Effects of unsteady state conditions on the biooxidation of methyl ethyl and methyl isobutyl ketone in continuous flow liquid phase cultures

The effects of changing operating conditions on the biooxidation of methyl ethyl and/or methyl isobutyl ketone in continuous flow enrichment culture are examined. Particular emphasis is placed on responses to step changes in feed stream concentrations and to substrate pulses injected directly into the culture supernatant. In general, the enrichment culture was better able to handle transients involving methyl isobutyl ketone, the preferred carbon substrate. However, the highly complex response patterns observed clearly indicated major gaps in knowledge concerning the physiology of methyl ketone-oxidizing bacteria. In spite of the two carbon substrates investigated being major environmental pollutants, their removal in waste biotreatment processes is remarkably little understood.     

基于小麦种子发芽和根伸长的麝香酮污染毒性效应

研究了新型污染物麝香酮对小麦种子发芽及幼苗生长的影响.结果表明,土壤麝香酮（10 mg·kg^-1）污染对小麦发芽率抑制作用达到显著水平（P<0.05）,对小麦根长和芽长的抑制作用达极显著水平（P<0.01）,并且芽长、根长与土壤中麝香酮浓度之间存在极显著（P<0.01）的剂量 效应关系.表明小麦根和芽伸长可以指示土壤麝香酮的污染程度.在土壤麝香酮污染条件下,小麦幼苗的根长和芽长之间呈极显著（P<0.01）的正相关性,发芽率和生物量之间呈极显著（P<0.01）的负相关性.有机污染物的毒性除了与它在水中的溶解度有关外,还与其化学性质及对靶标生物的毒性机制有关.     

Synthese d'un acide gras cyclohexenique disubstitute: L'acide (propyl-2′ cyclohexen-4′ yl-1′)-9 nonanoïque

(Propyl-2′ cyclohexen-4′ yl-1′)-9 nonanoïc acid was synthesized through a succession of the following reactions: condensation, according to Kondakof, of methyl undecylenate and propionyl chloride; condensation, according to Diels Alder, between the resulting aliphatic ketone and butadiene; reduction of the disubstituted cyclohexenyl ketone, according to Hutchins.The compounds formed at each step of the synthesis were studied and characterized.     

Synthesis of methyl ketones by metabolically engineered Escherichia coli

Methyl ketones are a group of highly reduced platform chemicals with widespread applications in the fragrance, flavor and pharmacological industries. Current methods for the industrial production of methyl ketones include oxidation of hydrocarbons, but recent advances in the characterization of methyl ketone synthases from wild tomato have sparked interest towards the development of microbial platforms for the industrial production of methyl ketones. A functional methyl ketone biosynthetic pathway was constructed in Escherichia coli by over-expressing two genes from Solanum habrochaites: shmks2, encoding a 3-ketoacyl-ACP thioesterase, and shmks1, encoding a beta-decarboxylase. These enzymes enabled methyl ketone synthesis from 3-ketoacyl-ACP, an intermediate in the fatty acid biosynthetic cycle. The production of 2-nonanone, 2-undecanone, and 2-tridecanone by MG1655 pTH-shmks2-shmks1 was initially detected by nuclear magnetic resonance and gas chromatography–mass spectrometry analyses at levels close to 6?mg/L. The deletion of major fermentative pathways leading to ethanol (adhE), lactate (ldhA), and acetate (pta, poxB) production allowed for the carbon flux to be redirected towards methyl ketone production, doubling total methyl ketone concentration. Variations in methyl ketone production observed under different working volumes in flask experiments led to a more detailed analysis of the effects of oxygen availability on methyl ketone concentration in order to determine optimal levels of oxygen. The methyl ketone concentration achieved with MG1655 ?adhE ?ldhA ?poxB ?pta pTrcHis2A-shmks2-shmks1, the best performer strain in this study, was approximately 500?mg/L, the highest reported for an engineered microorganism. Through the establishment of optimal operating conditions and by executing rational metabolic engineering strategies, we were able to increase methyl ketone concentrations by almost 75-fold from the initial confirmatory levels.     

Synthesis of N-acylated 7-amino-2,6,7-trideoxy-D-erythroheptopyranosides from methyl alpha-D-mannoside

Hexopyranoside methyl alpha-D-mannoside (8) was homologated to yield 7-(acylamino)-2,6,7-trideoxy-heptopyranosides 19-26. A crucial reaction step is the radical cleavage of benzylidene derivative 10 to obtain bromide 11. Since nucleophilic substitution of 11 with KCN provided the bicyclic nitrile 13 instead of nitrile 14, ketone 11 was protected as the dimethyl acetal 15. Nucleophilic substitution of 15 with KCN, subsequent hydrogenation with H2/Raney Ni and acylation with various carboxylic acid derivatives yielded 7-(acylamino)heptopyranosides 19-22.     

An efficient synthesis of the precursor of AI-2, the signalling molecule for inter-species quorum sensing

Autoinducer-2 (AI-2) is a signalling molecule for bacterial inter-species communication. A synthesis of (S)-4,5-dihydroxypentane-2,3-dione (DPD), the precursor of AI-2, is described starting from methyl glycolate. The key step was an asymmetric reduction of a ketone with (S)-Alpine borane. This new method was highly reproducible affording DPD for biological tests without contaminants. The biological activity was tested with the previously available assays and compared with a new method using an Escherichia coli reporter strain thus avoiding the use of the pathogenic Salmonella reporter.     

Studies on bovine insulin with methyl vinyl ketone. Isolation of crystalline A1-3-oxobutyl derivative of bovine insulin

Reaction of methyl vinyl ketone with bovine insulin affords, amongst others, a crystalline A1-(3-oxobutyl)insulin. This retains full biological activity in the mouse convulsion assay. The presence of zinc ions changes the course of the above reaction, and illustrates the use of zinc as a "blocking function".     

Pathways and control of ketone body metabolism: on the fringe of lipid biochemistry

Ketone bodies become major body fuels during fasting and consumption of a high-fat, low-carbohydrate (ketogenic) diet. Hyperketonemia is associated with potential health benefits. Ketone body synthesis (ketogenesis) is the last recognizable step of lipid energy metabolism, a pathway that links dietary lipids and adipose triglycerides to the Krebs cycle and respiratory chain and has three highly regulated control points: (1) adipocyte lipolysis, (2) mitochondrial fatty acids entry, controlled by the inhibition of carnitine palmityl transferase I by malonyl coenzyme A (CoA) and (3) mitochondrial 3-hydroxy-3-methylglutaryl CoA synthase, which catalyzes the irreversible first step of ketone body synthesis. Each step is suppressed by an elevated circulating insulin level or insulin/glucagon ratio. The utilization of ketone bodies (ketolysis) also determines circulating ketone body levels. Consideration of ketone body metabolism reveals the mechanisms underlying the extreme fragility of dietary ketosis to carbohydrate intake and highlights areas for further study.     

Mutagenicity studies on ketone solvents: methyl ethyl ketone, methyl isobutyl ketone, and isophorone

3 ketone solvents (methyl ethyl ketone (MEK), methyl isobutyl ketone (MiBK), and isophorone) were tested for potential genotoxicity. The assays of MEK and MiBK included the Salmonella/microsome (Ames) assay, L5178Y/TK+/- mouse lymphoma (ML) assay, BALB/3T3 cell transformation (CT) assay, unscheduled DNA synthesis (UDS) assay, and micronucleus (MN) assay. Only the ML, UDS, and MN assays were conducted on samples of isophorone. No genotoxicity was found for MEK or isophorone. The presence of a marginal response only at the highest, cytotoxic concentration tested in the ML assay, the lack of reproducibility in the CT assay, and clearly negative results in the Ames assay, UDS and MN assays, suggest that MiBK is unlikely to be genotoxic in mammalian systems.     

Cytotoxicity of alkylating agents in isolated rat kidney proximal tubular and distal tubular cells

Patterns of chemical-induced cytotoxicity in different regions of the nephron were studied with freshly isolated proximal tubular and distal tubular cells from rat kidney. Three model alkylating agents, methyl vinyl ketone, allyl alcohol, and N-dimethylnitrosamine, were used as test chemicals. Methyl vinyl ketone and a metabolite of allyl alcohol, acrolein, are Michael acceptors that bind to cellular protein sulfhydryl groups and GSH. N-Dimethylnitrosamine binds to cellular protein and DNA. Lactate dehydrogenase leakage was used to assess irreversible cellular injury. Distal tubular cells were more susceptible than proximal tubular cells to injury produced by methyl vinyl ketone or allyl alcohol while the two cell populations were equally susceptible to injury produced by N-dimethylnitrosamine. Preincubation of both proximal tubular and distal tubular cells with GSH protected them from methyl vinyl ketone- and allyl alcohol-induced cytotoxicity but had no effect on N-dimethylnitrosamine-induced cytotoxicity. Similarly, incubation of cells with methyl vinyl ketone or allyl alcohol, but not N-dimethylnitrosamine, altered cellular GSH status. As with GSH status, incubation of cells with methyl vinyl ketone or allyl alcohol, but not N-dimethylnitrosamine, caused pronounced inhibitory effects on mitochondrial function, as evidenced by ATP depletion and inhibition of cellular oxygen consumption. These results demonstrate that alkylating agents are cytotoxic to both proximal tubular and distal tubular cells, and that interaction with cellular GSH is a factor determining nephron cell type specificity of injury.     

Influence of chiral carvones on selectivity of pure lipase-B from Candida antarctica

Summary In the esterification reaction in non-aqueous media lipase-B from Candida antarctica is stereoselective towards the R-isomer of ketoprofen in an achiral solvent such as isobutyl methyl ketone and in S(+) carvone. On the contrary, S(+) ketroprofen is esterified quicker in R(–) carvone. In addition, the esterification yield changes depending on the stereochemistry of the carvone used as solvent. The formation of disteromeric complexes (chiral solvent + chiral substrates) may explain this finding.     

The oxidation and (methylthio)methylation of cotton by methyl sulfoxide-acetic anhydride

Methyl sulfoxide-acetic anhydride oxidizes some of the cellulosic hydroxyl groups of cotton yarn to aldehyde and ketone groups, while etherifying other hydroxyl groups with (methylthio)methyl groups. The ratio of oxidation to (methylthio)methylation of the cellulose is influenced by the reaction temperature, the reaction time, and the ratio of methyl sulfoxide to acetic anhydride employed. The (methylthio)methyl groups may be cleaved by boiling the cotton in aqueous solutions of acetic acid.The total carbonyl content of the oxidized cellulose was determined by conversion into the polyoxime. The ratio of aldehyde to ketone groups in the oxidized cellulose was determined by further oxidation with chlorous acid; the car?yl groups produced were measured spectrophotometrically by a method involving adsorption of Methylene Blue.     

Acetone, methyl ethyl ketone, ethyl acetate, acetonitrile and other polar aprotic solvents are strong inducers of aneuploidy in Saccharomyces cerevisiae

A diploid yeast strain D61.M was used to study induction of mitotic chromosomal malsegregation, mitotic recombination and point mutation. Several ketones (including acetone and methyl ethyl ketone) and some organic acid esters (including the methyl, ethyl and 2-methoxyethyl esters of acetic acid) and acetonitrile strongly induced aneuploidy but not recombination or point mutation. Only diethyl ketone induced low levels of recombination and point mutation in addition to aneuploidy. Related compounds were weak inducers of aneuploidy: methyl n-propyl ketone, the methyl esters of propionic and butyric acid, acetic acid esters of n- and iso-propanol and ethyl propionate. No mutagenicity was found with n-butyl and isoamyl acetate, ethyl formate, acetyl acetone (2,5-dipentanone) and dioxane. Methyl isopropyl ketone induced only some recombination and point mutation but no aneuploidy. Efficient induction was only observed with a treatment protocol in which growing cells were exposed to the chemicals during a growth period of 4 h at 28 degrees C followed by incubation in ice for more than 90 min, usually overnight for 16-17 h. Aneuploid cells could be detected in such cultures during a subsequent incubation at growth temperature if the chemical was still present. Detailed analysis showed that there was a high incidence of multiple events of chromosomal malsegregation. It is proposed that the mutagenic agents act directly on tubulin during growth so that labile microtubules are formed which dissociate in the cold. When cells are brought back to temperatures above the level critical for reassembly of tubulin and allowed to grow, faulty microtubules are formed.     

A general route to 4-C-branched sugars. Synthesis of methyl alpha-caryophylloside

The total synthesis of methyl 3,6-dideoxy-4-C-(D-altro-1,3,4,5 tetrahydroxyhexyl)-alpha-D-xylo-hexopyranoside, the methyl glycoside of the recently isolated 4-C-branched sugar caryophyllose, has been completed in a stereoselective and convergent manner. The synthesis of this dodecose relies on the diiodosamarium mediated coupling of two six-carbon fragments: a cyclic ketone and an acid chloride.     

Reduction in mitochondrial membrane potential is an early event in Fas-independent CTL-mediated apoptosis.

Cytotoxic T lymphocytes (CTL) can destroy target cells via the Fas-mediated pathway or the granule-mediated pathway. We used Fas-negative target cells to examine for target-cell reduction in mitochondrial membrane potential (DeltaPsi(m)) induced by intact CTL via the granule-mediated pathway. We find that reduction in DeltaPsi(m) is an early step in Fas-independent CTL killing of target cells that precedes phosphatidyl serine translocation, cytosolic protein release, or loss of plasma membrane integrity. Target-cell reduction in DeltaPsi(m) and cytoplasmic protein release in Fas-independent CTL killing were inhibited by N-carbobenzoxy-Ala-Pro-Phe chloromethyl ketone, but not by caspase inhibitors N-carbobenzoxy-Val-Ala-Asp fluoromethyl ketone (z-VAD-fmk) or N-carbobenzoxy-Asp-Glu-Val-Asp fluoromethyl ketone (z-DEVD-fmk). This contrasts with Fas-mediated apoptosis, in which the reduction in DeltaPsi(m) can be inhibited by z-VAD-fmk or z-DEVD-fmk. Assessing the changes in target-cell DeltaPsi(m) can provide for a sensitive and rapid means with which to monitor CTL activity.     

Methyl ketone production by Pseudomonas putida is enhanced by plant-derived amino acids

Plants are an attractive sourceof renewable carbon for conversion to biofuels and bio-based chemicals. Conversion strategies often use a fraction of the biomass, focusing on sugars from cellulose and hemicellulose. Strategies that use plant components, such as aromatics and amino acids, may improve the efficiency of biomass conversion. Pseudomonas putida is a promising host for its ability to metabolize a wide variety of organic compounds. P. putida was engineered to produce methyl ketones, which are promising diesel blendstocks and potential platform chemicals, from glucose and lignin-related aromatics. Unexpectedly, P. putida methyl ketone production using Arabidopsis thaliana hydrolysates was enhanced 2–5-fold compared with sugar controls derived from engineered plants that overproduce lignin-related aromatics. This enhancement was more pronounced (~seven-fold increase) with hydrolysates from nonengineered switchgrass. Proteomic analysis of the methyl ketone-producing P. putida suggested that plant-derived amino acids may be the source of this enhancement. Mass spectrometry-based measurements of plant-derived amino acids demonstrated a high correlation between methyl ketone production and amino acid concentration in plant hydrolysates. Amendment of glucose-containing minimal media with a defined mixture of amino acids similar to those found in the hydrolysates studied led to a nine-fold increase in methyl ketone titer (1.1 g/L).     

Patterns of biosynthesis and accumulation of hydrocarbons and contact sex pheromone in the female german cockroach,Blattella germanica

De novo synthesis of contact female sex pheromone and hydrocarbons in Blattella germanica was examined using short in vivo incubations. Accumulation of pheromone on the epicuticular surface and the internal pheromone titer were related to age-specific changes in hydrocarbon synthesis and accumulation in normal and allatectomized females. The incorporation of radiolabel from [1-¹⁴C]propionate into the cuticular methyl ketone pheromone fraction was positively related to corpora allata activity during two gonotrophic cycles. During peak pheromone production the total internal lipid fraction contained greater titers of pheromone than the cuticular surface, and it too exhibited a cycle internally, preceding the rise in external pheromone. This suggests that synthesis and accumulation of pheromone internally are followed by transport of pheromone to the epicuticular surface where it accumulates. Radiolabel was incorporated efficiently into both cuticular and internal hydrocarbons after the imaginal molt and until the peak of pheromone synthesis, but it declined to lower levels before ovulation and throughout pregnancy. The internal hydrocarbon titer decreased 58% after oviposition, suggesting deposition in the egg case. It remained relatively unchanged during pregnancy and increased again during the second gonotrophic cycle. In allatectomized females, hydrocarbon synthesis was reduced relative to control females until oviposition in the latter. However, subsequent rates of hydrocarbon synthesis in allatectomized females (without oothecae) exceeded the rates in sham-operated females (with oothecae). In the absence of ovarian uptake of hydrocarbons, the internal titer increased without the decline found in control females at oviposition. As internal hydrocarbons increased, so did cuticular hydrocarbons and both internal and cuticular methyl ketone pheromones. These patterns corresponded well with feeding patterns in sham-operated and allatectomized females, suggesting that pheromone production is normally regulated by stage-specific feeding-induced hydrocarbon synthesis (precursor accumulation internally) and juvenile hormoneinduced conversion of hydrocarbon to pheromone. They also suggest that both the cuticle and the ovaries might be target sites for hydrocarbon and possibly methyl ketone deposition. © 1994 Wiley-Liss, Inc.     

Aerobic biotreatment of acetone and methanol in a continuous flow bioreactor during unsteady state operation

The responses of a culture, enriched with acetone and methanol as dual carbon energy substrates, when growing in a continuous flow bioreactor are examined with respect to various imposed transient state operating conditions. The transients investigated include both removal from and addition to the process feed of acetone and methanol, step changes in the concentrations of acetone and methanol in the process feed, and step changes in the dilution rates employed. The capacity of the culture to achieve complete acetone oxidation, after step changes, was shown to be suspect, emphasizing the need to base performance criteria for biotreatment process operation on individual key component concentrations rather than on the lumped parameters widely used to describe pollutant loads in aqueous effluents.