Ericoid mycorrhizas are associated with a number of host plants in the Ericaceae in high-elevation regions of Taiwan. The ability of these microorganisms to thrive in harsh environmental conditions in the regions implies their capability of decomposing plant organic matter (raw humus). The objective of this study was to investigate the decomposition characteristics of three ericoid mycorrhizal endophytes isolated from the roots of Formosan rhododendron (Rhododendron formosanum Hemsl.). Molecular analysis indicated that strains Rf9 and Rf32 belong to the genus Cryptosporiopsis while strain Rf28 is a member of the genus Phialocephala. Mycorrhizal synthesis experiment showed that the roots of synthesized seedlings produced hyphal coils, a characteristic of ericoid mycorrhiza. Decomposition ability analysis revealed that strains Rf28 and Rf32 had the highest rates of decomposition of organic matter (up to 10.4% after 70 days) while the value for strain Rf9 was about 6.8%. Consistently, these strains secreted extracellular oxidases when cultured on tannic acid medium. Enzyme assay revealed that strains Rf28 and Rf32 secreted peroxidase, laccase, tyrosinase, and cellulase, but strain Rf9 secreted mainly peroxidase and tyrosinase. Apparently, the differences in secreted hydrolytic enzymes among the three endophytes are related to their ability to decompose organic matter. In the mycorrhizal synthesis experiment, all inoculated seedlings survived in the organic matter substrate for 70 days and exhibited a stronger vigor than the control. This study demonstrated that these three isolated endophytes, Rf9, Rf28, and Rf32, are ericoid mycorrhizal fungi, capable of forming ericoid mycorrhiza with Formosan rhododendron. Meanwhile, all three endophytes can secrete hydrolytic enzymes to decompose organic matter for growth, presumably a prerequisite for the adaptation of Formosan rhododendron to the harsh environments of high elevation.
Bladder cancer is highly recurrent after therapy, which has an enormous impact on the health and financial condition of the patient. It is worth developing diagnostic tools for bladder cancer. In our previous study, we found that the bladder carcinogen BBN increased urothelial global DNA CpG methylation and decreased GSTM1 protein expression in mice. Here, the correlation of BBN-decreased GSTM1 and GSTM gene CpG methylation status was analyzed in mice bladders. BBN treatment decreased the protein and mRNA expression of GSTM1, and the CpG methylation ratio of GSTM1 gene promoter was slightly increased in mice bladders. Unlike mouse GSTM1, the human GSTM1 gene tends to be deleted in bladder cancers. Among 7 human bladder cancer cell lines, GSTM1 gene is really null in 6 cell lines except one, T24 cells. The CpG methylation level of GSTM1 was 9.9% and 5-aza-dC did not significantly increase GSTM1 protein and mRNA expression in T24 cells; however, the GSTM5 gene was CpG hypermethylated (65.4%) and 5-aza-dC also did not affect the methylation ratio and mRNA expression. However, in other cell lines without GSTM1, 5-aza-dC increased GSTM5 expression and decreased its CpG DNA methylation ratio from 84.6% to 61.5% in 5637, and from 97.4% to 75% in J82 cells. In summary, two biomarkers of bladder tumor were provided. One is the GSTM1 gene which is down-regulated in mice bladder carcinogenesis and is usually deleted in human urothelial carcinoma, while the other is the GSTM5 gene, which is inactivated by DNA CpG methylation.
Due to the rising abuse of ketamine usage in recent years, ketamine-induced urinary tract syndrome has received increasing attention. The present study aimed to investigate the molecular mechanism underlying ketamine-associated cystitis in a mouse model. Female C57BL/6 mice were randomly divided into two groups: One group was treated with ketamine (100 mg/kg/day of ketamine for 20 weeks), whereas, the control group was treated with saline solution. In each group, micturition frequency and urine volume were examined to assess urinary voiding functions. Mouse bladders were extracted and samples were examined for pathological and morphological alterations using hematoxylin and eosin staining, Masson's trichrome staining and scanning electron microscopy. A cDNA microarray was conducted to investigate the differentially expressed genes following treatment with ketamine. The results suggested that bladder hyperactivity increased in the mice treated with ketamine. Furthermore, treatment with ketamine resulted in a smooth apical epithelial surface, subepithelial vascular congestion and lymphoplasmacytic aggregation. Microarray analysis identified a number of genes involved in extracellular matrix accumulation, which is associated with connective tissue fibrosis progression, and in calcium signaling regulation, that was associated with urinary bladder smooth muscle contraction. Collectively, the present results suggested that these differentially expressed genes may serve critical roles in ketamine-induced alterations of micturition patterns and urothelial pathogenesis. Furthermore, the present findings may provide a theoretical basis for the development of effective therapies to treat ketamine-induced urinary tract syndrome.
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