First dual M3 antagonists-PDE4 inhibitors: synthesis and SAR of 4,6-diaminopyrimidine derivatives

SAR around 4,6-diaminopyrimidine derivatives allowed the discovery of the first potent dual M(3) antagonists and PDE4 inhibitors. Various chemical modulations around that scaffold led to the discovery of ucb-101333-3 which is characterized by the most interesting profile on both targets.     

Ssp DnaB intein大肠杆菌中介导FVIII重链和轻链的连接

研究利用intein的蛋白质反式剪接功能在大肠杆菌中对凝血VIII因子(FVIII)重链和轻链的连接作用,将B结构域大部分缺失型FVIII(BDD-FVIII)于满足剪接所需的保守性氨基酸Ser1657前断裂为重链和轻链,分别与split mini Ssp DnaB intein的106个氨基酸的N端(Int-N)和48个氨基酸的C端(Int-C)融合,构建到原核表达载体pBV220。诱导表达后SDS-PAGE分析可见预期大小的BDD-FVIII蛋白条带,Western blotting用FVIII特异性抗体证明其为剪接所产生的BDD-FVIII蛋白,表明intein可有效连接BDD-FVIII的重链和轻链。为进一步甲型血友病基因治疗研究应用intein以双腺相关病毒载体(AAV)携带FVIII基因,克服单个AAV载体的容量限制提供了依据。     

S-Adenosyl-N-decyl-aminoethyl, a Potent Bisubstrate Inhibitor of Mycobacterium tuberculosis Mycolic Acid Methyltransferases

S-Adenosylmethionine-dependent methyltransferases (AdoMet-MTs) constitute a large family of enzymes specifically transferring a methyl group to a range of biologically active molecules. Mycobacterium tuberculosis produces a set of paralogous AdoMet-MTs responsible for introducing key chemical modifications at defined positions of mycolic acids, which are essential and specific components of the mycobacterial cell envelope. We investigated the inhibition of these mycolic acid methyltransferases (MA-MTs) by structural analogs of the AdoMet cofactor. We found that S-adenosyl-N-decyl-aminoethyl, a molecule in which the amino acid moiety of AdoMet is substituted by a lipid chain, inhibited MA-MTs from Mycobacterium smegmatis and M. tuberculosis strains, both in vitro and in vivo, with IC₅₀ values in the submicromolar range. By contrast, S-adenosylhomocysteine, the demethylated reaction product, and sinefungin, a general AdoMet-MT inhibitor, did not inhibit MA-MTs. The interaction between Hma (MmaA4), which is strictly required for the biosynthesis of oxygenated mycolic acids in M. tuberculosis, and the three cofactor analogs was investigated by x-ray crystallography. The high resolution crystal structures obtained illustrate the bisubstrate nature of S-adenosyl-N-decyl-aminoethyl and provide insight into its mode of action in the inhibition of MA-MTs. This study has potential implications for the design of new drugs effective against multidrug-resistant and persistent tubercle bacilli.One-third of the world population is infected with the tubercle bacillus, Mycobacterium tuberculosis, and tuberculosis kills one person every 20 s. The inhaled pathogenic bacilli are taken up by phagocytosis by pulmonary macrophages, which, together with lymphocytes and dendritic cells, form granulomas. The bacilli persist in the granuloma until their reactivation, dissemination into the lungs, and the triggering of disease. The natural resistance of persistent tubercle bacilli to drugs and the emergence of multidrug-resistant and extensively drug-resistant M. tuberculosis strains are two main concerns in the treatment of the disease. A survey carried out by the Centers for Disease Control and Prevention and the World Health Organization between 2000 and 2004 reported that 20% of 17,690 M. tuberculosis isolates from 49 countries were multidrug-resistant, and 2% were extensively drug-resistant (1). The development of new drugs effective against persistent and drug-resistant bacilli has therefore become a priority.The thick lipid-rich envelope of the Mycobacterium genus is characterized by the presence of mycolic acids (MAs),⁴ very long chain (C₆₀–C₉₀) α-alkylated β-hydroxylated fatty acids (2). MAs are the major components of the mycomembrane (3, 4) lipid bilayer, which plays a key role in both the architecture and permeability of the mycobacterial envelope. The MA biosynthetic pathway is essential for mycobacterial survival. MAs are generated by Claisen condensation between two fatty acyl chains as follows: the very long meromycoloyl chain (C₄₀–C₆₀) and a shorter saturated chain (C₂₂–C₂₆) (2). The different types of MAs are defined by the presence of decorations introduced at proximal and distal positions of the meromycolic chain (Fig. 1A) by a family of paralogous S-adenosylmethionine-dependent methyltransferases (AdoMet-MTs), the mycolic acid methyltransferases (MA-MTs). These chemical modifications are known to be important for the pathogenicity, virulence, and persistence of M. tuberculosis. For example, the cis-cyclopropane introduced at the proximal position of α-MAs by PcaA has an impact on the persistence of the tubercle bacillus within infected organisms (5). Furthermore, the keto and methoxy groups, with a vicinal methyl ramification at the distal position of oxygenated MAs, play a role in M. tuberculosis virulence in the mouse model of infection (6) and have recently been reported to be involved in host-pathogen interplay. Indeed, oxygenated MAs have been shown to modulate IL-12p40 production by macrophages (7) and to trigger the in vitro differentiation of monocyte-derived macrophages into foamy macrophages, which house the bacillus in a dormant state, within granulomas (8). Oxygenated MA biosynthesis requires the Hma (MmaA4) methyltransferase (Fig. 1B), as demonstrated by the absence of the oxygenated form in an M. tuberculosis hma knock-out mutant (6, 9). These results suggest that the enzymes responsible for adding the decorations to MAs, including oxygenated groups in particular, may be relevant pharmacological targets for the development of new antituberculous drugs (10).Open in a separate windowFIGURE 1.A, structures of MAs from M. tuberculosis and M. smegmatis. D, distal position; P, proximal position. Enzymes involved in the introduction of decorations on the meromycolic chain are indicated. B, proposed reaction scheme for the introduction of oxygenated groups. m = 17, 19; n, unknown; X, unknown carrier.Based on the essential role played by MA-MTs in the physiopathology of tuberculosis, several studies have investigated the possible inhibition of this family of enzymes. A recent study revealed that the antituberculous drug thiacetazone and its chemical analogs inhibited MA cyclopropanation at concentrations in the micromolar range (11). Another study, based on mixtures of crude extracts of heat-inactivated mycobacteria and recombinant Escherichia coli overproducing MA-MTs, suggested that the incorporation of [³H]AdoMet into growing meromycolic chains is inhibited by a high concentration (1 mg/ml, i.e. 2.6 mm) of S-adenosyl-l-homocysteine (AdoHcy) or sinefungin (12), the demethylated reaction product and a natural structural analog of AdoMet, respectively (Fig. 2). By contrast, AdoHcy and sinefungin are strong inhibitors of other AdoMet-MTs in vitro, including the cyclopropane fatty-acid synthase (CFAS) from E. coli (K_i of 30 and 0.22 μm, respectively) (13, 14). However, they are active only against the isolated enzyme, whereas S-adenosyl-N-decyl-aminoethyl (SADAE), a molecule in which the amino acid moiety of AdoMet is substituted by a lipid chain (Fig. 2), is active against CFAS both in vitro (K_i,app = 6 μm) and in vivo (complete inhibition at 150 μm) (15). The broad screening of possible inhibitors of MA-MTs with an in vitro mini-assay poses a major challenge, as these enzymes most likely use very long meromycolic chains as substrates. In this context, the similarity between CFAS and Hma in terms of their sequences (31% sequence identity) and substrates may be useful, as it suggests that SADAE may inhibit MA-MTs (15).Open in a separate windowFIGURE 2.Structure of AdoMet and of the AdoHcy, sinefungin, and SADAE analogs.We report here our investigations of the interactions between Hma and SADAE, as compared with those between Hma and AdoHcy or sinefungin, and the potential impact of these interactions on the activities of Hma and other MA-MTs and mycobacterial growth. Our high resolution crystallographic characterization of the Hma-SADAE interaction illustrates the bisubstrate nature of the ligand, which is strongly correlated with its strong inhibitory properties.     

The 2.1 Å crystal structure of an acyl‐CoA synthetase from Methanosarcina acetivorans reveals an alternate acyl‐binding pocket for small branched acyl substrates

The acyl‐AMP forming family of adenylating enzymes catalyze two‐step reactions to activate a carboxylate with the chemical energy derived from ATP hydrolysis. X‐ray crystal structures have been determined for multiple members of this family and, together with biochemical studies, provide insights into the active site and catalytic mechanisms used by these enzymes. These studies have shown that the enzymes use a domain rotation of 140° to reconfigure a single active site to catalyze the two partial reactions. We present here the crystal structure of a new medium chain acyl‐CoA synthetase from Methanosarcina acetivorans. The binding pocket for the three substrates is analyzed, with many conserved residues present in the AMP binding pocket. The CoA binding pocket is compared to the pockets of both acetyl‐CoA synthetase and 4‐chlorobenzoate:CoA ligase. Most interestingly, the acyl‐binding pocket of the new structure is compared with other acyl‐ and aryl‐CoA synthetases. A comparison of the acyl‐binding pocket of the acyl‐CoA synthetase from M. acetivorans with other structures identifies a shallow pocket that is used to bind the medium chain carboxylates. These insights emphasize the high sequence and structural diversity among this family in the area of the acyl‐binding pocket. Proteins 2009. © 2009 Wiley‐Liss, Inc.     

Kinetic determination of tryptophan by using the B-Z oscillating chemical system

A simple and rapid method was devised for determination of tryptophan, based on the Belousov-Zhabotinskii (B-Z) oscillating chemical system. Changes in oscillating period and amplitude were linearly proportional to the negative logarithm of l-tryptophan concentration over the range of 6.44 × 10⁻⁷–2.55 × 10⁻⁴ M, with the regression coefficients of near unity and a lower detection limit of 6.5 × 10⁻⁸ M. d-tryptophan was also examined although it is rarely found in most biological fluids, and perhaps not at all in natural proteins. The change of period against to negative logarithm of d-tryptophan concentration over the range of 4.9 × 10⁻⁵–8.24 × 10⁻⁴ M is linear. Because the optimum conditions for determination of l- and d-tryptophan are not the same, a little amount of d-tryptophan does not affect the determination of l-tryptophan. Various influences were studied and a possible mechanism of perturbation to the B-Z oscillator by tryptophan was also discussed. Spectrophotometry and fluorescence spectrophotofluorimetry were used for comparision and confirmation of the results.     

Microbial transformation of phytosterol in corn flour and soybean flour to 4-androstene-3,17-dione by Fusarium moniliforme Sheld

A strain that was capable of transforming the phytosterol in corn flour and soybean flour was isolated from soil and identified as Fusarium moniliforme Sheld. The main transformation product was purified by high performance liquid chromatography (HPLC), and was characterized by nuclear magnetic resonance (NMR), mass spectrum (MS), and infrared spectrum (IR). The results indicated that the product was 4-androstene-3,17-dione (AD). The production of AD was increased with the increase of initial concentration of corn flour while the yield of AD was decreased. The yield of AD was lower in the media with only soybean flour. Sulfate–phosphate–ferric method (SPF) was first used for determination of the total phytosterol content in corn flour or soybean flour. The measured value by SPF method matched reasonably well with that by HPLC, which indicated the validity of SPF method.     

Population dynamics in bioaugmented membrane bioreactor for treatment of bromoamine acid wastewater

The performances and microbial population changes in laboratory-scale membrane bioreactor (MBR) augmented with Sphingomonas xenophaga QYY were investigated in the present study. It was demonstrated that after 30 days acclimation, the non-augmented MBR system were able to degrade bromoamine acid (BAA) well. However, the efficiency of the system decreased with BAA concentration increasing. While the augmented MBR showed higher capability, in which the color and COD removal were more than 90% and 50%, respectively. By ribosomal intergenic spacer analysis (RISA), it was found that BAA-utilizing populations gradually increased to become the dominant species in the non-augmented MBR. However, the augmented MBR possessed relatively stable treatment abilities, in which the introduced strain QYY could be persistent and co-exist well with the indigenous populations.     

Using the combined bioelectrochemical and sulfur autotrophic denitrification system for groundwater denitrification

A combined bioelectrochemical and sulfur autotrophic denitrification system (CBSAD) was evaluated to treat a groundwater with nitrate contamination (20.9-22.0mgNO(3)(-)-N/L). The reactor was operated continuously for several months with groundwater to maximize treatment efficiency under different hydraulic retention times (HRT) and electric currents. The denitrification rate of sulfur autotrophic part followed a half-order kinetics model. Moreover, the removal efficiency of bioelectrochemical part depended on the electric current. The reactor could be operated efficiently at the HRT ranged from 4.2 to 2.1h (corresponding nitrogen volume-loading rates varied from 0.12 to 0.24 kg N/m(3)d; and optimum current ranged from 30 to 1000 mA), and the NO(3)(-)-N removal rate ranged from 95% to 100% without NO(3)(-)-N accumulation. The pH of effluent was satisfactorily adjusted by bioelectrochemical part, and the sulfate concentration of effluent was lower than 250 mg/L, meeting the drinking water standard of China EPA.     

Small-Molecule Selectively Recognizes Human Telomeric G-Quadruplex DNA and Regulates Its Conformational Switch

Structural complexity is an inherent feature of the human telomeric sequence, and it presents a major challenge for developing ligands of pharmaceutical interest. Recent studies have pointed out that the induction of a quadruplex or change of a quadruplex conformation on binding may be the most powerful method to exert the desired biological effect. In this study, we demonstrate a quadruplex ligand that binds selectively to different forms of the human telomeric G-quadruplex structure and regulates its conformational switch. The results show that not only can oxazine750 selectively induce parallel quadruplex formation from a random coil telomeric oligonucleotide in the absence of added cations, it also can easily surpass the energy barrier between two structures and change the G-quadruplex conformation in Na⁺ or K⁺ solution. The combination of its unique properties, including the size and shape of the G-quadruplex and the small molecule, is proposed as the predominant force for regulating the special structural formation and transitions. These results may stimulate the design of new quadruplex binders that would be capable of discriminating different G-quadruplex structures as well as controlling biological phenomena, functional molecules, and nanomaterials.