NO and H2O2 induced by Verticillium dahliae toxins and its influence on the expression of GST gene in cotton suspension cells

Nitric oxide （NO） and hydrogen peroxide （H2O2） have been shown to be important signaling molecules that participate in the regulation of several physiological processes. In particular, they have significant role in plant resistance to pathogens by contributing to induction defense genes. Here, whether NO and H2O2 participate in the resistance responses against Verticillium dahliae toxins （VD-toxins） and their effects on the expression of GSTgene are studied. The results reveal that NO and H2O2 are produced as part of a complex network of signals that respond to VD-toxins and may converge to function both synergistically and independently by inducing resistant responses. GSTgene is potentially involved in the resistance mechanism in the cotton suspension cells. NO induces the expression of GSTgene independently of H2O2. H2O2 may be a more potent signal in the resistance responses against VD-toxins.     

P15——a new tumor suppressor gene

In addition to the tumor suppressor genes such as Rb and p53, it has been found that some molecules of the same class named CKI (cyclin-dependent kinase inhibitor) also play an important role in the inhibition of tumorigenesis and the tumor progression. In the KIP and INK4 families of CKIs, p15 shares extensive homology with p16. Findings in many tumors and their cell lines show that the inactivation of p15 (deletion, mutation, rearrangement, etc.) is very frequent, and inactive p15 is involved in the progress of some tumors. These studies provide evidence that the p15 is a new tumor suppressor gene. Furthermore, the research on the molecular mechanism of p15 in regulation of cell proliferation shows that p15 can inhibit the growth of some kinds of tumor cells, and p15 is the mediator of TGF-β-induced cell arrest. Investigations on p15 in cell differentiation suggest that increased p15 is related to the change of malignant phenotype. These results supply clues for further interpretation about the molecular mechnism of cell cycle control and cell tumorigenesis. And they may provide theoretical and experimental basis for application of p15 to clinical therapy of tumors.