Identification of the site of inhibition of mitogenic signaling by oncogenic ras-p21 by a ras effector peptide

We have previously found that a ras switch 1 domain peptide (PNC-7, residues 35–47) selectively blocks oocyte maturation induced by oncogenic (Val 12–containing) ras-p21 protein and also blocks c-raf–induced oocyte maturation. We now find that oncogenic ras-p21 does not inhibit oocyte maturation of a constitutively activated raf protein (raf BXB) that is lacking most of the first 301 amino terminal amino acids, including the major ras binding domain and accessory ras-binding regions. We also find that a dominant negative raf that completely blocks c-raf–induced maturation likewise does not block raf-BXB–induced maturation. We conclude that PNC-7 blocks ras by binding to the amino-terminal domain of raf and that raf BXB must initiate signal transduction in the cytosol.     

Formation of plant cuticle: evidence for the occurrence of the peroxygenase pathway

Cuticle plays a major role as a protective barrier in plants. Despite its physiological importance, the mode of formation of this complex structure remains poorly understood. In particular, none of the putative enzymes involved in the biosynthesis of the cutin, the matrix of cuticle, have been cloned. We have shown previously that peroxygenase is able to catalyze in vitro the epoxidation step required for the biosynthesis of C18 cutin monomers. In the present work, we have confirmed in planta that this oxidase is indeed a key enzyme involved in the formation of cutin. Thus, in maize leaves, the specific inactivation of peroxygenase by organophosphorothioates resulted in a dramatic decrease of cuticular epoxide content, as visualized by a specific histochemical technique that was accompanied by a reduced thickness of the cuticle. A strict correlation could also be established between the extent of inhibition of the peroxygenase and the modification of the cuticle triggered by a family of structurally related inhibitors. Importantly, these effects were restricted to plants that contain a cutin originating from C18 monomers. The altered cuticle of maize, treated with the peroxygenase inhibitor, was characterized by an increased permeability to pesticides. In addition, such plants became largely susceptible to infection by fungi, implying that the cuticle represents a crucial target for the modulation of the response in plant-pathogen interactions.     

Role of the switch II region in the conformational transition of activation of Ha-ras-p21

The role of the switch II region in the conformational transition of activation of Ha-ras-p21 has been investigated by mutating residues predicted to act as hinges for the conformational transition of this loop (Ala59, Gly60, and Gly75) (Díaz JF, Wroblowski B, Schlitter J, Engelborghs Y, 1997, Proteins 28:434-451), as well as mutating the catalytic residue Gln61. The proposed mutations of the hinge residues decrease the rate of the conformational transition of activation as measured by the binding of BeF3- to the GDP-p21 complex. Also, the thermodynamic parameters of the binding reaction are altered by a factor between three and five, depending on the temperature. (Due to changes in activation and reaction enthalpies, partially compensated by entropy changes.) The control mutation Q61H in which only the catalytic residue is changed has only a limited effect on the kinetic rate constants of the conformational transition and on the thermodynamic parameters of the reaction. The fact that mutations of the hinge residues of the switch II region affect both the binding of the phosphate analog and the conformational transition of activation indicates that the switch II is implicated both in the early and the late states of the transition.     

Differential Isotope Labeling Strategy for Determining the Structure of Myristoylated Recoverin by NMR Spectroscopy

The three-dimensional solution structure of recombinant bovine myristoylated recoverin in the Ca2+-free state has been refined using an array of isotope-assisted multidimensional heteronuclear NMR techniques. In some experiments, the myristoyl group covalently attached to the protein N-terminus was labeled with 13C and the protein was unlabeled or vice versa; in others, both were 13C-labeled. This differential labeling strategy was essential for structural refinement and can be applied to other acylated proteins. Stereospecific assignments of 41 pairs of -methylene protons and 48 methyl groups of valine and leucine were included in the structure refinement. The refined structure was constructed using a total of 3679 experimental NMR restraints, comprising 3242 approximate interproton distance restraints (including 153 between the myristoyl group and the polypeptide), 140 distance restraints for 70 backbone hydrogen bonds, and 297 torsion angle restraints. The atomic rms deviations about the averaged minimized coordinate positions for the secondary structure region of the N-terminal and C-terminal domains are 0.44 ± 0.07 and 0.55 ± 0.18 Å for backbone atoms, and 1.09 ± 0.07 and 1.10 ± 0.15 Å for all heavy atoms, respectively. The refined structure allows for a detailed analysis of the myristoyl binding pocket. The myristoyl group is in a slightly bent conformation: the average distance between C1 and C14 atoms of the myristoyl group is 14.6 Å. Hydrophobic residues Leu28, Trp31, and Tyr32 form a cluster that interacts with the front end of the myristoyl group (C1-C8), whereas residues Phe49, Phe56, Tyr86, Val87, and Leu90 interact with the tail end (C9-C14). The relatively deep hydrophobic pocket that binds the myristoyl group (C14:0) could also accommodate other naturally occurring acyl groups such as C12:0, C14:1, and C14:2 chains.     

增强型肿瘤特异性启动子介导CDTK治疗肝癌的体内外研究

目的:探讨运用增强子上调肿瘤特异性启动子h TERT转录活性后,调控自杀融合基因CDTK对人肝癌细胞系Bel-7402的体内外杀伤作用。方法:将CMV增强子、h TERT启动子及CDTK自杀融合基因克隆入核糖体基因区打靶载体p Hrn,构建p Hr-Ce Tp CDTK-GFP治疗载体并转染Bel-7402细胞,经RT-PCR、HPLC、MTT检测CDTK基因的表达和对肝癌细胞的体外杀伤效果。再将Bel-7402细胞接种到裸鼠皮下致瘤,以肿瘤杀伤载体p Hr-Ce Tp CDTK-GFP进行瘤内转染并检测其抑瘤效果,此外将转染后的细胞接种致瘤,检测其成瘤时间及肿瘤生长曲线等,从两方面检测其体内杀伤效果。结果:成功构建了肿瘤特异性治疗载体,体外转染肝癌细胞后,经RTPCR、HPLC证明CDTK基因能在肝癌中表达,且治疗载体在体外对肝癌细胞有明显毒性。动物实验结果发现裸鼠致瘤后治疗组血清中5-Fu浓度为7.694μg/ml,治疗组肿瘤体积与对照组相比减小6.5倍。而细胞转染治疗载体后致瘤,治疗组成瘤时间比对照组晚8天,且治疗组裸鼠的平均生存期较对照组延长16天。结论:p Hr-Ce Tp CDTK-GFP载体能在体内外高效靶向杀伤肝癌细胞,为肝癌基因治疗提供了一种新的途径。     

Measurement of H2S in Crude Oil and Crude Oil Headspace Using Multidimensional Gas Chromatography,Deans Switching and Sulfur-selective Detection

A method for the analysis of dissolved hydrogen sulfide in crude oil samples is demonstrated using gas chromatography. In order to effectively eliminate interferences, a two dimensional column configuration is used, with a Deans switch employed to transfer hydrogen sulfide from the first to the second column (heart-cutting). Liquid crude samples are first separated on a dimethylpolysiloxane column, and light gases are heart-cut and further separated on a bonded porous layer open tubular (PLOT) column that is able to separate hydrogen sulfide from other light sulfur species. Hydrogen sulfide is then detected with a sulfur chemiluminescence detector, adding an additional layer of selectivity. Following separation and detection of hydrogen sulfide, the system is backflushed to remove the high-boiling hydrocarbons present in the crude samples and to preserve chromatographic integrity. Dissolved hydrogen sulfide has been quantified in liquid samples from 1.1 to 500 ppm, demonstrating wide applicability to a range of samples. The method has also been successfully applied for the analysis of gas samples from crude oil headspace and process gas bags, with measurement from 0.7 to 9,700 ppm hydrogen sulfide.     

Crystal violet as an i-motif structure probe for reversible and label-free pH-driven electrochemical switch

A simple pH-induced electrochemical switch based on an i-motif structure is developed by using crystal violet as a selective electrochemical probe for the i-motif structure. Thiol-modified cytosine-rich single-strand oligonucleotide (C-rich ssDNA) can be self-assembled on the gold electrode surface via gold–sulfur interaction. Crystal violet is employed as an electrochemical probe for the i-motif structure because of its capability of binding with the i-motif structure through an end-stacking mode. In acidic aqueous solution, crystal violet may approach the electrode surface owing to the formation of the i-motif structure, resulting in an obvious signal, so-called “ON” state. Whereas in neutral or basic aqueous solution, the i-motif structure unfolds to dissociative single strand, which causes crystal violet to leave from the electrode surface, and a weak signal is obtained, so-called “OFF” state. In addition, in the range of pH 4.6–7.3, the increase in current has a good linear relationship (R = 0.989) with pH value in the testing solutions. This pH-driven electrochemical switch has the advantages of simplicity, sensitivity, high selectivity, and good reversibility. Furthermore, it provides a possible platform for pH measurement.     

A plausible model for bimodal p53 switch in DNA damage response

p53 is a tumor suppressor and the p53 dynamics displays stimulus dependent patterns. Recent evidence suggests a bimodal p53 switch in cell fate decision. However, no theoretical studies have been proposed to investigate bimodal p53 induction. Here we constructed a model and showed that MDM2–p53 mRNA binding might contribute to bimodal p53 switch through an intrinsic positive feedback loop. Lower damage favored pulsing while monotonic increasing was generated with higher damage. Bimodal p53 dynamics was largely influenced by cellular MDM2 and elevated p53/MDM2 ratios with increasing etoposide favor mono-ubiquitination. Our model replicated recent experiments and provided potential insights into dynamic mechanisms of bimodal switch.     

A switch-like dynamic mechanism for the initiation of replicative senescence

Telomeres are specialized structures protecting chromosomes against genome instability. Telomeres shorten with cell division, and replicative senescence is induced when telomeres are badly eroded. Whereas TRF2 (telomeric-repeat binding factor 2), ATM (ataxia telangiectasia mutated) and p53 have been identified involved in senescence induction, how it is triggered remains unclear. Here, we propose an integrated model associating telomere loss with senescence trigger. We characterize the dynamics of telomere shorting and the p53-centered regulatory network. We show that senescence is initiated in a switch-like manner when both the shortest telomere becomes uncapped and the TRF2-ATM-p53-Siah1 positive feedback loop is switched on. This work provides a coherent picture of senescence induction in terms of telomere shortening and p53 activation.