M. Kraml scite author profile

Cell-free protein synthesis is a versatile protein production system. Performance of the protein synthesis depends on highly active cytoplasmic extracts. Extracts from E. coli are believed to work best; they are routinely obtained from exponential growing cells, aiming to capture the most active translation system. Here, we report an active cell-free protein synthesis system derived from cells harvested at non-growth, stressed conditions. We found a downshift of ribosomes and proteins. However, a characterization revealed that the stoichiometry of ribosomes and key translation factors was conserved, pointing to a fully intact translation system. This was emphasized by synthesis rates, which were comparable to those of systems obtained from fast-growing cells. Our approach is less laborious than traditional extract preparation methods and multiplies the yield of extract per cultivation. This simplified growth protocol has the potential to attract new entrants to cell-free protein synthesis and to broaden the pool of applications. In this respect, a translation system originating from heat stressed, non-growing E. coli enabled an extension of endogenous transcription units. This was demonstrated by the sigma factor depending activation of parallel transcription. Our cell-free expression platform adds to the existing versatility of cell-free translation systems and presents a tool for cell-free biology.

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A High-Performance Liquid Chromatographic Method for the Simultaneous Determination of Venlafaxine and O-Desmethylvenlafaxine in Biological Fluids

Hicks

Wolaniuk

Russell

et al. 1994

Therapeutic Drug Monitoring

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The Metabolic Disposition of Etodolac in Rats, Dogs, and Man

Cayen¹,

Kraml²,

Ferdinandi³

et al. 1981

Drug Metabolism Reviews

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The metabolic disposition of etodolac (etodolic acid) was studied after oral and intravenous administration of the 14C-labeled or unlabeled drug to rats and dogs, and after oral administration of the drug to man. In all species, peak serum drug levels were attained within 2 hr after dosing. In rats and dogs, virtually all of the oral dose was absorbed; etodolac represented 95% of the serum radioactivity in rats and 75% in dogs. Serum levels in all species were generally dose-related. The elimination portion of the serum drug concentration/time curves was characterized by several peaks, which in rats were shown to be due to enterohepatic circulation. Tissue distribution studies in rats showed that radioactivity localized primarily in blood vessels, connective tissue, and highly vascularized organs (liver, heart, lung, and kidney) and that the rate of elimination of radioactivity from tissues was similar to that found in the serum. The apparent elimination half-life of etodolac averaged 17 hr in rats, 10 hr in dogs, and 7 hr in man. Etodolac was extensively bound to serum proteins. Liver microsomal cytochrome P-450 levels were unaltered in rats given etodolac daily for 1 week. The primary route of excretion in rats and dogs was via the bile into the feces. Preliminary biotransformation studies in dogs showed the presence of the glucuronide conjugate of etodolac in bile, but not in the urine. Glucuronide conjugates were not seen in the rat. Four hydroxylated metabolites in rat bile were tentatively identified. It was concluded that, in rats and dogs, etodolac is well absorbed, is subject to extensive enterohepatic circulation, undergoes partial biotransformation, and is excreted primarily into the feces.U

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M. Kraml

A semi-automated determination of phospholipids

A Novel Mode of Inhibition of Cholesterol Biosynthesis

Cell-free protein synthesis from non-growing, stressed Escherichia coli

A High-Performance Liquid Chromatographic Method for the Simultaneous Determination of Venlafaxine and O-Desmethylvenlafaxine in Biological Fluids

The Metabolic Disposition of Etodolac in Rats, Dogs, and Man

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