Polylactate (PLA) is synthesized as a representative bio-based polyester by the chemo-bio process on the basis of metal catalystmediated chemical polymerization of lactate (LA) supplied by microbial fermentation. To establish the one-step microbial process for synthesis of LA-based polyesters, we explored whether polyhydroxyalkanoate (PHA) synthase would exhibit polymerizing activity toward a LA-coenzyme A (CoA), based on the fact that PHA monomeric constituents, especially 3-hydroxybutyrate (3HB), are structurally analogous to LA. An engineered PHA synthase was discovered as a candidate by a two-phase in vitro polymerization system previously developed. An LA-CoA producing Escherichia coli strain with a CoA transferase gene was constructed, and the generation of LA-CoA was demonstrated by capillary electrophoresis/MS analysis. Next, when the engineered PHA synthase gene was introduced into the resultant recombinant strain, we confirmed the one-step biosynthesis of the LA-incorporated copolyester, P(6 mol% LA-co-94 mol% 3HB), with a number-average molecular weight of 1.9 ؋ 10 5 , as revealed by gel permeation chromatography, gas chromatography/MS, and NMR.lactate coenzyme A ͉ polyhydroxyalkanoate synthase ͉ substrate specificity ͉ CoA transferase ͉ enzyme engineering T he current polymer materials in common use are nearly all derived from petrochemical sources, and the industry is a significant contributor to greenhouse gas emissions, particularly during the processes of production and incineration of plastics. At present, the development of nonpetrochemical sources for plastic has focused on renewable resources, such as sugars, plant oils, and even CO 2 to replace diminishing supplies of fossil fuel. Polylactate (PLA) is a representative bio-based polyester, which is chemically synthesized by ring-opening polymerization of a cyclic diester (lactide) of lactic acid (LA), produced by microbial fermentation (the left portion in Fig. 1) (1, 2). By introducing variations in molecular weight and crystallinity, PLA is turned into highly valuable materials for biomedical, food, and generalpurpose applications, as described in numerous patents. Thus, PLA combines inexpensive large-scale fermentation with chemical processing capacity to produce a value-added polymer product. However, as the chemo-process of PLA can be carried out via harmful metal catalysts with high reaction velocities, it often leaves chemical residues that are subject to health and safety concerns. The paradigm shift from the chemo-process to the bio-process for PLA production is thus preferable to overcome this problem.The complete biosynthesis of PLA is an enormous challenge for both academic research and industry. For this purpose, a ''LA-polymerizing enzyme,'' which can function as an alternative to a metal catalyst, would be desired to establish the bio-process, as shown in Fig. 1. The simplest strategy would be the discovery of a PLA-producing micro-organism, but this approach has not succeeded yet. Thus, we focused on the microbial biosynthetic...
The structural gene for thermostable farnesyl diphosphate synthase from Bacillus stearothermophilus was cloned, sequenced, and overexpressed in Escherichia coli cells. A 1,260-nucleotide sequence of the cloned fragment was determined. This sequence specifies an open reading frame of 891 nucleotides for farnesyl diphosphate synthase. The deduced amino acid sequence shows a 42% similarity with that of E. coli FPP synthase [Fujisaki et al. (1990) J. Biochem. 108, 995-1000]. Comparison with prenyltransferases from a wide range of organisms, from bacteria to human, revealed the presence of seven highly conserved regions. In contrast to thermolabile prenyltransferases, which have four to six cysteine residues, the thermostable farnesyl diphosphate synthase carries only two cysteine residues. This enzyme is also unique in that some of the amino acids that are fully conserved in equivalents from other sources are replaced by functionally different amino acids. Construction of an overproducing strain provided a sufficient supply of this enzyme and it was purified to homogeneity. The purified recombinant enzyme is immunochemically identical with the native B. stearothermophilus enzyme, and it is not inactivated even after treatment at 65 degrees C for 70 min.
(E, E, E)-Geranylgeraniol (GGOH) is a valuable starting material for perfumes and pharmaceutical products. In the yeast Saccharomyces cerevisiae, GGOH is synthesized from the end products of the mevalonate pathway through the sequential reactions of farnesyl diphosphate synthetase (encoded by the ERG20 gene), geranylgeranyl diphosphate synthase (the BTS1 gene), and some endogenous phosphatases. We demonstrated that overexpression of the diacylglycerol diphosphate phosphatase (DPP1) gene could promote GGOH production. We also found that overexpression of a BTS1-DPP1 fusion gene was more efficient for producing GGOH than coexpression of these genes separately. Overexpression of the hydroxymethylglutaryl-coenzyme A reductase (HMG1) gene, which encodes the major rate-limiting enzyme of the mevalonate pathway, resulted in overproduction of squalene (191.9 mg liter ؊1 ) rather than GGOH (0.2 mg liter ؊1 ) in test tube cultures. Coexpression of the BTS1-DPP1 fusion gene along with the HMG1 gene partially redirected the metabolic flux from squalene to GGOH. Additional expression of a BTS1-ERG20 fusion gene resulted in an almost complete shift of the flux to GGOH production (228.8 mg liter ؊1 GGOH and 6.5 mg liter ؊1 squalene). Finally, we constructed a diploid prototrophic strain coexpressing the HMG1, BTS1-DPP1, and BTS1-ERG20 genes from multicopy integration vectors. This strain attained 3.31 g liter ؊1 GGOH production in a 10-liter jar fermentor with gradual feeding of a mixed glucose and ethanol solution. The use of bifunctional fusion genes such as the BTS1-DPP1 and ERG20-BTS1 genes that code sequential enzymes in the metabolic pathway was an effective method for metabolic engineering.(E,E,E)-Geranylgeraniol (GGOH) can be used as an important ingredient for perfumes and as a desirable raw material for synthesizing vitamins A and E (4, 13). It is also known to induce apoptosis in various cancer and tumor cell lines (24,36). GGOH is the dephosphorylated derivative of (E,E,E)-geranylgeranyl diphosphate (GGPP) (Fig. 1). GGPP is a significant intermediate of ubiquinone and carotenoid biosyntheses, especially in carotenoid-producing microorganisms and plant cells. It is also utilized as the lipid anchor of geranylgeranylated proteins. In the yeast Saccharomyces cerevisiae, GGPP is synthesized by GGPP synthase (GGPS), encoded by the BTS1 gene, which catalyzes the condensation of farnesyl diphosphate (FPP) and isopentenyl diphosphate (IPP) rather than the successive addition of IPP molecules to dimethylallyl diphosphate, geranyl diphosphate, and FPP that is detected in mammalian tissues (14). Biologically synthesized GGOH comprises only (E,E,E)-geometric isomers, and only the (E,E,E)-isomers have significant biological activities (23). The chemically synthesized form is usually obtained as mixtures of (E)-and (Z)-isomers and thus has lower potency. Therefore, there is a greater possibility of attaining efficient production of (E,E,E)-GGOH through fermentative production.Some yeast strains accumulate ergosterol up to 4.6% d...
Farnesyl diphosphate synthases have been shown to possess seven highly conserved regions (I-VII) in their amino acid sequences [Koyama et al. (1993) J. Biochem. (Tokyo) 113, 355-363]. Site-directed mutants of farnesyl diphosphate synthase from Bacillus stearothermophilus were made to evaluate the roles of the conserved aspartic acids in region VI and lysines in regions I, V, and VI. The aspartate at position 224 was changed to alanine or glutamate (mutants designated as D224A and D224E, respectively); aspartates at positions 225 and 228 were changed to isoleucine and alanine (D225I, D228A); lysine at position 238 was changed to either alanine or arginine (K238A, K238R). The lysines at positions 47 and 183 were changed to isoleucine and alanine (K471, K183A), respectively. Kinetic analyses of the wild-type and mutant enzymes indicated that the mutagenesis of Asp-224 and Asp-225 resulted in a decrease of Kcat values of approximately 10(4)- to 10(5)-fold compared to the wild type. On the other hand, D228A showed a Kcat value approximately one-tenth of that of the wild type, and the k(m) value for isopentenyl diphosphate increased approximately 10-fold. Both K471 and K183A showed k(m) values for isopentenyl diphosphate 20-fold larger and kcat values 70-fold smaller than the wild type. These results suggest that the two conserved lysines in regions I and V contribute to the binding of isopentenyl diphosphate and that the first and the second aspartates in region VI are involved in catalytic function. Aspartate-228 is also important for the binding of isopentenyl diphosphate rather than for catalytic reaction.
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