Downregulation of GLTSCR2 expression is correlated with breast cancer progression.

Glioma tumor-suppressor candidate region gene2 (GLTSCR2) is a recently identified nucleolus-localized protein participating in the regulation of cell cycle progression and apoptosis. Down-regulation of GLTSCR2 in several types of cancers and increased transforming activity in GLTSCR2-downregulated cancer cells indicated its tumor suppressive potential. The aim of this study was to evaluate GLTSCR2 expression in breast cancer and to investigate the question of whether reduced expression of GLTSCR2 may have any pathological significance in breast cancer development or progression. In this study, we performed quantitative RT-PCR and immunohistochemistry to evaluate the expression of GLTSCR2 and relevance with clinicopathological factors in the invasive ductal carcinoma (IDC). GLTSCR2 expression was reduced in 48% of IDC (n=426) by a semi-quantitative scoring system using tissue microarray. GLTSCR2 mRNA was significantly reduced by 0.16 fold in 15 out of 17 (88%) cases of IDC. Reduction of GLTSCR2 was significantly correlated with increased histological grade (p<0.005), increased tumor size (p<0.001), axillary lymph node involvement (p<0.001) and decreased disease free survival (p<0.025). In addition, we show that upregulation of GLTSCR2 decreases the invasive potential of breast cancer cells. Taken together, our data suggest that GLTCR2 may play a role in the tumorigenesis, progression and biological behavior in breast cancer.

Improved production of biohydrogen in light-powered Escherichia coli by co-expression of proteorhodopsin and heterologous hydrogenase.

BACKGROUND: Solar energy is the ultimate energy source on the Earth. The conversion of solar energy into fuels and energy sources can be an ideal solution to address energy problems. The recent discovery of proteorhodopsin in uncultured marine γ-proteobacteria has made it possible to construct recombinant Escherichia coli with the function of light-driven proton pumps. Protons that translocate across membranes by proteorhodopsin generate a proton motive force for ATP synthesis by ATPase. Excess protons can also be substrates for hydrogen (H(2)) production by hydrogenase in the periplasmic space. In the present work, we investigated the effect of the co-expression of proteorhodopsin and hydrogenase on H(2) production yield under light conditions. RESULTS: Recombinant E. coli BL21(DE3) co-expressing proteorhodopsin and [NiFe]-hydrogenase from Hydrogenovibrio marinus produced ~1.3-fold more H(2) in the presence of exogenous retinal than in the absence of retinal under light conditions (70 µmole photon/(m2·s)). We also observed the synergistic effect of proteorhodopsin with endogenous retinal on H(2) production (~1.3-fold more) with a dual plasmid system compared to the strain with a single plasmid for the sole expression of hydrogenase. The increase of light intensity from 70 to 130 µmole photon/(m(2)·s) led to an increase (~1.8-fold) in H(2) production from 287.3 to 525.7 mL H(2)/L-culture in the culture of recombinant E. coli co-expressing hydrogenase and proteorhodopsin in conjunction with endogenous retinal. The conversion efficiency of light energy to H(2) achieved in this study was ~3.4%. CONCLUSION: Here, we report for the first time the potential application of proteorhodopsin for the production of biohydrogen, a promising alternative fuel. We showed that H(2) production was enhanced by the co-expression of proteorhodopsin and [NiFe]-hydrogenase in recombinant E. coli BL21(DE3) in a light intensity-dependent manner. These results demonstrate that E. coli can be applied as light-powered cell factories for biohydrogen production by introducing proteorhodopsin.