Ellagic acid normalizes mitochondrial outer membrane permeabilization and attenuates inflammation-mediated cell proliferation in experimental liver cancer.

Despite great advances in our understanding of the molecular causes of liver cancer, significant gaps still remain in our knowledge of the disease pathogenesis and development of effective strategies for early diagnosis and treatment. The present study was conducted to evaluate the chemopreventive activity of ellagic acid (EA) against experimental liver cancer in rats. This is the first report that implies a possible role of EA in controlling liver cancer through activation of mitochondrial outer membrane permeability via activating proteins such as Bax, bcl-2, cyt-C, and caspase-9, which play important roles in apoptosis. Downregulation of NF-κB, cyclin D1, cyclin E1, matrix metalloproteinases (MMP)-2, MMP-9, and proliferating cell nuclear antigen (PCNA) were noted in EA-treated experimental rats and controlled inflammation mediated liver cancer when compared to the diethylnitrosamine (DEN)-induced group. Transmission electron microscopy (TEM) analysis of the livers of experimental rats demonstrated that EA treatment renovated its internal architecture. Overall, these results demonstrate the value of molecular approaches in identifying the potential role of EA as an effective chemopreventive agent.

BrRZFP1 a Brassica rapa C3HC4-type RING zinc finger protein involved in cold, salt and dehydration stress.

C3HC4-type RING zinc finger proteins are known to be essential in the regulation of plant processes, including responses to abiotic stress. Here, we identify, clone and examine the first C3HC4-type RING zinc finger protein (BrRZFP1) from Brassica rapa under stress conditions. Phylogenetic analysis of BrRZFP1 revealed strong sequence similarity to C3HC4-type zinc finger proteins from Arabidopsis that are induced by abiotic stresses. Diverse environmental stresses, including salt and cold, were found to induce BrRZFP1 transcripts greater than eightfold in B. rapa. Additional strong induction was shown of the stress hormone abscisic acid, together suggesting that BrRZFP1 could play a role as a general stress modulator. Similar profiles of induction for each of these stresses was found in both root and shoot tissues, although at much higher levels in roots. Constitutive expression of BrRZFP1 in Nicotiana tabacum was conducted to further analyse how changes in gene expression levels would affect plant stress responses. BrRZFP1 overexpression conferred increased tolerance to cold, salt and dehydration stresses. This was observed in several assays examining growth status throughout development, including increased germination, fresh weight and length of shoots and roots, as well as enhanced chlorophyll retention. These results suggest that the transcription factor BrRZFP1 is an important determinant of stress response in plants and that changes in its expression level in plants could increase stress tolerance.

Identification of S-genotypes by PCR-RFLP in breeding lines of Brassica.

We developed a molecular method for the identification of the S-alleles of Brassicaceae, which belongs to the inbred line. This method is quicker and more precise than the existing methods. The genotype of the S-allele for 20 S-haplotypes of cabbage and 20 S-haplotypes of broccoli was determined by a pollination test. In order to identify the S-alleles, we performed PCR-RFLP with a mixture of the primers that are related to the S-locus glycoprotein (SLG) gene, which corresponds to the results of the pollination test. The selected primers amplified all of the single bands of about 1,150 bp in all 40 lines of cabbage and broccoli. Three out of 20 lines of cabbage were amplified by class I SLG specific primers, whereas all of the lines of the cabbage were amplified by class II SLG specific primers. Therefore, we could not classify class I and class II precisely by the class I and class II primers. However, 15 out of 20 lines of broccoli were amplified by the class I SLG specific primers. The remaining 5 lines were amplified with the class II SLG specific primers. We then digested the amplified PCR products with various restriction endonucleases and chose a restriction endonuclease, which accords exactly with the results of the diallel cross. The best one was HinfI. Its RFLP result was the same as that of the nucleotide sequence analysis. The 40 lines of cabbage and broccoli consisted of 16 different S-haplotypes. Therefore, the PCR-RFLP analysis was quicker and more precise in identifying the characteristics of S-haplotypes that are used in breeding. Also, we were able to check whether the lines could be mixed. The S-genotypes were difficult to determine due to the different flowering time.