Efficient production of (2S)-flavanones by Escherichia coli containing an artificial biosynthetic gene cluster

For the fermentative production of plant-specific flavanones (naringenin, pinocembrin) by Escherichia coli, a plasmid was constructed which carried an artificial biosynthetic gene cluster, including PAL encoding a phenylalanine ammonia-lyase from a yeast, ScCCL encoding a cinnamate/coumarate:CoA ligase from the actinomycete Streptomyces coelicolor A3(2), CHS encoding a chalcone synthase from a licorice plant and CHI encoding a chalcone isomerase from the Pueraria plant. The recombinant E. coli cells produced (2S)-naringenin from tyrosine and (2S)-pinocembrin from phenylalanine. When the two subunit genes of acetyl-CoA carboxylase from Corynebacterium glutamicum were expressed under the control of the T7 promoter and the ribosome-binding sequence in the recombinant E. coli cells, the flavanone yields were greatly increased, probably because enhanced expression of acetyl-CoA carboxylase increased a pool of malonyl-CoA that was available for flavanone synthesis. Under cultural conditions where E. coli at a cell density of 50 g/l was incubated in the presence of 3 mM tyrosine or phenylalanine, the yields of naringenin and pinocembrin reached about 60 mg/l. The fermentative production of flavanones in E. coli is the first step in the construction of a library of flavonoid compounds and un-natural flavonoids in bacteria.     

Expression of an artificial yeast TRP-gene cluster in yeast and Escherichia coli

Summary All five tryptophan biosynthetic genes of Saccharomyces cerevisiae were unified on plasmid pME554, which is based on 2 m DNA and pBR322 sequences allowing for autonomous replication in yeast and E. coli. Homologous and heterologous expression of this artificial yeast TRP-gene cluster was studied. Plasmid pME554 allowed for nearly normal growth of a yeast strain bearing auxotrophic mutations in all five TRP-genes. The plasmid-borne genes TRP2 to TRP5 were expressed and regulated normally in the frame of the general control. Gene TRP1, carried on an EcoRI/BglII fragment lacking the ARS1 function, was expressed poorly and did not respond to the general control like the chromosomally-borne TRP1 gene.Plasmid pME554 allowed for poor growth of E. coli strain W3110 tna ^– trpEA2 on minimal medium. Marked stimulation was observed, however, when anthranilic acid or indole were added. Accordingly, poor expression of the first Trp-enzyme anthranilate synthase and the last enzyme tryptophan synthase was found, whereas the other three genes were moderately well expressed in E. coli.Abbreviations bp basepair - kb kilobase     

Expression of the synthetic gene of an artificial DDT-binding polypeptide in Escherichia coli

This paper reports the expression of an artificial functional polypeptide in bacteria. The gene of a designed 24-residue DDT-binding polypeptide (DBP) was inserted between the BamHI and PstI cleavage sites of plasmid pUR291. The hybrid plasmid, pUR291-DBP, was cloned in Escherichia coli JM109. After induction by isopropyl-beta-D-thiogalactopyranoside a fusion protein was expressed in which DBP was linked to the COOH-terminus of beta-galactosidase. DBP, which is stable to trypsin, was obtained by tryptic digestion of the fusion protein and subsequent fractionation of the tryptic peptides by reversed-phase h.p.l.c. Recombinant and chemically synthesized DBP showed identical chromatographic properties, amino acid composition, and chymotryptic digestion patterns. Both the beta-galactosidase-DBP fusion and isolated recombinant DBP bound DDT. The fusion protein was 25 times as potent as the designed 24-residue DBP in activating a cytochrome P-450 model system using equimolar catalytic amounts of the two proteins.     

Increasing l-threonine production in Escherichia coli by overexpressing the gene cluster phaCAB

Journal of Industrial Microbiology & Biotechnology - l-Threonine is an important branched-chain amino acid and could be applied in feed, drugs, and food. In this study, l-threonine production...     

The metD D-methionine transporter locus of Escherichia coli is an ABC transporter gene cluster

The metD D-methionine transporter locus of Escherichia coli was identified as the abc-yaeE-yaeC cluster (now renamed metNIQ genes). The abc open reading frame is preceded by tandem MET boxes bracketed by the -10 and -35 boxes of a promoter. The expression driven by this promoter is controlled by the MetJ repressor and the level of methionine.     

The entD gene of the Escherichia coli K12 enterobactin gene cluster

The Escherichia coli entD gene encodes a product necessary for the synthesis of the iron-chelating and transport molecule enterobactin (Ent); cells harbouring entD mutations fail to grow in iron-deficient environments. For unknown reasons, it has not been possible to identify the entD product. The nucleotide sequence of the entD region has now been determined. An open reading frame extending in the same direction as the adjacent fepA gene and capable of encoding an approximately 24 kDa polypeptide was found; it contained a high percentage of rare codons and two possible translational start sites. Complementation data suggested that EntD proteins truncated at the carboxy terminus retain some activity. Two REP sequences were present upstream of entD and an IS186 sequence was observed downstream. RNA dot-blot hybridizations demonstrated that entD is transcribed from the strand predicted by the sequencing results. An entD-lacZ recombinant plasmid was constructed and shown to express low amounts of a fusion protein of the anticipated size (approximately 125 kDa). The evidence suggests a number of possible explanations for difficulties in detecting the entD product. Sequence data indicate that if entD has its own promoter, it is weak; the REP sequences suggest that entD mRNA may be destabilized; and translation may be slow because of the frequency of rare codons and a possible unusual start codon (UUG). The data are also consistent with previous evidence that the entD product is unstable.     

Characterization and sequence of the Escherichia coli panBCD gene cluster

Abstract A metabolic key enzyme malate dehydrogenase (MDH) was purified from a deep-sea psychrophilic bacterium, Vibrio sp. strain no. 5710. The enzyme displayed an optimal activity shifted toward lower temperature and a pronounced heat lability. A gene encoding this enzyme was isolated and cloned. Recombinant Escherichia coli cells harboring the isolated clone expressed MDH activity with temperature stability identical to that of the parental psychrophile. Nucleotide sequencing of the gene revealed that its primary sequence was similar to that of a mesophile E. coli MDH (78% amino acid identity), for which the three-dimensional structure is known. The enzyme is thus suitable for the analysis of molecular adaptations to low temperatures.     

Biosynthesis of plant-specific stilbene polyketides in metabolically engineered Escherichia coli

Background  

Phenylpropanoids are the precursors to a range of important plant metabolites such as the cell wall constituent lignin and the secondary metabolites belonging to the flavonoid/stilbene class of compounds. The latter class of plant natural products has been shown to function in a wide range of biological activities. During the last few years an increasing number of health benefits have been associated with these compounds. In particular, they demonstrate potent antioxidant activity and the ability to selectively inhibit certain tyrosine kinases. Biosynthesis of many medicinally important plant secondary metabolites, including stilbenes, is frequently not very well understood and under tight spatial and temporal control, limiting their availability from plant sources. As an alternative, we sought to develop an approach for the biosynthesis of diverse stilbenes by engineered recombinant microbial cells.     

Fumarase a from Escherichia coli: purification and characterization as an iron-sulfur cluster containing enzyme.

It has been shown previously that Escherichia coli contains three fumarase genes designated fumA, fumB, and fumC. The gene products fumarases A, B, and C have been divided into two classes. Class I contains fumarases A and B, which have amino acid sequences that are 90% identical to each other, but have almost no similarity to the sequence of porcine fumarase. Class II contains fumarase C and porcine fumarase, which have amino acid sequences 60% identical to each other [Woods, S.A., Schwartzbach, S.D., & Guest, J.R. (1988) Biochim. Biophys. Acta 954, 14-26]. In this work it is shown that purified fumarase A contains a [4Fe-4S] cluster. This conclusion is based on the following observations. Fumarase A contains 4 Fe and 4 S2- per mole of protein monomer. (The mobility of fumarase A in native polyacrylamide gel electrophoresis and the elution volume on a gel permeation column indicate that it is a homodimer.) Its visible and circular dichroism spectra are characteristic of proteins containing an Fe-S cluster. Fumarase A can be reduced to an EPR active-state exhibiting a spectrum consisting of a rhombic spectrum at high fields (g-values = 2.03, 1.94, and 1.88) and a broad peak at g = 5.4. Upon addition of substrate, the high field signal shifts upfield (g-values = 2.035, 1.92, and 1.815) and increases in total spins by 8-fold, while the g = 5.4 signal disappears.(ABSTRACT TRUNCATED AT 250 WORDS)     

Molecular cloning of the Escherichia coli B L-fucose-D-arabinose gene cluster.

To metabolize the uncommon pentose D-arabinose, enteric bacteria often recruit the enzymes of the L-fucose pathway by a regulatory mutation. However, Escherichia coli B can grow on D-arabinose without the requirement of a mutation, using some of the L-fucose enzymes and a D-ribulokinase that is distinct from the L-fuculokinase of the L-fucose pathway. To study this naturally occurring D-arabinose pathway, we cloned and partially characterized the E. coli B L-fucose-D-arabinose gene cluster and compared it with the L-fucose gene cluster of E. coli K-12. The order of the fucA, -P, -I, and -K genes was the same in the two E. coli strains. However, the E. coli B gene cluster contained a 5.2-kb segment located between the fucA and fucP genes that was not present in E. coli K-12. This segment carried the darK gene, which encodes the D-ribulokinase needed for growth on D-arabinose by E. coli B. The darK gene was not homologous with any of the L-fucose genes or with chromosomal DNA from other D-arabinose-utilizing bacteria. D-Ribulokinase and L-fuculokinase were purified to apparent homogeneity and partially characterized. The molecular weights, substrate specificities, and kinetic parameters of these two enzymes were very dissimilar, which together with DNA hybridization analysis, suggested that these enzymes are not related. D-Arabinose metabolism by E. coli B appears to be the result of acquisitive evolution, but the source of the darK gene has not been determined.     

Production L-tryptophan by Escherichia coli cells

Whole cells of Escherichia coli B 10 having high tryptophan synthetase activity were used directly as an enzyme source to produce L-tryptophan from indole and L- or D,L-serine. This strain is tryptophan auxotrophic, which is tryptophanase negative and, in addition, L- and D-serine deaminase negative under production conditions. To avoid inhibition of tryptophan synthetase by a high concentration of indole, nonaqueous organic solvents, Amberlite XAD-2 adsorbent, and nonionic detergents were used as reservoirs of indole in the reaction mixture for the production of L-tryptophan. As a result, different effects were observed on the production of L-tryptophan. Particularly, among the nonionic detergents, Triton X-100 was very efficient. Using Triton X-100 for production of L-tryptophan from indole and L- or D,L-serine by whole cells of Escherichia coli B 10, 14.14 g/100 mL and 14.2 g/100 mL of L-tryptophan were produced at 37 degrees C for 60 h.     

Hydrogen production by Escherichia coli containing a cloned hydrogenase gene from Citrobacter freundii

Two hydrogenase genes of Citrobacter freundii complementing different Escherichia coli hyd mutations were cloned on the multicopy-plasmid pBR322. Recombinant plasmids pCBH2 and pCFH1 were obtained. Since hydrogenase activities of E. coli transformant HK-8 (pCBH2) and HK-7 (pCFH1) were much the same as E. coli C600 (wild type cells), the reduction in DNA size of recombinant plasmid pCBH2 (10.7 kb) was investigated. Reduced recombinant plasmids pCBH4 (6.2 kb) and pCBH6 (5.7 kb) were obtained, and a hydrogenase gene was found to be located on the 2.35 kb fragment between AvaI and EcoRI sites. Hydrogenase activity and hydrogen-evolving activity of E. coli HK-8 (pCBH4 or pCBH6) from sodium formate, sodium pyruvate or glucose were approximately 2-fold higher than those of E. coli C600 (wild type cells).On the other hand, a reduced recombinant plasmid pCBH10 (6.0 kb), which contained the adjacent DNA fragment (2.15 kb) to a hydrogenase gene, was obtained. Hydrogenase activity of E. coli C600 harboring pCBH10 was half that of E. coli C600. From these results we estimate that in plasmid pCBH2, the repressor gene suppressing the synthesis of hydrogenase might have been cloned together with a hydrogenase gene.