The effects of EF-Ts and bismuth on EF-Tu in Helicobacter pylori: implications for an elegant timing for the introduction of EF-Ts in the elongation and EF-Tu as a potential drug target.

Helicobacter pylori is a common human pathogen responsible for various gastric diseases. Bismuth can effectively inhibit the growth of this bacterium and is commonly recommended for the treatment of the related diseases. Translation elongation factors EF-Tu and EF-Ts are two important components of the protein translation system. EF-Ts has inhibitory effects on the GTPase activity of EF-Tu and enhances GDP release, a hint that careful timing for the introduction of EF-Ts in the elongation should be accomplished to prevent the complete inhibition of the elongation process. Bismuth inhibits the chaperone activity of EF-Tu, and has opposite effects on the elongation activity: inhibitory effects on the intrinsic GTPase activity and stimulation of GDP release. The present work deepens our understanding of the bacterial elongation process as mediated by EF-Tu and EF-Ts and extends our knowledge about the inhibitory effects of bismuth-based drugs against Helicobacter pylori.

Isolation of mouse mesenchymal stem cells with normal ploidy from bone marrows by reducing oxidative stress in combination with extracellular matrix.

BACKGROUND: Isolation of mouse MSCs (mMSCs) with normal ploidy from bone marrow remains challenging. mMSCs isolated under 20% O(2) are frequently contaminated by overgrown hematopoietic cells, and could also be especially vulnerable to oxidative damage, resulting in chromosomal instability. Culture under low oxygen or extracellular matrix (ECM) improves proliferation of MSCs in several species. We tested the hypothesis that culture under low oxygen in combination with ECM prepared from mouse embryonic fibroblast (MEF-ECM) could be used to purify proliferative mMSCs, and to reduce oxidative damage and maintain their chromosomal stability. RESULTS: Optimization of culture conditions under 20% O(2) resulted in immortalization of mMSCs, showing extensive chromosome abnormalities, consistent with previous studies. In contrast, culture under low oxygen (2% O(2)) improved proliferation of mMSCs and reduced oxidative damage, such that mMSCs were purified simply by plating at low density under 2% O(2). MEF-ECM reduced oxidative damage and enhanced proliferation of mMSCs. However, these isolated mMSCs still exhibited high frequency of chromosome abnormalities, suggesting that low oxygen or in combination with MEF-ECM was insufficient to fully protect mMSCs from oxidative damage. Notably, antioxidants (alpha -phenyl-t-butyl nitrone (PBN) and N-acetylcysteine (NAC)) further reduced DNA damage and chromosomal abnormalities, and increased proliferation of mMSCs. mMSCs isolated by the combination method were successfully used to generate induced pluripotent stem (iPS) cells by ectopic expression of Oct4, Sox2, Klf4 and c-Myc. CONCLUSIONS: We have developed a technique that allows to reduce the number of karyotypic abnormalities for isolation of primary mMSCs and for limited culture period by combination of low oxygen, MEF-ECM, antioxidants and low density plating strategy. The effectiveness of the new combination method is demonstrated by successful generation of iPS cells from the isolated mMSCs. However, a culture system for mMSCs still is needed to prevent all the anomalies, especially after a long-term culture period.

Comparative analysis of duplicated sox21 genes in zebrafish.

Sox21 is thought to function as a counteracting partner of SoxB1 (Sox1, 2, 3) genes and is involved in cell fate determination. In this study, we comparatively analyzed the expression patterns and conserved cis-regulatory elements of the duplicated sox21 genes in zebrafish. In embryogenesis, sox21b is predominantly expressed in the telencephalon, hypothalamus, mesencephalon and lens, and sox21a is solely expressed in the midbrain-hindbrain boundary, olfactory placode and lateral line, while both genes are expressed in the hindbrain, spinal cord and ear. In adult, sox21a is expressed in the brain, skin, ovary and intestine, while sox21b is expressed in the brain and testis. Interestingly, all 16 pan-vertebrate conserved non-coding elements (CNEs) are asymmetrically preserved in the sox21b locus, whereas two fish-specific elements are kept in the sox21a locus, and this is correlated with increased evolutionary rate of the sox21a protein sequence. Transient transgenic reporter analysis revealed that six sox21b CNEs and two sox21a CNEs drove green fluorescent protein (GFP) expression in tissues correlated with the partitioning of expression in two orthologues. These results indicate that sox21a and sox21b have reciprocally lost expression domains of the ancestral gene reflected by degeneration of certain CNEs in their genomic loci and provide clear evidence for evolution of the duplicated sox21 genes by subfunctionalization. In addition, our data suggest that some CNEs-based regulatory pathways have been predominantly preserved in the sox21b locus.