Evaluation of chemical chaperones based on the monitoring of Bip promoter activity and visualization of extracellular vesicles by real-time bioluminescence imaging.

It is known that endoplasmic reticulum (ER) stress in cells and extracellular vesicles (EVs) plays a significant role in cancer cells, therefore the evaluation of compounds that can regulate ER stress and EV secretion would be a suitable system for further screening and development of new drugs. In this study, we evaluated chemical chaperones derived from natural products based on monitoring Bip/GRP78 promoter activity during cancer cell growth, at the level of the single cell, by a bioluminescence microscopy system that had several advantages compared with fluorescence imaging. It was found that several chemical chaperones, such as ferulic acid (FA), silybin, and rutin, affected the activity. We visualized EVs from cancer cells using bioluminescence imaging and showed that several EVs could be observed when using CD63 fused with NanoLuc luciferase, which has a much smaller molecular weight and higher intensity than conventional firefly luciferase. We then examined the effects of the chemical chaperones on EVs from cancer cells by bioluminescence imaging and quantified the expression of CD63 in these EVs. It was found that the chemical chaperones examined in this study affected CD63 levels in EVs. These results showed that imaging at the level of the single cell using bioluminescence is a powerful tool and could be used to evaluate chemical chaperones and EVs from cancer cells. This approach may produce new information in this field when taken together with conventional and classical methods.

Discovery of protein disulfide isomerase P5 inhibitors that reduce the secretion of MICA from cancer cells.

In order to regulate the activity of P5, which is a member of the protein disulfide isomerase family, we screened a chemical compound library for P5-specific inhibitors, and identified two candidate compounds (anacardic acid and NSC74859). Interestingly, anacardic acid inhibited the reductase activity of P5, but did not inhibit the activity of protein disulfide isomerase (PDI), thiol-disulfide oxidoreductase ERp57, or thioredoxin. NSC74859 inhibited all these enzymes. When we examined the effects of these compounds on the secretion of soluble major histocompatibility complex class-I-related gene A (MICA) from cancer cells, anacardic acid was found to decrease secretion. In addition, anacardic acid was found to reduce the concentration of glutathione up-regulated by the anticancer drug 17-demethoxygeldanamycin in cancer cells. These results suggest that anacardic acid can both inhibit P5 reductase activity and decrease the secretion of soluble MICA from cancer cells. It might be a novel and potent anticancer treatment by targeting P5 on the surface of cancer cells.

Synergetic cytotoxic activity toward breast cancer cells enhanced by the combination of Antp-TPR hybrid peptide targeting Hsp90 and Hsp70-targeted peptide.

BACKGROUND: Heat shock protein (Hsp) 90 and Hsp70 are indispensable for cell survival under conditions of stress. They bind to client proteins to assist in protein stabilization, translocation of polypeptides across the cell membrane, and recovery of proteins from aggregates in the cell. Therefore, these proteins have recently emerged as important targets in the treatment of cancer. We previously reported that the newly designed Antp-TPR hybrid peptide targeting Hsp90 induced cytotoxic activity to cancer cells both in vitro and in vivo. METHODS: To further improve the cytotoxic activity of Antp-TPR toward cancer cells, we investigated the effect of a Hsp70-targeted peptide, which was made cell-permeable by adding the polyarginine with a linker sequence, on the cytotoxic activity of Antp-TPR in breast cancer cell lines. RESULTS: It was revealed that Antp-TPR in the presence of a Hsp70-targeted peptide induced effective cytotoxic activity toward breast cancer cells through the descrease of Hsp90 client proteins such as p53, Akt, and cRaf. Moreover, the combined treatment with these peptides did not induce the up-regulation of Hsp70 protein, as determined by western blotting, a promoter assay using a luminometer, and single-cell level imaging with the LV200 system, although a small-molecule inhibitor of Hsp90, 17-allylamino-demethoxygeldanamycin (17-AAG), did induce the up-regulation of this protein. We also found that treatment with Antp-TPR, Hsp70-targeted peptide, or a combination of the two did not induce an increase in the glutathione concentrations in the cancer cells. CONCLUSION: These findings suggest that targeting both Hsp90 and Hsp70 with Antp-TPR and Hsp70-targeted peptide is an attractive approach for selective cancer cell killing that might provide potent and selective therapeutic options for the treatment of cancer.

Transfection efficiency of normal and cancer cell lines and monitoring of promoter activity by single-cell bioluminescence imaging.

The bioluminescence system (luciferase reporter assay system) is widely used to study gene expression, signal transduction and other cellular activities. Although transfection of reporter plasmid DNA to mammalian cell lines is an indispensable experimental step, the transfection efficiency of DNA varies among cell lines, and several cell lines are not suitable for this type of assay because of the low transfection efficiency. In this study, we confirm the transfection efficiency of reporter DNA to several cancer and normal cell lines after transient transfection by single-cell imaging. Luminescence images could be obtained from living single cells after transient transfection, and the calculated transfection efficiency of this method was similar to that of the conventional reporter assay using a luminometer. We attempted to measure the activity of the Bip promoter under endoplasmic reticulum stress conditions using both high and low transfection efficiency cells for plasmid DNA at the single-cell level, and observed activation of this promoter even in cells with the lowest transfection efficiency. These results show that bioluminescence imaging of single cells is a powerful tool for the analysis of gene expression based on a reporter assay using limited samples such as clinical specimens or cells from primary culture, and could provide additional information compared with the conventional assay.

Molecular mechanism of cytotoxicity induced by Hsp90-targeted Antp-TPR hybrid peptide in glioblastoma cells.

BACKGROUND: Heat-shock protein 90 (Hsp90) is vital to cell survival under conditions of stress, and binds client proteins to assist in protein stabilization, translocation of polypeptides across cell membranes, and recovery of proteins from aggregates. Therefore, Hsp90 has emerged as an important target for the treatment of cancer. We previously reported that novel Antp-TPR hybrid peptide, which can inhibit the interaction of Hsp90 with the TPR2A domain of Hop, induces selective cytotoxic activity to discriminate between normal and cancer cells both in vitro and in vivo. RESULTS: In this study, we investigated the functional cancer-cell killing mechanism of Antp-TPR hybrid peptide in glioblastoma (GB) cell lines. It was demonstrated that Antp-TPR peptide induced effective cytotoxic activity in GB cells through the loss of Hsp90 client proteins such as p53, Akt, CDK4, and cRaf. Antp-TPR also did not induce the up-regulation of Hsp70 and Hsp90 proteins, although a small-molecule inhibitor of Hsp90, 17-AAG, induced the up-regulation of these proteins. It was also found that Antp-TPR peptide increased the endoplasmic reticulum unfolded protein response, and the cytotoxic activity of this hybrid peptide to GB cells in the endoplasmic reticulum stress condition. CONCLUSION: These results show that targeting of Hsp90 by Antp-TPR could be an attractive approach to selective cancer-cell killing because no other Hsp90-targeted compounds show selective cytotoxic activity. Antp-TPR might provide potent and selective therapeutic options for the treatment of cancer.

Functional analysis of protein disulfide isomerase P5 in glioblastoma cells as a novel anticancer target.

P5, which is a member of the protein disulfide isomerase family, possesses isomerase and chaperone activity in vitro; however, the physiological functions of this enzyme in cells remain unclear. To understand the important roles of P5 in cancer cells, the present study examined its expression on the surface of normal and cancer cell lines by flow cytometry using an affinity­purified anti­P5 antibody labeled with 6­(fluorescein­5­carboxamido) hexanoic acid succinimidyl ester. P5 expression was increased on the surface of various cancer cell lines, including leukemia cells, and glioblastoma, breast, colon, ovarian and uterine cervical cancer cells, compared with normal cells. However, P5 was constantly expressed within both normal and cancer cell lysates, and its total expression levels were not significantly different between the cells. P5 knockdown in glioblastoma cells by small interfering RNA affected Bip promoter activation during cancer cell growth, and significantly inhibited cancer cell growth and migration. Immunoprecipitation using an anti­P5 antibody in cancer and normal cells demonstrated that vimentin was bound to P5, predominantly in U251 glioblastoma cells. P5 knockdown in glioblastoma cells did not affect the protein expression levels of vimentin; however, it did affect the expression of numerous epithelial­mesenchymal transition markers, including Snail and Slug. These results suggested that P5 may serve an important role in cancer cell growth, and may be considered an attractive and potent target for the treatment of glioblastoma.

A novel interleukin-13 receptor alpha 2-targeted hybrid peptide for effective glioblastoma therapy.

We previously designed and reported a novel class of drugs, namely hybrid peptides, which are chemically synthesized and composed of a targeted binding peptide and a lytic-type peptide containing cationic amino acid residues that cause cancer cell death. In the present study, we screened for peptides that bind to interleukin-13 receptor alpha 2 (IL-13Rα2) by using a T7 random peptide phage display library system and isolated several positive phage clones. The A2b11 peptide, which was one of the positive clones, was shown to bind to IL-13Rα2 protein by Biacore analysis and a binding assay using glioblastoma (GB) cell lines. This peptide was linked with a lytic peptide containing a linker sequence to form the IL-13Rα2-lytic hybrid peptide. The IL-13Rα2-lytic hybrid peptide showed cytotoxic activity against GB cell lines in vitro. The IL-13Rα2-lytic hybrid peptide also affected Akt and Erk1/2 activation following treatment with interleukin-13 and induced rapid ATP dynamics in GB cells. Anti-tumor activity of the IL-13Rα2-lytic hybrid peptide was observed in vivo after intratumoral injection in a mouse xenograft model of human GB cells. These results suggest that the IL-13Rα2-lytic hybrid peptide might be a potent therapeutic option for patients with GB.

Amino acid residues in GRK1/GRK7 responsible for interaction with S-modulin/recoverin.

GRK1 is a visual pigment kinase in rods and is essential for inactivation of light-activated rhodopsin. The GRK1 activity is inhibited by binding of the Ca(2+)-bound form of S-modulin/recoverin. We previously identified the S-modulin/recoverin site to interact with GRK1. In the present study, we identified its counterpart in GRK1. We synthesized 29 of GRK1 or GRK7 partial peptides that cover the entire sequence of GRK1/GRK7, and examined whether these peptides inhibit S-modulin/recoverin activity most probably by preoccupying the binding site for GRK1. The inhibition was the greatest with the N-terminal peptide (p1, aa 3-23 in GRK7). On mutation of each of eight amino acid residues highly conserved in the p1 region of more than 10 orthologs, the inhibition was significantly reduced in the mutation of Leu(6), Asn(12) and Tyr(15). We further examined the binding of the peptides, including mutated ones, to S-modulin/recoverin with a resonance mirror biosensor. The binding correlated well with the degree of the inhibition by a peptide. The inhibition, therefore, seemed to be due to a direct binding of the kinase peptide to the binding site of active S-modulin/recoverin. A GRK1 region close to its C-terminus also seemed to be the binding site for S-modulin/recoverin.

Protein disulfide isomerase P5-immunopositive inclusions in patients with Alzheimer's disease.

Amyloid plaques and neurofibrillary tangles (NFTs) are the major pathological characteristics of Alzheimer's disease (AD). NFTs are composed of tubular filaments and paired helical filaments containing polymerized hyperphosphorylated tau protein. Another feature of AD is excessive generation of nitric oxide (NO). Protein disulfide isomerase (PDI) is a chaperon protein located in the endoplasmic reticulum (ER). It was recently reported that NO-induced S-nitrosylation of PDI inhibits its enzymatic activity, leading to the accumulation of polyubiquitinated proteins, and activates the unfolded protein response. In addition, we previously reported the presence of PDI-immunopositive NFTs in AD. Here, we found that protein disulfide isomerase P5 (P5), which is a member of the PDI protein family, was co-localized with tau in NFTs. To our knowledge, this is the first report of P5-immunopositive inclusion in AD. Furthermore, we showed that S-nitrosylated P5 was present and the expression level of P5 was decreased in AD brains compared with that of control brains. We also demonstrated that the knock-down of PDI or P5 by siRNA could affect the viability of SH-SY5Y cells under ER stress. Previously, the observation of S-nitrosylated PDI in AD was reported. NO may inhibit P5 by inducing S-nitrosylation in the same manner as PDI, which inhibits its enzymatic activity allowing protein misfolding to occur in AD. The accumulation of misfolded proteins induces ER stress and may cause apoptosis of neuronal cells through S-nitrosylation and down-regulation of PDI and P5 in AD.