Manganese superoxide dismutase (MnSOD) 3'-untranslated region: a novel molecular sensor for environmental stress

Chaudhuri, Leena

01 December 2010

Eukaryotic gene expression is a complex process and can be controlled at the level of transcription, post-transcription or translation and post-translation. In recent years, there is a growing interest in understanding the role of 3'-untranslated region (UTR) in regulating mRNA turnover and translation. The 3'-UTR harbors the poly(A) signal and post-transcriptional regulatory sequences like miRNA and AU-rich elements (AREs). The presence of multiple poly(A) sites often results in multiple transcripts; shorter transcripts correlating with more protein abundance. Manganese superoxide dismutase (MnSOD) is a nuclear encoded and mitochondrial matrix localized antioxidant enzyme that converts mitochondrial generated superoxide to hydrogen peroxide. Human MnSOD has two poly(A) sites resulting in two transcripts: 1.5 and 4.2 kb. We hypothesize that the 3'-UTR of MnSOD regulates its mRNA and protein levels as well as activity in response to growth states and environmental stress. Results from a Q-RT-PCR assay showed a preferential accumulation of the shorter MnSOD transcript during quiescence, which correlated with an increase in MnSOD activity. The accumulation of the longer MnSOD transcript during proliferation was associated with a decrease in MnSOD activity. Log transformed expression ratio of the longer to shorter transcript was also higher in proliferating epithelial non-cancerous (mammary: MCF-10A) and cancer cells (mammary: MB-231, SUM 159; oral squamous: SQ20B, FaDu, Cal27; and lung: A549, H292), suggesting that the abundance of the longer transcript is independent of cellular transformation status, instead it is dependent on cellular growth state. Interestingly, the abundance of the longer transcript directly correlated with percent S-phase (R2=0.86). The shorter transcript was enriched in irradiated MB-231 cells. MCF-10A cells exposed to 2-(4-chlorophenyl)benzo-1,4-quinone (4-Cl-BQ), a metabolite of the environmental pollutant polychlorinated biphenyl 3, showed a significant decrease in the abundance of the 4.2 kb transcript due to a faster mRNA turnover, 14 h compared to 20 h in untreated control cells. The decrease in the 4.2 kb transcript levels was associated with a corresponding decrease in MnSOD protein levels and activity, which resulted in a significant inhibition of quiescent cells entry into the proliferative cycle. Deletion and reporter assays showed: (a) a significant decrease in reporter activity in constructs carrying multiple AREs that are present in the 3'-UTR of the longer MnSOD transcript; (b) irradiation increased the reporter activity of the constructs carrying the 3'-UTR sequence of the shorter MnSOD transcript and (c) N-acetyl-cysteine increased the reporter activity of constructs carrying multiple AREs. Because the longer transcript carries AREs, our results identified redox sensitive AREs as novel regulators of MnSOD transcript levels. We conclude that MnSOD 3'-UTR is a novel molecular sensor regulating MnSOD mRNA levels in response to different growth states and environmental stress. A better understanding of the 3'-UTR regulating gene expression could lead to the development of new molecular biology-based redox therapy designed to treat proliferative disorders.

3'-untranslated region

Cancer

Cell cycle

Manganese superoxide dismutase

Tumor suppressor

THE DIFFERENCES BETWEEN IRON AND IRON-SUBSTITUTED MANGANESE SUPEROXIDE DISMUTASE WITH RESPECT TO HYDROGEN PEROXIDE TREATMENT

Wang, Jianing

01 January 2014

Iron-substituted manganese superoxide dismutase (Fe(Mn)SOD) was produced using an in vivo preparation method. It’s an inactive enzyme in catalyzing superoxide radical dismutation owing to the mis-incorporation of Fe in the active site evolved to use Mn. To investigate the possible toxicity of human Fe(Mn)SOD proposed by Yamakura, we studied the properties of Fe(Mn)SOD upon H2O2 treatment and compared to that of FeSOD. It’s found that the responses to H2O2 treatment were different, including the changes of optical spectra, variations of active site coordination and secondary structures. Fe3+ reduction was not observed in Fe(Mn)SOD even H2O2 is believed to oxidize proteins via highly reactive intermediates including Fe and formed via Fe2+, which is true in FeSOD. What’s more, the activities of Fe(Mn)SOD and FeSOD were totally different in the ABTS assay or Amplex Red assay. These results indicated that the mechanism of peroxidase reaction of Fe(Mn)SOD is not identical to that of FeSOD.

Hydrogen peroxide treatment

Tryptophan modification

secondary structure loss

Alternate substrate oxidation

Biochemistry