The Xdsg protein in presumptive primordial germ cells (pPGCs) is essential to their differentiation into PGCs in Xenopus

In order to know the role of the Xdsg gene in presumptive PGCs (pPGCs) of Xenopus, we attempted to inhibit the translation of Xdsg mRNA in pPGCs by injecting antisense morpholino oligo (asMO), together with Fluorescein Dextran-Lysine (FDL), into single germ plasm-bearing cells of 32-cell embryos. Among three types of asMOs complementary to different parts of the 5'-untranslated region of Xdsg mRNA tested, only one asMO, designated as Xdsg-3, inhibited the translation of the mRNA in FDL-labeled pPGCs, resulting in the absence of labeled PGCs in experimental tadpoles. On the other hand, two other asMOs, Xdsg-1 and -2, did not inhibit the translation, so that a similar number of labeled PGCs found in FDL-injected but asMO-uninjected control tadpoles were observed in experimental tadpoles derived from asMO-injected embryos. Surprisingly, use of Xdsg-3 asMO resulted in the disappearance of the protein of Xenopus vasa homolog (Xenopus vasa-like gene 1, XVLG1) from FDL-labeled pPGCs by inhibiting the translation of XVLG1 mRNA. However, the effect of Xdsg-3 asMO on the translation of Xdsg and XVLG1 mRNAs and PGC formation could be canceled by the coinjection with Xdsg mRNA. Consequently, the Xdsg protein in pPGCs may play an important role in the formation of PGCs by regulating the production of XVLG1 protein.     

The Tat system proofreads FeS protein substrates and directly initiates the disposal of rejected molecules

The twin-arginine translocation (Tat) system transports folded proteins across the bacterial plasma membrane, including FeS proteins that receive their cofactors in the cytoplasm. We have studied two Escherichia coli Tat substrates, NrfC and NapG, to examine how, or whether, the system exports only correctly folded and assembled FeS proteins. With NrfC, substitutions in even one of four predicted FeS centres completely block export, indicating an effective proofreading activity. The FeS mutants are rapidly degraded but only if they interact with the Tat translocon; they are stable in a tat deletion strain and equally stable in wild-type cells if the signal peptide twin-arginine motif is removed to block targeting. Basically similar results are obtained with NapG. The Tat apparatus thus proofreads these substrates and directly initiates the turnover of rejected molecules. Turnover of mutated FeS substrates is completely dependent on the TatA/E subunits that are believed to be involved in the late stages of translocation, and we propose that partial translocation triggers substrate turnover within an integrated quality control system for FeS proteins.     

A p38 MAPK-CREB pathway functions to pattern mesoderm in Xenopus

Dorsal-ventral patterning is specified by signaling centers secreting antagonizing morphogens that form a signaling gradient. Yet, how morphogen gradient is translated intracellularly into fate decisions remains largely unknown. Here, we report that p38 MAPK and CREB function along the dorsal-ventral axis in mesoderm patterning. We find that the phosphorylated form of CREB (S133) is distributed in a gradient along the dorsal-ventral mesoderm axis and that the p38 MAPK pathway mediates the phosphorylation of CREB. Knockdown of CREB prevents chordin expression and mesoderm dorsalization by the Spemann organizer, whereas ectopic expression of activated CREB-VP16 chimera induces chordin expression and dorsalizes mesoderm. Expression of high levels of p38 activator, MKK6E or CREB-VP16 in embryos converts ventral mesoderm into a dorsal organizing center. p38 MAPK and CREB function downstream of maternal Wnt/β-catenin and the organizer-specific genes siamois and goosecoid. At low expression levels, MKK6E induces expression of lateral genes without inducing the expression of dorsal genes. Loss of CREB or p38 MAPK activity enables the expansion of the ventral homeobox gene vent1 into the dorsal marginal region, preventing the lateral expression of Xmyf5. Overall, these data indicate that dorsal-ventral mesoderm patterning is regulated by differential p38/CREB activities along the axis.     

Thermodynamic contributions of the reactions of DNA intramolecular structures with their complementary strands

One focus of our research is to further our understanding of the physico-chemical properties of unusual DNA structures and their interaction with complementary oligonucleotides. We have investigated three types of reactions involving the interaction of intramolecular DNA complexes with their complementary single strands of varied length. Specifically, we have used a combination of isothermal titration (ITC) and differential scanning (DSC) calorimetry and spectroscopy techniques to determine standard thermodynamic profiles for the reaction of an i-motif, G-quadruplex, and triplex with their complementary strands. The enthalpies for each reaction are measured directly in ITC titrations and compared with those obtained indirectly from Hess cycles using DSC unfolding data. All reactions investigated yielded favorable free energy contributions, indicating that each single strand is able to invade and disrupt the corresponding intramolecular DNA complex. These favorable free energy terms are enthalpy driven, which result from a compensation of exothermic contributions, due to the formation of additional base-pair stacks (or base-triplet stacks) in the duplex product (or triplex product), immobilization of electrostricted water by the base-pair and base-triplet stacks, and the removal of structural water from the reactant single strands; and endothermic contributions from the disruption of base-base stacking interactions of the reactant single strands. This investigation of nucleic acid reactions has provided new methodology, based on physico-chemical principles, to determine the molecular forces involved in the interactions between DNA nucleic acid structures. This methodology may be used in targeting reactions for the control of gene expression.     

<Emphasis Type="Italic">Escherichia coli tat</Emphasis> mutant strains are able to transport maltose in the absence of an active <Emphasis Type="Italic">malE</Emphasis> gene

The twin-arginine transport (Tat) system is a prokaryotic protein transport system. Escherichia coli mutants in this pathway show a defect in cell separation during cell division, resulting in destabilization and permeability of the outer membrane. Maltose uptake is catalysed by a membrane-bound transporter of the ATP binding cassette (ABC) superfamily, where MalE is the essential periplasmic binding protein component. Here, we report that tat mutants are unexpectedly able to transport maltose in the absence of malE. This observation is specific to the MalE component since co-inactivation of malF, which encodes one of the channel components of the transporter, completely abolishes maltose transport even when the Tat system is inactivated. Genetic repair of the outer membrane leaky phenotype of the tat mutant strain re-established the absolute requirement for MalE in maltose uptake. In addition, we demonstrate that phenotypic repair of the outer membrane defect of the tat strain can also be achieved chemically by the inclusion of high concentrations of calcium or magnesium in the growth medium.     

Enhancement of gene transfer using YIGSR analog of Tat-derived peptide

Cell penetrating peptide based gene carriers are notably known for low level of gene transfer. To remedy this, as laminin receptor (LR) has been previously linked to tumor metastasis, the LR-binding domain (YIGSR) as well as a scrambled sequence (SGIYR) were added to Tat-derived peptide sequence (YIGSR-Tat and SGIYR-Tat respectively). Peptides cellular uptake was assessed with high-LR (HT1080) and low-LR (HT29) cell lines by flow cytometry. Their ability to form complexes with DNA was examined using YOPRO-1 fluorescence assay and their transfection efficiencies evaluated using a luciferase reporter gene assay. DNA complexes were formed at (+/-) charge ratios as low as 2:1. While no conclusion could be drawn on the effect of YIGSR sequence on peptides uptake in both cell lines, a significant improvement in gene transfection in HT1080 cells was achieved using YIGSR-Tat compared to Tat and SGIYR-Tat. Additionally this increased efficiency was inhibited by excess free YIGSR. No significant difference in transfection efficiency was observed between Tat, SGIYR-Tat and YIGSR-Tat based complexes in HT29 cells. These studies demonstrate that attachment of receptor-binding ligand (YIGSR) to Tat-derived peptide can improve the efficiency of gene transfer in LR-positive cells (HT1080).     

PG与番茄果实成熟的关系

系统比较了转多聚半乳糖醛酸酶(PG)反义基因和对照番茄果实成熟过程中绿熟、转色、粉顶、粉红、全红5个时期的PG活性和与其相关的生理、生化组分的动态变化.实验表明,转基因果与对照果相比,PG活性始终处于较低水平,PG活性强烈被抑制是在全红期;果实的硬度、贮藏寿命指数都高于对照果;番茄红素合成积累进程被延缓;可溶性果胶含量、电解质外渗百分率均低于对照果.外源乙烯刺激引起对照果PG活性剧增,而转基因果表现钝化.讨论了PG活性与果实成熟、耐贮性及软化的关系,及对外源乙烯刺激的敏感性.首次明确提出PG活性在对照果中极大地表达,在转基因果中强烈被抑制是在全红期,而不是在整个成熟期;PG活性在果实软化中起直接和重要作用;PG活性的高低与番茄红素的合成与积累有关.