Polyhexamethyleneguanidine phosphate induces cytotoxicity through disruption of membrane integrity.

Polyhexamethyleneguanidine phosphate (PHMG-P) is a polymeric biocide with a guanidine group. It has multiple positive charges in physiological conditions due to nitrogen atom in the guanidine and this cationic property contributes antimicrobial effect by disrupting cell membranes. To determine whether the cationic nature of PHMG-P results in cytotoxicity in human cell lines, anionic compounds were treated with PHMG-P. The cytotoxic effect was evaluated with ROS production and HMGB1 release into media. To verify the protection effect of anion against PHMG-P-induced cell death in vivo, a zebrafish assay was adopted. In addition, membrane disruption by PHMG-P was evaluated using fluorescein diacetate and propidium iodine staining. As a result, anionic substances such as DNA and poly-l-glutamic acids, decreased PHMG-P induced cell death in a dose-dependent manner. While HMGB1 and ROS production increased with PHMG-P concentration, the addition of anionic compounds with PHMG-P reduced the ROS production and HMGB1 release. The mortality of the zebrafish increased with PHMG-P concentration and co-treatment of anionic compounds with PHMG-P decreased mortality in a dose-dependent manner. In addition, FDA and PI staining confirmed that PHMG-P disrupts plasma membrane. Taken together, a cationic property is considered to be one of the main causes of PHMG-P-induced mammalian cell toxicity.

Melphalan inhibits adenoma development through modulating the expression of K-ras-specific markers in K-ras Tg mice.

In previous research, we focused on the discovery of K-ras biomarkers, and effects of genotoxic carcinogens on their expression were investigated in this study. It is well-known that mutated K-ras gene is involved in approximately 30% of human cancers such as lung cancer. To search for K-ras oncogene-induced modulators in lung tissues of K-ras transgenic mice, we analyzed K-ras-specific genes and proteins related to cancer development, signal transduction, inflammation as well as tumor suppression in a previous study. In this study, we investigated the modulating effects of genotoxic carcinogen treatment on expression of K-ras-dependent modulated genes and proteins in lung tissues of K-ras Tg mice. In order to evaluate candidate K-ras markers modulated by genotoxic stress and to investigate whether a genotoxic carcinogen would enhance or inhibit carcinogenesis in lung tissues of the K-ras Tg mice, the anti-cancer drug melphalan was intraperitoneally injected into K-ras Tg mice every two days for four weeks. RT-qPCR and proteomics analyses were performed in order to confirm whether K-ras-specific biomarkers would be modulated by melphalan treatment in K-ras Tg mice. The decreased adenomas were histopathologically observed and K-ras expression was suppressed in melphalan-treated K-ras Tg mice. Melphalan also recovered the expression of K-ras-dependent modulated biomarkers. These results suggest that melphalan inhibits carcinogenesis via modulating K-ras-specific genes and proteins expressed in the lung tissues of K-ras Tg mice.

Assessment of General and Cardiac Toxicities of Astemizole in Male Cynomolgus Monkeys: Serum Biochemistry and Action Potential Duration.

Toxicology screening following treatment with astemizole, a histamine receptor antagonist, at oral doses of 0, 10, 30 and 60 mg/kg was carried out in male cynomolgus monkeys (Macaca fascicularis). No dose-related changes in mortality, clinical signs, body weight changes, food consumption, or urine analysis occurred in any animal compared to the vehicle control. However, the high-dose group showed a decrease in BUN and ALP compared to vehicle control group. In addition, the levels of TG, AST, ALP and CK increased. Although astemizole did not produce significant toxicological changes at any dose tested, we predict that it can cause toxicological changes of the liver and heart based on the changes in the serum parameters related to the heart and liver. The Action Potential Duration (APD) was prolonged in the heart of 60 mg/kg treatment group compared to the control group. The APD increase in 60 mg/kg treatment group along the other related changes in toxicological parameters imply that astemizole has major cardiotoxic effects in the cynomolgus monkey. This study is a valuable assessment for predicting the general toxicity and cardiotoxic effects of antihistamine drugs using nonhuman primates.