in infected cells and any components of viral particles. In this review, we will focus on recent advances in the diagnosis and treatment of viral hepatitis based on aptamer technology. In recent years, various types of aptamers including RNA and DNA were introduced against viral hepatitis. Some of these aptamers can be utilized for early and precise diagnosis of hepatitis infections and other group selected as therapeutic tools against viral targets. Designing diagnostic and therapeutic platforms based on aptamer technology is a promising approach in viral infections. The obtained aptamers in the recent years showed obvious potential for use as diagnostic and therapeutic tools against viral hepatitis. Although some modifications to increase the biostability and half-life of aptamers are underway, it seems these molecules will be a favorable substitute for monoclonal antibody in near future.
Integrins are adhesion molecules which play crucial roles in cell-cell and cell-extracellular matrix interactions. Very late antigen-4 or α4β1 and lymphocyte Peyer’s patch adhesion molecule-1 or α4β7, are key factors in the invasion of tumor cells and metastasis. Based on the previous reports, integrin α4 (ITGA4) is overexpressed in some immune disorders and cancers. Thus, inhibition of ITGA4 could be a therapeutic strategy. In the present study, miR-30a was selected in order to suppress ITGA4 expression. The ITGA4 3' UTR was amplified, cloned in the Z2827-M67-(ITGA4) plasmid and named as Z2827-M67/3'UTR. HeLa cells were divided into five groups; (1) untreated without any transfection, (2) mock with Z2827-M67/3'UTR transfection and X-tremeGENE reagent, (3) negative control with Z2827-M67/3'UTR transfection alone, (4) test with miR-30a mimic and Z2827-M67/3'UTR transfection and (5) scramble with miR-30a scramble and Z2827-M67/3'UTR transfection. The MTT assay was performed to evaluate cell survival and cytotoxicity in each group. Real-time RT-PCR was applied for the ITGA4 expression analysis. The findings of this study showed that miR-30a downregulated ITGA4 expression and had no effect on the cell survival. Due to the silencing effect of miR-30a on the ITGA4 gene expression, this agent could be considered as a potential tool for cancer and immune disorders therapy.
Prostate cancer usually develops to a hormone-refractory state that is irresponsive to conventional therapeutic approaches. Therefore, new methods for treating aggressive prostate cancer are under development. Because of the importance of androgen receptors (ARs) in the development of the hormone-refractory state and AR mechanism of action, this study was designed. A single-stranded DNA as an aptamer was designed that could mimic the hormone response element (HRE). The LNCaP cells as an AR-rich model were divided into three sets of triplicate groups: the test group was transfected with Aptamer Mimicking HRE (AMH), Mock received only transfection reagents (mock) and a negative control. All three sets received 0, 10 and 100 nM of dehydroepiandrosterone (DHEA) separately. Data analysis showed hormone dependency of LNCaP cells in the negative control group upon treatment with 10 and 100 nM DHEA (compared with cells left untreated (P=0.001)). Transfection of AMH resulted in significant reduction of proliferation in the test group when compared with the negative control group with 10 (P=0.001) or 100 nM DHEA (P=0.02). AMH can form a hairpin structure at 37 °C and mimic the genomic HRE. Hence, it is capable of effectively competing with genomic HRE and interrupting the androgen signaling pathway in a prostate cancer cell line (LNCaP).
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