Self-Assembling Derivative of Hydrocortisone as Glucocorticoid Receptor-Targeted Nanotherapeutics for Synergistic, Combination Therapy against Colorectal Tumor.

Hydrocortisone, a natural glucocorticoid secreted by adrenal and extra-adrenal tissues, locally governs the transcription of genes involved in inflammation, immune response, metabolism, and energy homeostasis via binding to its cognate glucocorticoid receptor (GR). In this study, we show that modified hydrocortisone (HC16), a cancer-selective cytotoxic molecule, showed synergism in combination with drugs like Doxorubicin and docetaxel, self-assembled into vesicles, entrapped docetaxel and complexed with anti-cancer plasmid DNA for enhanced killing of cancer cells. These vesicles exhibited GR-mediated nuclear localization, delivery of the p53 gene, and also inhibited cell viability selectively in RKO, HCT15, and CT26 colon cancer cells but not in normal cells like CHO and HEK293T. Apart from exerting its own anti-cancer activity, the self-assembled HC16 vesicles loaded with docetaxel sensitized the cancer cells to its drug cargo by downregulating the drug metabolizing CYP3A4 gene. This indirectly reduces the risk of nonspecific adverse effects in normal cells, as the viability of sensitized cancer cells could be significantly reduced even in low doses of cytotoxic docetaxel. The near infrared (NIR)-dye-associated self-assemblies accumulated in a colon tumor with higher orders of NIR intensity compared to those in a colon of healthy mice. Thereafter, the treatment of HC16-docetaxel-p53 vesicle/DNA complex led to significant tumor regression, which resulted in a cecum/body weight ratio in tumor-bearing mice similar to that of healthy mice measured at 24 h postcompletion of treatment. There was an up to 2.5-fold enhancement in the overall survivability of colon-tumor-bearing mice treated with HC16-docetaxel-p53 vesicle/DNA complexes when compared against the pristine docetaxel-treated groups. Further, the HC16-docetaxel-p53 vesicle/DNA complex-treated group showed reduced nuclear accumulation of cell proliferation marker Ki67, reduced protein levels of prosurvival and mesenchymal proteins like Bcl-2, PARP, vimentin, and N-cadherin, and increased the levels of pro-apoptotic activated caspases as compared to the pristine docetaxel-treated groups. The therapeutic package described herein is expected to find future use as a rational, multifaceted, GR-targeted approach for inhibiting colon tumor progression.

Nanomaterial designing strategies related to cell lysosome and their biomedical applications: A review.

Lysosomes, an important organelle of eukaryotic cells, are covered with the cell membrane and contain an array of degradative enzymes. The disrupt in lysosomal functions may lead to the development of severe diseases. In nanotechnology, nanomaterials working mechanism and its biomedical output are highly dependent on the lysosomes as it plays a crucial role in intracellular transport. Several nanomaterials specifically designed for lysosome-related actions are highly advantageous in trafficking and delivering the loaded imaging/therapeutic agents. But for other applications, especially gene-based therapeutic delivery into the sub-organelles such as mitochondria and nucleus, lysosomal related degradation could be an obstacle to achieve a maximal therapeutic index. In order to understand the relationship between lysosomes and designed nanomaterials for kind of desired application in biomedical research, complete knowledge of their various designing strategies, size dependent or ligand supportive cellular uptake mechanisms, trafficking, and localizations in eukaryotic cells is highly desired. In this review, we intended to discuss various nanomaterial types that have been applied in biomedical applications based on lysosomal internalization and escape from endo/lysosomes and explored their related advantages/disadvantages. Additionally, we also deliberated nanomaterials direct translocation mechanism, their autophagic accumulation and the underlying mechanism to induced autophagy. Finally, some challenges and critical issues in current research from clinical application perspective has also been addressed. Great understanding of these factors will help in understanding and facilitating the development of safe and effective lysosomal related nanomaterial-based imaging/therapeutic systems for future applications.

A Fluorescent Probe for Stimulated Emission Depletion Super-Resolution Imaging of Vicinal-Dithiol-Proteins on Mitochondrial Membrane.

Realizing the significant roles of vicinal-dithiol proteins (VDPs) in maintaining the cellular redox homeostasis and their implication in many diseases, we synthesized a smart arsenate based fluorescent probe 1 which can preferentially target the mitochondrial membrane-bound vicinal dithiol proteins (VDPs), especially voltage-dependent anion channel (VDAC2). The probe targetability was demonstrated by in vitro studies such as colocalization, stimulated emission depletion (STED) super-resolution imaging, proteomic MS/MS analysis, and Western blot analysis. The probe represents a rare example of fluorescence labeling of mitochondrial membrane-bound VDPs and can provide a new way to construct VDPs-specific fluorescent probes to gain deeper understanding of their roles in mitochondrial-related disorders.

Cationic lipid-conjugated hydrocortisone as selective antitumor agent.

Hydrocortisone, the endogenously expressed steroidal, hormonal ligand for glucocorticoid receptor (GR), is body's natural anti-inflammatory and xenobiotic metabolizing agent. It has both palliative as well as adverse effects in different cancer patients. Herein, we show that conjugation product of C16-carbon chain-associated cationic lipid and hydrocortisone (namely, HYC16) induces selective toxicity in cancer (e.g. melanoma, breast cancer and lung adenocarcinoma) cells with least toxicity in normal cells, through induction of apoptosis and cell cycle arrest at G2/M phase. Further, significant tumor growth inhibition was observed in syngeneic melanoma tumor model with considerable induction of apoptosis in tumor-associated cells. In contrast to hydrocortisone, significantly higher anti-angiogenic behavior of HYC16 helped in effective tumor shrinkage. This is the first demonstration to convert natural hormone hydrocortisone into a selective bioactive entity possessing anti-tumor effect.

Bis-arylidene oxindoles as anti-breast-cancer agents acting via the estrogen receptor.

We report a new family of bis-arylidene oxindole derivatives that show highly selective estrogen receptor (ER)-mediated anticancer activity at low-nanomolar concentrations in ER-positive (ER+) breast cancer cells. In terms of cell growth inhibition, IC50 values for these compounds in ER+ breast cancer cells are two to three orders of magnitude lower than in ER-negative (ER-) breast cancer cells and non-cancer cells. In comparison with known bis-arylidene drugs, these compounds are at least three orders of magnitude more toxic than tamoxifen and 1.5-4-fold more toxic than 4-hydroxytamoxifen in ER+ MCF-7 cancer cells. These oxindoles inhibit ER transactivation, and their anticancer activities are inhibited in ER-depleted MCF-7 cells. Some of these nonsteroidal molecules also exhibit essential properties of selective ER down-regulation. From the development of two series of bis-arylidene oxindole-based compounds, we report a new series of anticancer agents for estrogen-responsive breast cancer.

Hsp90-targeted miRNA-liposomal formulation for systemic antitumor effect.

Chaperone protein Hsp90 maintains functional integrity and maturation of a large number of cellular proteins including transcription factors, kinases, etc. It is often over-expressed in cancer cells for simultaneous maintenance of many non-regulated and/or genetically mutated proteins. Small molecule-based regimens inhibiting over-expressing Hsp90 in cancer cells often plagued with improper targeting leading to non-specific toxicity. Recently using a glucocorticoid receptor (GR)-targeted cationic lipoplex, we observed cancer cell-specific GR-transactivation and transgene expression by utilizing an unprecedentedly compromised chaperone-activity of cancer cell-associated Hsp90. In normal cells, GR is expressed ubiquitously and is highly regulated and chaperoned by Hsp90. This does not allow cancer cell-alike GR-mediated transgene expression. As a novel anticancer strategy, we showed that compromising Hsp90 in cancer cells can be utilized to selectively deplete its own level by delivering a specially designed artificial miRNA-plasmid against Hsp90 (amiR-Hsp90). Practically, GR-mediated delivery of amiR-Hsp90 plasmid in tumor-bearing mice, depleted Hsp90, critically down-regulated levels of Akt, VEGFR2 and other Hsp90-client proteins but up-regulated wild-type p53 in tumor. These enforced apoptosis in angiogenic vessels and in tumor mass and significantly shrunk tumor-volume. The present study describes gene therapy strategy against Hsp90 using a new GR-targeted liposome-amiR-Hsp90 lipoplex formulation for treating cancer.