Project description:Pyruvate dehydrogenase (PDH) catalyses the irreversible decarboxylation of pyruvate to acetyl-CoA, which feeds the tricarboxylic acids cycle. We analysed how the lack of PDH affects Pseudomonas putida metabolism. Inactivating PDH generated a strain that can no longer use compounds whose assimilation converges into pyruvate, including sugars and several amino acids. Compounds generating acetyl-CoA supported growth. Interestingly, inactivation of PDH led to loss of the carbon catabolite repression (CCR) effect that inhibits the assimilation of non-preferred compounds when other preferred ones are also present. P. putida can degrade many aromatic compounds, most of which generate acetyl-CoA, and is a useful bacterium for biotransformation and bioremediation processes. However, the genes involved in these metabolic pathways are frequently inhibited by CCR when substrates such as glucose or mixtures of amino acids are also present. Our results show that the PDH-null strain could efficiently degrade aromatic compounds in the presence of other preferred substrates, a condition in which the wild type strain could not mineralise them. Since lack of PDH limits the assimilation of many sugars and amino acids, and relieved CCR, the PDH-null strain could be useful in biotransformation or bioremediation processes that imply growth with mixtures of preferred substrates and aromatic compounds.

Project description:This study uses iTRAQ based proteomics approach to understand the cellular metabolic machineries present within the Clostridium strain BOH3 (discovered by our group) which can simultaneously utilise both glucose (six carbon sugar) and xylose (five carbon sugar) to produce butanol and riboflavin.

Project description:Investigation of whole genome gene expression level changes in a Escherichia coli MG1655 K-12 ∆arcA mutant, compared to the wild-type strain. The mutations engineered into this strain produce a strain lacking the ArcA protein. The results are further described in the manuscript The response regulator ArcA uses a diverse binding site architechture to globally regulate carbon oxidation in E. coli

Project description:Methanogen that uses methanol and hydrogen to produce methane

Project description:Methanogen that uses methanol and hydrogen to produce methane

Project description:Production of cephalosporin precursors with recombinant strains of Penicillium chrysogenum has improved the economics and reduced the environmental impact of industrial cephalosporin production. The engineered P. chrysogenum strains used in these processes express heterologous enzymes that convert the intermediate acyl-6-aminopenicillanic acid into different tailor-made compounds. Activation of the cephalosporin side-chain precursor to its corresponding CoA thioester is an essential step for its incorporation into the β-lactam backbone. To identify the acyl-CoA ligase involved in activation of adipic acid, a frequently used cephalosporin side-chain precursor, we searched the genome of P.chrysogenum for putative structural genes encoding acyl-CoA ligases. Chemostat-based transcriptome analysis was then used to identify the one presenting the highest expression level when cells were grown in the presence of adipic acid. Deletion of the gene renamed aclA, led to a 32% decreased specific rate of adipic acid consumption and a three-fold reduction of adipoyl-6-aminopenicillanic acid levels in chemostat cultures of P. chrysogenum, but did not affect penicillin production. After cloning the gene and overexpressing it in Escherichia coli, its purified protein product was shown to have adipoyl-CoA ligase, but no phenylacetyl-CoA ligtase activity. Finally, by fusing the gene to a sequence encoding cyan fluorescent protein, the resulting fusion protein localized to microbodies, which indicates that activation of the side-chain precursor adipic acid takes place in this compartment, where also the subsequent acyltransferase step takes place. Identification and functional characterization of this adipoyl-CoA ligtase gene may aid in developing future metabolic engineering strategies for improving the production of different cephalosporins.

Project description:Medium- and branched-chain diols and amino alcohols are important industrial solvents, polymer building blocks, cosmetics and pharmaceutical ingredients, yet biosynthetically challenging to produce. Here, we present a novel approach utilising a modular polyketide synthase (PKS) platform for the efficient production of these compounds. This platform takes advantage of a versatile loading module from the rimocidin PKS and NADPH-dependent terminal thioreductases (TRs), previously untapped in engineered PKSs. Reduction of the terminal aldehyde with specific alcohol dehydrogenases enables production of diols, oxidation enables production of hydroxy acids, and transamination with specific transaminases enables production of various amino alcohols. Furthermore, replacement of the malonyl-coenzyme A (CoA)–specific acyltransferase (AT) in the extension module with methyl- or ethylmalonyl-CoA–specific ATs enables production of branched-chain diols and amino alcohols. In total, we demonstrated production of nine 1,3-diols (including the difficult-to-produce insect repellent and cosmetic ingredient 2-ethyl-1,3-hexanediol), six amino alcohols, and two carboxylic acids using our PKS platform in Streptomyces albus. Finally, tuning production of the PKS acyl-CoA substrates enabled production of high titers of specific diols and amino alcohols (1 g/L diol titer in shake flasks), demonstrating high tunability and efficiency of the platform.

Project description:Fatty acid synthesis is closely linked to nutrient availability and cellular energetic status. The committed step in fatty acid synthesis is the acetyl CoA carboxylase. Eukaryotes have two genes encoding acetyl CoA carboxylases, one encoding a cytosolic enzyme and another coding for a mitochondrial enzyme. They catalyze the synthesis of malonyl CoA in the cytosol and the mitochondria, respectively. While cytosolic malonyl CoA is the precursor for fatty acid synthesis, mitochondrial malonyl CoA controls the transfer of fatty acyl group into the mitochondria by inhibiting carnitine/palmitoyl transferase activity and thus, regulates β-oxidation. In Saccharomyces cerevisiae, β-oxidation is restricted to the peroxisomes, raising the question of the function of the mitochondrial isoform (HFA1). In this study, we replaced the cytosolic Acc1 with Hfa1 expressed in the cytosol by removing the mitochondrial leader peptide, under control of the HFA1 promoter. We studied fatty acid synthesis and transcription profiles in this strain during starvation for carbon or nitrogen, using glucose or ethanol as the carbon source. Under all the conditions studied, the key sensor of energetic status, Snf1, was activated, indicating active inhibition of fatty acid synthesis. The pool size of fatty acids was smaller when Acc1 was replaced with truncated Hfa1 for fatty acid synthesis. Yet, the transcription profiles were similar in both the cases. These results point towards the conclusion that Hfa1 is either catalytically less efficient or it is more sensitive to inhibition by Snf1. Gene expression from a strain of Saccharomyces cerevisiae where cytosolic fatty acid synthesis occurs by mitochondrial acetyl CoA carboxylase (without its mitochondrial leader peptide) is compared with that in a reference strain while growing in chemostats on carbon or nitrogen starvation using glucose or ethanol as the carbon source. There are two strains (reference or mutant), two carbon sources (glucose or ethanol) and two limitations (carbon or nitrogen), resulting in 8 comparisons. Each array was performed in duplicate, resulting in 16 CEL files. Growth was limited by either carbon or nitrogen. When carbon was the limited nutrient, we tested growth on either glucose or ethanol (both using ammonium sulfate as the nitrogen source). When ammonium sulfate was limiting, we used either glucose or ethanol as the carbon source.

Project description:Uses methane as sole carbon and energy source

Project description:Various environmental bacteria were adapted to the presence of toxic and recalcitrant organic solvents. Cupriavidus metallidurans CH34, a β-proteobacterium that was found in industrial environments is known as a bacterial model to study heavy metal resistance. Interestingly, genome screening of CH34 also reveals the existence of genes involved in the degradation of recalcitrant organic solvents, such acetone and aromatic compounds. Here, we showed that this bacterium could resist a large variety of organic solvents, and was also able to metabolize some of them. In particular, investigations were focused on acetone and isopropanol catabolism. Integrative studies based on transcriptomic (DNA microarrays), proteomic (2D-DIGE and Isotope-Coded Protein Label technology) and biochemical analyses (enzyme purification and characterization) showed a similar catabolic pathway for both molecules which involved the AcxABC acetone carboxylase. First, isopropanol is oxidized into acetone by the Adh alcohol dehydrogenase. Acetoacetate production from acetone is then catalyzed by the acetone carboxylase. The generated acetoacetate molecules are then transformed by the PacIJ 3-oxoacid CoA-transferase, to acetoacetyl-CoA and succinate. Finally, an acetyl-CoA acetyltransferase catalyses the hydrolysis of acetoacetyl-CoA into 2 acetyl-CoA that are introduced into the glyoxylate cycle. As demonstrated, key enzymes of the acetone/isopropanol catabolism (encoded by acx and ald genes) are under the control of a σ54-dependent RNA polymerase. Moreover, the catabolic pathway involved in acetone and isopropanol consumption was repressed when gluconate was given as alternative carbon substrate, displaying a new example of diauxie. The results presented here provide a comprehensive picture of acetone and isopropanol biodegradation in Cupriavidus metallidurans CH34 and strongly support the fact that CH34 can be considered as a solvent tolerant bacterium. Two-condition experiments. Comparing samples after induction with acetone versus non-induced samples. Biological triplicate. Each array contains 3 technical replicates.