Pyridine salvage and nicotinic acid conjugate synthesis in leaves of mangrove species

The metabolic fate of [carbonyl-¹⁴C]nicotinamide was surveyed in leaf disks of seven mangrove species, Bruguiera gymnorrhiza, Rhizophora stylosa, Kandeliaobovata, Sonneratia alba, Pemphis acidula, Lumnitzera racemosa and Avicennia marina, with and without 250 mM NaCl. Uptake of [¹⁴C]nicotinamide by leaf disks was stimulated by 250 mM NaCl in K. candel, R. stylosa, A. marina and L. racemosa. [Carbonyl-¹⁴C]nicotinamide was converted to nicotinic acid and was utilised for the synthesis of nucleotides and nicotinic acid conjugates. Formation of nicotinic acid by the deaminase reaction was rapid; there was little accumulation of nicotinamide in the disks 3 h after administration. Radioactivity from [carbonyl-¹⁴C]nicotinamide was incorporated into pyridine nucleotides (mainly NAD and NADP) in all mangrove leaves, and the rates varied from 2% (in L. racemosa) to 15% (S. alba) of the total radioactivity taken up. NaCl generally reduced nicotinic acid salvage for NAD and NADP. In all mangrove leaf disks, the most heavily labelled compounds (up to 70% of total radioactivity) were trigonelline (N-methylnicotinic acid) and/or nicotinic acid N-glucoside. Trigonelline was formed in all mangrove plants, but N-glucoside synthesis was found only in leaves of A. marina and K. obovata. In A. marina, incorporation of radioactivity into N-glucoside (51%) was much greater than incorporation into trigonelline (2%). In general, NaCl stimulates the synthesis of these pyridine conjugates. The rate of decarboxylation of nicotinic acid in roots of A. marina seedlings was much greater than for the corresponding reaction observed in leaves.     

Probing of contacts between <Emphasis Type="Italic">Eco</Emphasis>RII DNA methyltransferase and DNA with the use of substrate analogs and molecular modeling

The molecular mechanisms of DNA recognition and modification by EcoRII DNA methyltransferase (M.EcoRII) were studied using 14-mer substrate analogs containing 2-aminopurine or 1′,2′-dideoxy-D-ribofuranose in the M.EcoRII recognition site. The efficiency of DNA binding and methylation depended on the position of a modified nucleoside residue in the recognition site. A structural model of M.EcoRII in complex with substrate DNA and the cofactor analog S-adenosyl-L-homocysteine (AdoHcy) was constructed using the available crystal structures of M.Hha and M.HaeIII and the recent Frankenstein’s monster approach. The amino acid residues interacting with DNA were predicted based on the model. In addition, theoretical and experimental findings made it possible to predict the groups of atoms of the heterocyclic bases of the M.EcoRII recognition site that are presumably involved in the interactions with the enzyme.     

Application of DNA methyltransferases in targeted DNA methylation

Taxol is a valuable plant-derived drug showing activity against various cancer types. Worldwide efforts had been made to overcome the supply problem, because the supply by isolation from the bark of the slow-growing yew trees is limited. Plant cell cultures as well as chemical and biotechnological semisynthesis are processes, which are intensively investigated for the production of taxanes paclitaxel (Taxol) and docetaxel (Taxotere) in the last few years. This article provides a comparison of the current research on taxane biosynthesis and production in yew cell cultures.     

Recognition elements in rRNA for the tylosin resistance methyltransferase RlmA(II)

The methyltransferase RlmA(II) (formerly TlrB) is found in many Gram-positive bacteria, and methylates the N-1 position of nucleotide G748 within the loop of hairpin 35 in 23S rRNA. Methylation of the rRNA by RlmA(II) confers resistance to tylosin and other mycinosylated 16-membered ring macrolide antibiotics. We have previously solved the solution structure of hairpin 35 in the conformation that is recognized by the RlmA(II) methyltransferase from Streptococcus pneumoniae. It was shown that while essential recognition elements are located in hairpin 35, the interactions between RlmA(II) and hairpin 35 are insufficient on their own to support the methylation reaction. Here we use biochemical techniques in conjunction with heteronuclear/homonuclear nuclear magnetic resonance spectroscopy to define the RNA structures that are required for efficient methylation by RlmA(II). Progressive truncation of the rRNA substrate indicated that multiple contacts occur between RlmA(II) and nucleotides in stem-loops 33, 34 and 35. RlmA(II) appears to recognize its rRNA target through specific surface shape complementarity at the junction formed by these three helices. This means of recognition is highly similar to that of the orthologous Gram-negative methyltransferase, RlmA(I) (formerly RrmA), which also interacts with hairpin 35, but methylates at the adjacent nucleotide G745.     

A comparison of the folding of two knotted proteins: YbeA and YibK

The extraordinary topology of proteins belonging to the alpha/beta-knot superfamily of proteins is unexpected, due to the apparent complexities involved in the formation of a deep trefoil knot in a polypeptide backbone. Despite this, an increasing number of knotted structures are being identified; how such proteins fold remains a mystery. Studies on the dimeric protein YibK from Haemophilus influenzae have led to the characterisation of its folding pathway in some detail. To complement research into the folding of YibK, and to address whether folding pathways are conserved for members of the alpha/beta-knot superfamily, the structurally similar knotted protein YbeA from Escherichia coli has been studied. A comprehensive thermodynamic and kinetic analysis of the folding of YbeA is presented here, and compared to that of YibK. Both fold via an intermediate state populated under equilibrium conditions that is monomeric and considerably structured. The unfolding/refolding kinetics of YbeA are simpler than those found for YibK and involve two phases attributed to the formation of a monomeric intermediate state and a dimerisation step. In contrast to YibK, a change in the rate-determining step on the unfolding pathway for YbeA is observed with a changing concentration of urea. Despite this difference, both proteins fold by a mechanism involving at least one sequential monomeric intermediate that has properties similar to that observed during the equilibrium unfolding. The rate of dimerisation observed for YbeA and YibK is very similar, as is the rate constant for formation of the kinetic monomeric intermediate that precedes dimerisation. The findings suggest that relatively slow folding and dimerisation may be common attributes of knotted proteins.     

Investigation of the mechanism of nicotine demethylation in Nicotiana through 2H and 15N heavy isotope effects: implication of cytochrome P450 oxidase and hydroxyl ion transfer

Heavy-atom isotope effects for the N-demethylation of nicotine have been determined in vivo in static-phase biosynthetically incompetent plant cell cultures of Nicotiana species. A (2)H kinetic isotope effect of 0.587 and a (15)N kinetic isotope effect of 1.0028 were obtained. An identical (15)N kinetic isotope effect of 1.0032 was obtained for the nicotine analogue, N-methyl-2-phenylpyrrolidine. The magnitude of the (15)N heavy-atom isotope effect indicates that the fission of the CN bond is not rate limiting for demethylation. The theoretical calculation of heavy-atom isotope effects for a model of the reaction pathway based on cytochrome P450 best fits the measured kinetic isotope effect to the addition of hydroxyl ion to iminium to form N-hydroxymethyl, for which the computed (2)H- and (15)N kinetic isotope effects are 0.689 and 1.0081, respectively. This large inverse (2)H kinetic isotope effect is not compatible with the initial abstraction of the H from the methyl group playing a significant kinetic role in the overall kinetic limitation of the reaction pathway, since computed values for this step (4.54 and 0.9995, respectively) are inconsistent with the experimental data.     

Protein arginine methylation regulates insulin signaling in L6 skeletal muscle cells

Protein N-arginine methyltransferase (PRMT)1 catalyzes arginine methylation in a variety of substrates, although the potential role of PRMT1 in insulin action has not been defined. We therefore investigated the effect of PRMT1-mediated methylation on insulin signaling and glucose uptake in skeletal L6 myotubes. Exposure of L6 myotubes to insulin rapidly induced translocation of PRMT1 and increased its catalytic activity in membrane fraction. Several proteins in the membrane fraction were arginine-methylated after insulin treatment, which were inhibited by pretreatment with an inhibitor of methyltransferase, 5′-deoxy-5′-(methylthio)adenosine (MTA), or a small interfering RNA against PRMT1 (PRMT1-siRNA). Inhibition of arginine methylation with MTA or PRMT1-siRNA diminished later phase of insulin-stimulated tyrosine phosphorylation of insulin receptor (IR) β and IRS-1, association of IRS-1 with p85α subunit of PI3-K, and glucose uptake. Our results suggest that PRMT1-mediated methylation serves as a positive modulator of IR/IRS-1/PI3-K pathway and subsequent glucose uptake in skeletal muscle cells.     

Spermatinamine, the first natural product inhibitor of isoprenylcysteine carboxyl methyltransferase, a new cancer target

Isoprenylcysteine methyltransferase (Icmt) catalyzes the carboxyl methylation of oncogenic proteins in the final step of a series of post-translational modifications. The inhibition of Icmt provides an attractive and novel anticancer target. A natural product high-throughput screening campaign was conducted to discover inhibitors of Icmt. The Australian marine sponge, Pseudoceratina sp., yielded spermatinamine, a novel alkaloid with a bromotyrosyl-spermine-bromotyrosyl sequence, as the bioactive constituent. Its structure was determined by 1D and 2D NMR spectroscopy. Spermatinamine is the first natural product inhibitor of Icmt.     

植物表观遗传与DNA甲基化

表观遗传在植物生长发育过程中起着极其重要的作用。甲基化是基因组DNA的一种主要表观遗传修饰形式,是调节基因功能的重要手段。介绍了植物体中胞嘧啶甲基化现象,RNA指导的DNA甲基化的信号分子、作用机制,以及与RNA介导的基因沉默机制之间的区别和RNA对转座子的表观控制。