Influence of diastereomeric ratios of deoxyribonucleoside phosphoramidites on the synthesis of phosphorothioate oligonucleotides

Extensive investigations on the influence of diastereomeric ratios of deoxyribonucleoside phosphoramidites on stereo-reproducibility of solid phase synthesis of phosphorothioate oligodeoxyribonucleotides via the phosphoramidite approach indicate that the process is stereoreproducible and under inherent process control.     

Continuous acetonitrile degradation in a packed-bed bioreactor

A 20-l packed-bed reactor filled with foamed glass beads was tested for the treatment of acetonitrile HPLC wastes. Aeration was provided by recirculating a portion of the reactor liquid phase through an aeration tank, where the dissolved oxygen concentration was kept at 6 mg/l. At a feeding rate of 0.77 g acetonitrile l^–1 reactor day^–1, 99% of the acetonitrile was removed; and 86% of the nitrogen present in acetonitrile was released as NH₃, confirming that acetonitrile volatilization was not significant. Increasing the acetonitrile loading resulted in lower removal efficiencies, but a maximum removal capacity of 1.0 g acetonitrile l^–1 reactor day^–1 was achieved at a feeding rate of 1.6 g acetonitrile l^–1 reactor day^–1. The removal capacity of the system was well correlated with the oxygenation capacity, showing that acetonitrile removal was likely to be limited by oxygen supply. Microbial characterization of the biofilm resulted in the isolation of a Comamonas sp. able to mineralize acetonitrile as sole carbon, nitrogen and energy source. This organism was closely related to C. testosteroni (91.2%) and might represent a new species in the Comamonas genus. This study confirms the potential of packed-bed reactors for the treatment of a concentrated mixture of volatile pollutants.     

Structural basis for feedback inhibition of the deoxyribonucleoside salvage pathway: studies of the Drosophila deoxyribonucleoside kinase

Deoxyribonucleoside kinases are feedback inhibited by the final products of the salvage pathway, the deoxyribonucleoside triphosphates. In the present study, the mechanism of feedback inhibition is presented based on the crystal structure of a complex between the fruit fly deoxyribonucleoside kinase and its feedback inhibitor deoxythymidine triphosphate. The inhibitor was found to be bound as a bisubstrate inhibitor with its nucleoside part in the nucleoside binding site and with its phosphate groups partially occupying the phosphate donor site. The overall structure of the enzyme--inhibitor complex is very similar to the enzyme--substrate complexes with deoxythymidine and deoxycytidine, except for a conformational change within a region otherwise directly involved in catalysis. This conformational change involves a magnesium ion, which is coordinated in the inhibitor complex to the phosphates and to the primary base, Glu52, that normally is positioned close to the 5'-OH of the substrate deoxyribose.     

Regulation of Cidea protein stability by the ubiquitin-mediated proteasomal degradation pathway

Cidea, one of three members of the CIDE (cell-death-inducing DNA-fragmentation-factor-45-like effector) family of proteins, is highly enriched in brown adipose tissue, in which it plays a critical role in adaptive thermogenesis and fat accumulation. Cidea-null mice have increased energy expenditure with resistance to high-fat-diet-induced obesity and diabetes. However, little is known as to how the Cidea protein is regulated. In the present study we show that Cidea is a short-lived protein as measured by cycloheximide-based protein chase experiments in different cell lines or in differentiated brown adipocytes. Proteasome inhibitors specifically increased the stability of both transfected and endogenous Cidea protein. Furthermore, Cidea protein was found to be polyubiquitinated when overexpressed in different culture cells as well as in differentiated mature brown adipocytes. Extensive mutational analysis of individual lysine residues revealed that ubiquitinated lysine residues are located in the N-terminal region of Cidea, as alteration of these lysine residues to alanine (N-5KA mutant) renders Cidea much more stable when compared with wild-type or C-terminal lysine-less mutant (C-5KA). Furthermore, K23 (Lys23) within the N-terminus of the Cidea was identified as the major contributor to its polyubiquitination signal and the protein instability. Taken together, the results of our study demonstrated that the ubiquitin-proteasome system confers an important post-translational modification that controls the protein stability of Cidea.     

Simultaneous degradation of acetonitrile and biphenyl by Pseudomonas aeruginosa

A bacterium capable of utilizing either acetonitrile as the sole source of carbon and nitrogen or biphenyl as the sole source of carbon was isolated from soil and identified as Pseudomonas aeruginosa. The bacterium also utilized other nitriles, amides, and polychlorinated biphenyls (PCBs) as growth substrates. Acetonitrile- or biphenyl-grown cells oxidized these substrates without a lag. In studies with [14C]acetonitrile, nearly 74% of the carbon was recovered as 14CO2 and 8% was associated with the biomass. In studies with [14C]biphenyl, nearly 68% of the carbon was recovered as 14CO2 and nearly 6% was associated with the biomass. Although higher concentrations of acetonitrile as the sole sources of nitrogen inhibited the rates of [14C]biphenyl mineralization, lower concentrations (0.05%, w/v) gave a 77% stimulation in 14CO2 recovery. Pseudomonas aeruginosa metabolized acetonitrile to ammonia and acetic acid and biphenyl to benzoic acid. The bacterium also simultaneously utilized biphenyl as the sole carbon source and acetonitrile as the sole nitrogen source. However, biphenyl utilization increased only after the depletion of acetonitrile. Metabolites of the mixed substrate were ammonia and benzoic acid, which completely disappeared in the later stages of incubation. Nitrile hydratase and amidase were responsible for the transformation of acetonitrile to acetic acid and ammonia.     

Remaining acetamide in acetonitrile degradation using nitrile hydratase- and amidase-producing microorganisms

The tandem conversion process involving nitrile hydratase- and amidase-producing microorganisms has potential for use in the treatment of acetonitrile-containing wastes. In that process, the acetamide hydrolysis step catalyzed by amidase is very slow compared with the acetonitrile hydration step catalyzed by nitrile hydratase, and a small amount of acetamide remains in the resulting solution. This study aimed to improve the efficiency of the acetamide hydrolysis step. An amidase-producing microorganism, Rhodococcus sp. S13-4, was newly obtained, whose use enabled rapid acetamide degradation. Though residual acetamide was still detected, it was successfully reduced by the addition of cation/anion mixed ion exchange resin or calcium hydroxide after the acetamide hydrolysis reaction using Rhodococcus sp. S13-4 cells. This result implies that acetamide hydrolysis and acetamide formation are in equilibrium. The incubation of Rhodococcus sp. S13-4 cells with high concentrations of ammonium acetate produced acetamide. The purified amidase from Rhodococcus sp. S13-4 revealed the acetamide formation activity (specific activity of 30.6 U/mg protein). This suggests that the amidase-catalyzed amide formation may cause the remaining of acetamide in the acetonitrile conversion process.     

Microbial degradation of acetonitrile using a suspended-carrier biofilm process

A microbial process for the destruction of acetonitrile has been developed. Suitable microorganisms were enriched from activated sludge by cultivation with a high selection pressure when acetonitrile was the sole source of carbon and nitrogen. The process is based on cultivating the microorganisms as a biofilm on plastic carriers. These are utilised in a stirred-tank reactor with continuous feeding of 40–150 mM acetonitrile and an outlet for spent medium. The observed efficiency in the conversion process was from 53–100%, depending on the organic load. To improve the capacity and reliability of the process, a two-step process was developed with two stirred-tank reactors coupled in series. With such an arrangement, conversion efficiencies from 92–100% were achieved when the organic load was 2 g acetonitrile l^–1 d^–1 in the first reactor.     

Application of 2-cyanoethyl N,N,N'',N''-tetraisopropylphosphorodiamidite for in situ preparation of deoxyribonucleoside phosphoramidites and their use in polymer-supported synthesis of oligodeoxyribonucleotides.

Deoxyribonucleoside phosphoramidites are prepared in situ from 5'-O,N-protected deoxyribonucleosides and 2-cyanoethyl N,N,N',N'-tetraisopropylphosphorodiamidite with tetrazole as catalyst, and the solutions applied directly on an automatic solid-phase DNA synthesizer. Using LCAA-CPG support and a cycle time of 12.5 min, oligonucleotides of 16-25 bases are obtained with a DMT-efficiency per cycle of 98.0-99.3%. The crude and fully deblocked products are of a purity comparable to that obtained using purified phosphoramidites. In case of d(G)16 the product was difficult to analyse and a better product was not obtained using doubly protected (O-6 diphenylcarbamoyl) guanine.     

Method of addition of acetonitrile influences the structure and stability of collagen

Collagen has been extensively used as a biomaterial in many biomedical applications. Recently, collagen based biomaterials were prepared using organic solvents. In this context, the method of addition of organic solvent described in the present study will be an important contribution in the preparation of collagen-based biomaterials. The effect of acetonitrile on collagen structure and stability was investigated using biophysical methods. Collagen undergoes solvent-induced denaturation with increasing concentration of acetonitrile. It was observed that addition of acetonitrile (50–90%) to a collagen solution in a single shot (method 1) led to precipitation. Contrary, collagen remained in the solution when acetonitrile content was increased to 90% in a collagen solution that had been formerly equilibrated with 20% acetonitrile (method 2). Interestingly, triple helical structure was retained when precipitated collagen, obtained from method 1, was re-dissolved in acetic acid solution. The re-dissolved collagen exhibits comparable melting temperature as that of native collagen. Re-dissolved collagen also showed fibril formation, but with decreased rate. The soluble collagen in 90% acetonitrile, prepared by method 2, is found to be unordered. The above results thus suggest that the method of addition of acetonitrile plays an important role in the folding and unfolding of collagen.     

六六六微生物降解途径的研究进展

六六六是一种曾在世界范围内广泛使用的有机氯杀虫剂。由于其具有高毒性和长残留性,目前在发达国家已经被限制或禁止使用,但是一些发展中国家和地区仍然在继续使用。即使在一些停用六六六多年的国家,六六六的残留依然存在。概述六六六降解菌的多样性和六六六4种主要同分异构体(α-、β-、γ-、δ-HCH)的微生物降解的最新研究进展,为六六六污染地区进行经济可行的生物修复提供参考。     

Modulation of the intracellular stability and toxicity of diphtheria toxin through degradation by the N-end rule pathway.

The enzymatically active A-fragment of diphtheria toxin enters the cytosol of sensitive cells where it inhibits protein synthesis by inactivating elongation factor 2 (EF-2). We have constructed a number of diphtheria toxin mutants that are degraded by the N-end rule pathway in Vero cells, and that display a wide range of intracellular stabilities. The degradation could be inhibited by the proteasome inhibitor lactacystin, indicating that the proteasome is responsible for N-end rule-mediated degradation in mammalian cells. Previously, the N-end rule has been investigated by studying the co-translational degradation of intracellularly expressed beta-galactosidase. Our work shows that a mature protein entering the cytosol from the exterior can also be degraded by the N-end rule pathway with a similar, but not identical specificity to that previously found. We found a correlation between the intracellular stability of the mutants and their toxic effect on cells, thus demonstrating a novel manner of modulating the toxicity of a protein toxin. The data also indicate that the inactivation of EF-2 is the rate-limiting step in the intoxication process.     

Aerobic degradation of dinitrotoluenes and pathway for bacterial degradation of 2,6-dinitrotoluene

An oxidative pathway for the mineralization of 2,4-dinitrotoluene (2, 4-DNT) by Burkholderia sp. strain DNT has been reported previously. We report here the isolation of additional strains with the ability to mineralize 2,4-DNT by the same pathway and the isolation and characterization of bacterial strains that mineralize 2, 6-dinitrotoluene (2,6-DNT) by a different pathway. Burkholderia cepacia strain JS850 and Hydrogenophaga palleronii strain JS863 grew on 2,6-DNT as the sole source of carbon and nitrogen. The initial steps in the pathway for degradation of 2,6-DNT were determined by simultaneous induction, enzyme assays, and identification of metabolites through mass spectroscopy and nuclear magnetic resonance. 2,6-DNT was converted to 3-methyl-4-nitrocatechol by a dioxygenation reaction accompanied by the release of nitrite. 3-Methyl-4-nitrocatechol was the substrate for extradiol ring cleavage yielding 2-hydroxy-5-nitro-6-oxohepta-2,4-dienoic acid, which was converted to 2-hydroxy-5-nitropenta-2,4-dienoic acid. 2, 4-DNT-degrading strains also converted 2,6-DNT to 3-methyl-4-nitrocatechol but did not metabolize the 3-methyl-4-nitrocatechol. Although 2,6-DNT prevented the degradation of 2,4-DNT by 2,4-DNT-degrading strains, the effect was not the result of inhibition of 2,4-DNT dioxygenase by 2,6-DNT or of 4-methyl-5-nitrocatechol monooxygenase by 3-methyl-4-nitrocatechol.     

Effect of acetonitrile on Cynara cardunculus L. cardosin A stability

The kinetics of the structural changes affecting cardosin A, a plant aspartic proteinase (AP) from Cynara cardunculus L., in the presence of a mixture of acetonitrile (AN) in water (W) was studied. Incubation of cardosin A with 10% (v/v) AN resulted in a gradual increase in protein helicity, accompanied by changes in the tertiary structure, seen by changes in the intrinsic fluorescence of tryptophan. Differential scanning calorimetry (DSC) revealed that the temperature of denaturation of cardosin A decreased upon the addition of AN. With longer incubation times, the small chain of cardosin A denatured completely, consequent exposure of the single tryptophan residue accounting well for the observed spectral shift intrinsic fluorescence of the protein. Enzymatic activity assays demonstrated that the kinetically determined unfolding of the small chain of cardosin A does not result in loss of the activity of this enzyme.     

Enzyme kinetics of the mitochondrial deoxyribonucleoside salvage pathway are not sufficient to support rapid mtDNA replication

Using a computational model, we simulated mitochondrial deoxynucleotide metabolism and mitochondrial DNA replication. Our results indicate that the output from the mitochondrial salvage enzymes alone is inadequate to support a mitochondrial DNA replication duration of as long as 10 hours. We find that an external source of deoxyribonucleoside diphosphates or triphosphates (dNTPs), in addition to those supplied by mitochondrial salvage, is essential for the replication of mitochondrial DNA to complete in the experimentally observed duration of approximately 1 to 2 hours. For meeting a relatively fast replication target of 2 hours, almost two-thirds of the dNTP requirements had to be externally supplied as either deoxyribonucleoside di- or triphosphates, at about equal rates for all four dNTPs. Added monophosphates did not suffice. However, for a replication target of 10 hours, mitochondrial salvage was able to provide for most, but not all, of the total substrate requirements. Still, additional dGTPs and dATPs had to be supplied. Our analysis of the enzyme kinetics also revealed that the majority of enzymes of this pathway prefer substrates that are not precursors (canonical deoxyribonucleosides and deoxyribonucleotides) for mitochondrial DNA replication, such as phosphorylated ribonucleotides, instead of the corresponding deoxyribonucleotides. The kinetic constants for reactions between mitochondrial salvage enzymes and deoxyribonucleotide substrates are physiologically unreasonable for achieving efficient catalysis with the expected in situ concentrations of deoxyribonucleotides.     

The pathway of hemoglobin degradation in malaria parasites

Hemoglobin degradation in malaria parasites appears to be a vital and massive undertaking during intraerythrocytic development. An ordered pathway exists that efficiently catabolizes hemoglobin to yield amino acids that the parasite uses as a nutrient source, and that co-ordinates the resultant heme into a remarkable crystalline structure called hemozoin. Daniel Goldberg and Andrew Slater explain that the enzymes involved are specific and present prime targets for chemotherapeutic intervention.     

一株萘降解菌的筛选及其降解途径

从胜利油田被污染土壤中筛选出一株能够以萘为唯一碳源的菌株W1,经形态和生理生化以及16S rD-NA测序分析,初步鉴定为沙雷氏菌属。其最适生长条件为35℃,pH 7.5。该菌对盐及萘有较好的耐受性。当培养基盐质量浓度为30 g/L,底物萘质量浓度为100 mg/L时,培养3 d后,其萘降解率仍可达到80.9%。当萘浓度为800 mg/L时,仍具有一定的降解作用,降解率为15.8%。通过对菌株降解原油前后组分的GC-MS分析,以及检测其降解多种底物后的吸光度,得出该菌能利用苯酚、甲苯、苯甲酸、1-萘酚、丙酮、辛烷生长,对原油中组分C20～C23、C33～C36的直链烃有较好的降解效果。经UV-Vis扫描其降解中间产物,初步判断其萘降解生物途径为邻苯二酚途径,萘首先被其降解生成水杨酸,而后转化为邻苯二酚,开环并生成一系列小分子物质,最后进入三羧酸循环。     

Vacuole import and degradation pathway: Insights into a specialized autophagy pathway

Glucose deprivation induces the synthesis of pivotagluconeogenic enzymes such as fructose-1,6-bisphos-phatase, malate dehydrogenase, phosphoenolpyruvatecarboxykinase and isocitrate lyase in Saccharomycescerevisiae. However, following glucose replenishment,these gluconeogenic enzymes are inactivated and de-graded. Studies have characterized the mechanismsby which these enzymes are inactivated in response toglucose. The site of degradation of these proteins hasalso been ascertained to be dependent on the dura-tion of starvation. Glucose replenishment of short-termstarved cells results in these proteins being degradedin the proteasome. In contrast, addition of glucose tocells starved for a prolonged period results in theseproteins being degraded in the vacuole. In the vacuoledependent pathway, these proteins are sequestered inspecialized vesicles termed vacuole import and degra-dation (Vid). These vesicles converge with the endo-cytic pathway and deliver their cargo to the vacuolefor degradation. Recent studies have identified thatinternalization, as mediated by actin polymerization, isessential for delivery of cargo proteins to the vacuolefor degradation. In addition, components of the targetof rapamycin complex 1 interact with cargo proteins during glucose starvation. Furthermore, Tor1p dissoci-ates from cargo proteins following glucose replenish-ment. Future studies will be needed to elaborate on the importance of internalization at the plasma membrane and the subsequent import of cargo proteins into Vid vesicles in the vacuole dependent degradation pathway.