Hirotomo Shibaguchi

Tumor growth inhibition by sonodynamic therapy using a novel sonosensitizer

Sonodynamic therapy (SDT) with low-intensity ultrasound combined with a sonosensitizer may be a promising approach to cancer therapy. Use of ultrasound has the advantage of being noninvasive, with deep-penetration properties, and convenient because of the low or no sensitivity of sonosensitizers to light. In this study, SDT with a novel sonosensitizer (a porphyrin derivative) was evaluated in vitro and in vivo. Ultrasound irradiation with a sonosensitizer elicited potent sonotoxicity in vitro without the danger of phototoxicity. The sonotoxic effect was mediated by reactive oxygen species (ROS) and was reduced by ROS scavengers. Cell membrane lipid peroxidation increased significantly just after ultrasound irradiation with a sonosensitizer, but there was no increase in apoptosis. In an in vivo mouse xenograft model, SDT with a sonosensitizer markedly inhibited tumor cell growth. The skin hypersensitivity after light exposure was not observed in a sonosensitizer-treatment group, consistent with the in vitro findings. These results suggest that ROS generated by SDT with a sensitizer can damage tumor cells, resulting in necrosis and prevention of tumor growth. This noninvasive treatment with no adverse effects such as skin sensitivity is therefore promising for therapy of cancers located deep within patients.

Generation, immunologic characterization and antitumor effects of human monoclonal antibodies for carcinoembryonic antigen

We generated fully human mAbs (HmAbs) to carcinoembryonic antigen (CEA) using the KM mouse, which carries a human chromosome 14 fragment containing the entire Ig H chain loci and human κ L chain segments in the mouse genome. Forty‐six hybridoma clones producing HmAbs to CEA were thus obtained by fusing the P3‐U1 mouse myeloma cells with splenocytes of the KM mice immunized with CEA. Among them, 22 clones produced HmAbs that reacted with CEA but not with 3 other CEA‐related cell adhesion molecule (CEACAM) family members, CEACAM1, CEACAM6 and CEACAM8. In 12 HmAbs examined, 8 were IgG4, 2 were IgG3, 1 was IgG2, and the other was IgG1. The affinity constants for CEA of these HmAbs were comparable to those of the previously prepared mouse anti‐CEA mAbs (MmAbs). BIAcore analyses revealed that 1 and 2 of the 22 HmAbs react with 2 epitopes defined by MmAbs on the domain N and the domain A1 or B1 of CEA, respectively. In the presence of human complement in vitro, 2 HmAbs tested showed substantial cytotoxicity, namely, 50–65%, against CEA‐expressing tumor cells. With human lymphokine‐activated killer cells in vitro, 3 HmAbs tested exhibited 40–65% Ab‐dependent cell‐mediated cytotoxicity against the tumor cells. Moreover, one of the HmAbs induced a significant inhibition of tumor growth when administered to mice xenografted with the CEA‐expressing cells. Considering their lack of immunogenicity to humans, these CEA‐specific HmAbs may be useful for immunotherapeutic approaches as well as for immunodiagnosis.

Potent and specific antitumor effect of CEA‐targeted photoimmunotherapy

Conventional photodynamic therapy (PDT) for cancer is limited by the insufficient efficacy and specificity of photosensitizers. We herein describe a highly effective and selective tumor‐targeted PDT using a near‐infrared (NIR) photosensitizer, IRDye700DX, conjugated to a human monoclonal antibody (Ab) specific for carcinoembryonic antigen (CEA). The antitumor effects of this Ab‐assisted PDT, called photoimmunotherapy (PIT), were investigated in vitro and in vivo. The Ab‐IRDye conjugate induced potent cytotoxicity against CEA‐positive tumor cells after NIR‐irradiation, whereas CEA‐negative cells were not affected at all, even in the presence of excess photoimmunoconjugate. We found an equivalent phototoxicity and a predominant plasma membrane localization of Ab‐IRDye after both one and six hours of incubation. Either no or little caspase activation and membrane peroxidation were observed in PIT‐treated cells and a panel of scavengers for reactive oxygen species showed only partial inhibition of the phototoxic effect. Strikingly, Ab‐IRDye retained significant phototoxicity even under hypoxia. We established a xenograft model, which allowed us to sensitively investigate the therapeutic efficacy of PIT by non‐invasive bioluminescence imaging. Luciferase‐expressing MKN‐45‐luc human gastric carcinoma cells were subcutaneously implanted into both flanks of nude mice. NIR‐irradiation was performed for only the tumor on one side. In vivo imaging and measurement of the tumor size revealed that a single PIT treatment, with intraperitoneal administration of Ab‐IRDye and subsequent NIR‐irradiation, caused rapid cell death and significant inhibition of tumor growth, but only on the irradiated side. Together, these data suggest that Ab‐IRDye‐mediated PIT has great potential as an anticancer therapeutics targeting CEA‐positive tumors.

Purkinje-cell degeneration in prion protein-deficient mice is associated with a cerebellum-specific Doppel protein species signature

PrPc (cellular prion protein) and Doppel are antagonizing proteins, respectively neuroprotective and neurotoxic. Evidence for Doppel neurotoxicity came from PrPc‐deficient (Prnp 0/0) mouse lines developing late onset Purkinje‐cell degeneration caused by Doppel overexpression in brain. To address the molecular underpinnings of this cell‐type specificity, we generated Doppel N‐terminal‐specific antibodies and started to examine the spatio‐temporal expression of Doppel protein species in Ngsk Prnp 0/0 brain. Although Doppel overexpression is ubiquitous, Western analyses of normal and deglycosylated protein extracts revealed cerebellar patterns distinct from the rest of the brain, supporting the idea that neurotoxicity might be linked to a particular Doppel species pattern. Furthermore, our newly raised antibodies allowed the first Doppel immunohistochemical analyses in brain, showing a distribution in Prnp 0/0 cerebellum similar to PrPc in wild type.

Strategies to endow cytotoxic T lymphocytes or natural killer cells with antibody activity against carcinoembryonic antigen.

Cytotoxic T lymphocytes (CTLs) and natural killer (NK) cells are main effecter cells in cellular immunity against tumor cells. T-cell immunotherapy is based on the assumption that tumor(-associated) antigen (TA) peptides are correctly presented by HLA class I molecules on target tumor cells, and NK cell immunotherapy is based on the hypothesis that cell surface TAs or ligands for NK receptors are widely expressed in tumor cells. However, human tumor cells often lose HLA class I molecules, and target cell ligands for NK receptors are not always expressed in human tumor cells. These altered HLA class I phenotypes and non-ubiquitous expression of NK receptor ligands constitute the major tumor escape mechanism facing tumor-specific CTL and/or NK cell mediated responses. These facts also indicate that it is not easy to eliminate the target tumors only by activating tumor-specific CTLs or NK cells with cancer vaccine treatments. On the other hand, it is easily confirmed by immunohistochemistry whether or not antibody-recognized TAs exist on the cell surface of target tumor cells. Therefore, endowing CTLs or NK cells with antigen-binding specificity of anti-TA antibody is a promising approach for re-targeting the activities of these effector cells to tumor cells in an HLA-independent manner. This review summarizes the following four new strategies for re-targeting CTLs or NK cells to carcinoembryonic-antigen-expressing tumor cells: (1) bispecific antibody technology; (2) antibody-cytokine fusion protein technology; (3) chimeric immune receptor technology, and (4) antibody-HLA/peptide complex technology.

Enhancement of the Antitumor Effect on Combination Therapy of an Anticancer Drug and Its Antibody against Carcinoembryonic Antigen

Background: Carcinoembryonic antigen (CEA) is frequently overexpressed in various types of human cancers and is associated with cell adhesion. There are three possible mechanisms of cancer therapy that employ anti-CEA antibody (Ab): Ab-dependent cell-mediated cytotoxicity (ADCC), complement-dependent cytotoxicity (CDC) or the prevention of CEA interaction with the extracellular matrix and/or intercellular adhesion molecules resulting in anoikis. In this study, the effect of C2-74, a human anti-CEA monoclonal Ab was evaluated. Methods: ADCC, CDC and anoikis assays in combination with C2-74 and an anticancer drug (5-fluorouracil or cisplatin) were investigated using tumor cell lines (MKN-45, MKN-74 and KATO III). In the anoikis assay, other human anti-CEA Abs and mouse anti-CEA-related cell adhesion molecule 6 Abs were also investigated using HLC-1 cells. Results: Additive cytotoxicity was observed when the anticancer drug and C2-74 on tumor cells were combined in the CDC assays, whereas in the anoikis assay, no such additive effect was observed. Anti-CEA-related cell adhesion molecule 6 Abs, but not anti-CEA Abs, accelerated anoikis in HLC-1 cells. Conclusion: A mechanism for the additive antitumor effect when an anticancer drug and C2-74 are combined is indicated mainly by CDC activity but is irrelevant to anoikis in tumor cells.

PPARα Ligand WY14643 Reduced Acute Rejection After Rat Lung Transplantation With The Upregulation of IL-4, IL-10 and TGFβ mRNA Expression

BACKGROUNDnThe peroxisome proliferators-activated receptor-alpha (PPARalpha) is important in lipid metabolism and regulation of inflammation. Recent studies have demonstrated the immunoregulatory effects of PPARalpha. This investigated the immunosuppressive effects of PPARalpha using its ligand, WY14643, on acute lung allograft rejection in a rat model and its mechanism of action.nnnMETHODnThe left lungs were transplanted orthotopically from Brown-Norway donors to F344 recipients. The recipients were then divided into control and WY14643 treatment groups. The allograft rejection was evaluated by daily chest X-ray imaging and was evaluated histologically on Day 7 after transplantation. The cytokine messenger RNA (mRNA) expression at Days 3 and 5 were also evaluated in allografts and recipient spleens.nnnRESULTSnThe radiologic and histologic findings indicated that treatment with the WY14643 reduced acute allograft rejection. WY14643 also significantly extended the allograft survival time. This amelioration of acute rejection by WY14643 was also associated with up-regulated interleukin (IL)-4, IL-10, and transforming growth factor-beta (TGFbeta) mRNA expression in the lung allografts and spleens.nnnCONCLUSIONnThis study demonstrated that the administration of the PPARa ligand, WY14643, ameliorates acute lung allograft rejection in rats. Treatment with WY14643 reduced histopathologic scores, prolonged graft survival, and up-regulated the expression of anti-inflammatory cytokine IL-4, IL-10, and TGFbeta mRNA compared with the control.