High-level production of valine by expression of the feedback inhibition-insensitive acetohydroxyacid synthase in Saccharomyces cerevisiae.

Valine, which is one of the branched-chain amino acids (BCAAs) essential for humans, is widely used in animal feed, dietary supplements and pharmaceuticals. At the commercial level, valine is usually produced by bacterial fermentation from glucose. However, valine biosynthesis can also proceed in the yeast Saccharomyces cerevisiae, which is a useful microorganism in fermentation industry. In S. cerevisiae, valine biosynthesis is regulated by valine itself via the feedback inhibition of acetohydroxyacid synthase (AHAS), which consists of two subunits, the catalytic subunit Ilv2 and the regulatory subunit Ilv6. In this study, to improve the valine productivity of yeast cells, we constructed several variants of Ilv6 by introducing amino acid substitutions based on a protein sequence comparison with the AHAS regulatory subunit of E. coli. Among them, we found that the Asn86Ala, Gly89Asp and Asn104Ala variants resulted in approximately 4-fold higher intracellular valine contents compared with those in cells with the wild-type Ilv6. The computational analysis of Ilv6 predicted that Asn86, Gly89 and Asn104 are located in the vicinity of a valine-binding site, suggesting that amino acid substitutions at these positions induce conformational change of the valine-binding site. To test the effects of these variants on AHAS activity, both recombinant Ilv2 and Ilv6 were purified and reconstituted in vitro. The Ilv6 variants were much less sensitive to feedback inhibition by valine than the wild-type Ilv6. Only a portion of the amino acid changes identified in the E. coli AHAS regulatory subunit IlvH enhanced the valine synthesis, suggesting structural and/or functional differences between the S. cerevisiae and E. coli AHAS regulatory subunits. It should also be noted that these amino acid substitutions did not affect the intracellular pools of the other BCAAs, leucine and isoleucine. The approach described here could be a practical method for the development of industrial yeast strains with high-level production of valine or isobutanol.

Acetolactate synthase (AlsS) in Bacillus licheniformis WX-02: enzymatic properties and efficient functions for acetoin/butanediol and L-valine biosynthesis.

Acetolactate synthase catalyzes two molecules of pyruvates to form α-acetolactate, which is further converted to acetoin and 2,3-butanediol. In this study, by heterologous expression in Escherichia coli, the enzymatic properties of acetolactate synthase (AlsS) from Bacillus licheniformis WX-02 were characterized. Its K m and k cat for pyruvate were 3.96 mM and 514/s, respectively. It has the optimal activity at pH 6.5, 37 °C and was feedback inhibited by L-valine, L-leucine and L-isoleucine. Furthermore, the alsS-deficient strain could not produce acetoin, 2,3-butanediol, and L-valine, while the complementary strain was able to restore these capacities. The alsS overexpressing strain produced higher amounts of acetoin/2,3-butanediol (57.06 g/L) and L-valine (2.68 mM), which were 10.90 and 92.80% higher than those of the control strain, respectively. This is the first report regarding the in-depth understanding of AlsS enzymatic properties and its functions in B. licheniformis, and overexpression of AlsS can effectively improve acetoin/2,3-butanediol and L-valine production in B. licheniformis. We envision that this AlsS can also be applied in the improvement of acetoin/2,3-butanediol and L-valine production in other microbes.

Temperature-dependent acetoin production by Pyrococcus furiosus is catalyzed by a biosynthetic acetolactate synthase and its deletion improves ethanol production.

The hyperthermophilic archaeon, Pyrococcus furiosus, grows optimally near 100°C by fermenting sugars to acetate, carbon dioxide and molecular hydrogen as the major end products. The organism has recently been exploited to produce biofuels using a temperature-dependent metabolic switch using genes from microorganisms that grow near 70°C. However, little is known about its metabolism at the lower temperatures. We show here that P. furiosus produces acetoin (3-hydroxybutanone) as a major product at temperatures below 80°C. A novel type of acetolactate synthase (ALS), which is involved in branched-chain amino acid biosynthesis, is responsible and deletion of the als gene abolishes acetoin production. Accordingly, deletion of als in a strain of P. furiosus containing a novel pathway for ethanol production significantly improved the yield of ethanol. These results also demonstrate that P. furiosus is a potential platform for the biological production of acetoin at temperatures in the 70-80°C range.

Enhanced production of 2,3-butanediol by overexpressing acetolactate synthase and acetoin reductase in Klebsiella pneumoniae.

Mutants with overexpression of α-acetolactate synthase (ALS), α-acetolactate decarboxylase, and acetoin reductase (AR), either individually or in combination, were constructed to improve 2,3-butanediol (2,3-BD) production in Klebsiella pneumoniae. The recombinant strains were characterized in terms of the enzyme activity, 2,3-BD yield, and expression levels. The recombinant K. pneumoniae strain (KG-rs) that overexpressed both ALS and AR showed an improved 2,3-BD yield. When cultured in the media with five different carbon sources (glucose, galactose, fructose, sucrose, and lactose), the mutant exhibited higher 2,3-BD productivity and production than the parental strain in all the tested carbon sources except for lactose. The 2,3-BD production of KG-rs in a batch fermentation with glucose as the carbon source was 12% higher than that of the parental strain.

Metabolic engineering of a Saccharomyces cerevisiae strain capable of simultaneously utilizing glucose and galactose to produce enantiopure (2R,3R)-butanediol.

2,3-Butanediol (BDO) is an important chemical with broad industrial applications and can be naturally produced by many bacteria at high levels. However, the pathogenicity of these native producers is a major obstacle for large scale production. Here we report the engineering of an industrially friendly host, Saccharomyces cerevisiae, to produce BDO at high titer and yield. By inactivation of pyruvate decarboxylases (PDCs) followed by overexpression of MTH1 and adaptive evolution, the resultant yeast grew on glucose as the sole carbon source with ethanol production completely eliminated. Moreover, the pdc- strain consumed glucose and galactose simultaneously, which to our knowledge is unprecedented in S. cerevisiae strains. Subsequent introduction of a BDO biosynthetic pathway consisting of the cytosolic acetolactate synthase (cytoILV2), Bacillus subtilis acetolactate decarboxylase (BsAlsD), and the endogenous butanediol dehydrogenase (BDH1) resulted in the production of enantiopure (2R,3R)-butanediol (R-BDO). In shake flask fermentation, a yield over 70% of the theoretical value was achieved. Using fed-batch fermentation, more than 100g/L R-BDO (1100mM) was synthesized from a mixture of glucose and galactose, two major carbohydrate components in red algae. The high titer and yield of the enantiopure R-BDO produced as well as the ability to co-ferment glucose and galactose make our engineered yeast strain a superior host for cost-effective production of bio-based BDO from renewable resources.

Mechanisms of resistance to acetolactate synthase-inhibiting herbicides in populations of Apera spica-venti from the Czech Republic.

BACKGROUND: This study investigates the mechanisms of resistance to acetolactate synthase-inhibiting herbicides in populations of Apera spica-venti (L.) P.B. from the Czech Republic. RESULTS: The proportion of resistance due to mutant acetolactate synthase (ALS) alleles was estimated by genotyping individuals from each of three populations for the eight ALS mutations known to confer resistance. Four resistance-conferring ALS mutations were identified: Pro-197-Ala, Pro-197-Thr, Trp-574-Leu and previously unreported Trp-574-Met substitution. Two populations (R1, R3) have amino acid substitution at positions Pro-197 and Trp-574. Individuals from the R3 population had two different resistance alleles. In the R2 population, only the resistant Trp-574-Met substitution was detected. Ten other single point mutations were identified, but these were not related to resistance. The cytochrome malathion decreased chlorsulfuron resistance in the resistant populations that were examined. Although malathion increased mortality, the GR50 values were too high to conclude that non-target-based mechanism was the main one for the resistance in Apera spica-venti populations tested in this study. CONCLUSIONS: Individuals of Apera spica-venti populations tested in this study possess the target-site ALS resistance mutation and an additional so far unknown resistance mechanism(s).

Isobutanol production in engineered Saccharomyces cerevisiae by overexpression of 2-ketoisovalerate decarboxylase and valine biosynthetic enzymes.

Engineering of Saccharomyces cerevisiae to produce advanced biofuels such as isobutanol has received much attention because this yeast has a natural capacity to produce higher alcohols. In this study, construction of isobutanol production systems was attempted by overexpression of effective 2-keto acid decarboxylase (KDC) and combinatorial overexpression of valine biosynthetic enzymes in S. cerevisiae D452-2. Among the six putative KDC enzymes from various microorganisms, 2-ketoisovalerate decarboxylase (Kivd) from L. lactis subsp. lactis KACC 13877 was identified as the most suitable KDC for isobutanol production in the yeast. Isobutanol production by the engineered S. cerevisiae was assessed in micro-aerobic batch fermentations using glucose as a sole carbon source. 93 mg/L isobutanol was produced in the Kivd overexpressing strain, which corresponds to a fourfold improvement as compared with the control strain. Isobutanol production was further enhanced to 151 mg/L by additional overexpression of acetolactate synthase (Ilv2p), acetohydroxyacid reductoisomerase (Ilv5p), and dihydroxyacid dehydratase (Ilv3p) in the cytosol.

Engineering Bacillus subtilis for isobutanol production by heterologous Ehrlich pathway construction and the biosynthetic 2-ketoisovalerate precursor pathway overexpression.

In the present work, Bacillus subtilis was engineered as the cell factory for isobutanol production due to its high tolerance to isobutanol. Initially, an efficient heterologous Ehrlich pathway controlled by the promoter P(43) was introduced into B. subtilis for the isobutanol biosynthesis. Further, investigation of acetolactate synthase of B. subtilis, ketol-acid reductoisomerase, and dihydroxy-acid dehydratase of Corynebacterium glutamicum responsible for 2-ketoisovalerate precursor biosynthesis showed that acetolactate synthase played an important role in isobutanol biosynthesis. The overexpression of acetolactate synthase led to a 2.8-fold isobutanol production compared with the control. Apart from isobutanol, alcoholic profile analysis also confirmed the existence of 1.21 g/L ethanol, 1.06 g/L 2-phenylethanol, as well as traces of 2-methyl-1-butanol and 3-methyl-1-butanol in the fermentation broth. Under microaerobic condition, the engineered B. subtilis produced up to 2.62 g/L isobutanol in shake-flask fed-batch fermentation, which was 21.3% higher than that in batch fermentation.

Comparative study of Chalcone synthase promoters across plant families / Estudio Comparativo de Promotores de la Chalcón Sintasa en Diferentes Familias de Plantas

In the post – genomic era the understanding of gene regulation has become a challenge and a research priority. In this research, we performed a comparative study of the regulator sequences of the chalcone synthase gene across plant families. Twenty-two sequences of chalcone synthase promoters were compared considering three regulator Cis elements: G-Box, H-Box and TATA Box. Our results show that these Cis elements are conserved among species and even at the family level. However, in some species all of the Cis elements were not found, showing that the expression and regulation of these promoters via the Cis elements can be variable. Additionally, a comparison between promoters from a species with a chalcone synthase multigene family showed that the duplicate genes are variable in the composition of the Cis elements, suggesting that these genes could be expressing in different ways.

Acetohydroxyacid synthase isozyme I from Escherichia coli has unique catalytic and regulatory properties.

AHAS I is an isozyme of acetohydroxyacid synthase which is apparently unique to enterobacteria. It has been known for over 20 years that it has many properties which are quite different from those of the other two enterobacterial AHASs isozymes, as well as from those of "typical" AHASs which are single enzymes in a given organism. These include a unique mechanism for regulation of expression and the absence of a preference for forming acetohydroxybutyrate. We have cloned the two subunits, ilvB and ilvN, of this Escherichia coli isoenzyme and examined the enzymatic properties of the purified holoenzyme and the enzyme reconstituted from purified subunits. Unlike other AHASs, AHAS I demonstrates cooperative feedback inhibition by valine, and the kinetics fit closely to an exclusive binding model. The formation of acetolactate by AHAS I is readily reversible and acetolactate can act as substrate for alternative AHAS I-catalyzed reactions.

Effects of deletions at the C-terminus of tobacco acetohydroxyacid synthase on the enzyme activity and cofactor binding.

AHAS (acetohydroxyacid synthase) catalyses the first committed step in the biosynthesis of branched-chain amino acids, such as valine, leucine and isoleucine. Owing to the unique presence of these biosynthetic pathways in plants and micro-organisms, AHAS has been widely investigated as an attractive target of several classes of herbicides. Recently, the crystal structure of the catalytic subunit of yeast AHAS has been resolved at 2.8 A (1 A=0.1 nm), showing that the active site is located at the dimer interface and is near the herbicide-binding site. In this structure, the existence of two disordered regions, a 'mobile loop' and a C-terminal 'lid', is worth notice. Although these regions contain the residues that are known to be important in substrate specificity and in herbicide resistance, they are poorly folded into any distinct secondary structure and are not within contact distance of the cofactors. In the present study, we have tried to demonstrate the role of these regions of tobacco AHAS by constructing variants with serial deletions, based on the structure of yeast AHAS. In contrast with the wild-type AHAS, the truncated mutant which removes the C-terminal lid, Delta630, and the internal deletion mutant without the mobile loop, Delta567-582, impaired the binding affinity for ThDP (thiamine diphosphate), and showed different elution profiles representing a monomeric form in gel-filtration chromatography. Our results suggest that these regions are involved in the binding/stabilization of the active dimer and ThDP binding.

Changes in mitochondrial electron partitioning in response to herbicides inhibiting branched-chain amino acid biosynthesis in soybean.

The adaptation of the respiratory metabolism in roots of soybean (Glycine max L. Merr. cv Ransom) treated with herbicides that inhibit the enzyme acetolactate synthase (ALS) was analyzed. A new gas phase dual-inlet mass spectrometry system for simultaneous measurement of 34O2 to 32O2 and O2 to N2 ratios has been developed. This system is more accurate than previously described systems, allows measurements of much smaller oxygen gradients, and, as a consequence, works with tissues that have lower respiration rates. ALS inhibition caused an increase of the alternative oxidase (AOX) protein and an accumulation of pyruvate. The combination of these two effects is likely to induce the activation of the alternative pathway and its participation in the total respiration. Moreover, the start of the alternative pathway activation and the increase of AOX protein were before the decline in the activity of cytochrome pathway. The possible role of AOX under ALS inhibition is discussed.

Effect of variation of Klebsiella pneumoniae acetolactate synthase expression on metabolic flux redistribution in Escherichia coli.

Escherichia coli strains carrying the Bacillus subtilis acetolactate synthase (ALS) gene were previously shown to produce less acetate with higher ATP yields. Metabolic flux analysis was used to show that excess pyruvate was channeled into the less inhibitory product, acetoin. To further understand the role of intrinsic enzymatic properties and the effect of variations in enzyme levels in the alternation of metabolic fluxes, we constructed a chromosomal integrant of the Klebsiella pneumoniae ALS gene. The reported in vitro Michaelis-Menten constants (K(m)) for the Bacillus and the Klebsiella ALS are 13.0 mM and 8.0 mM, respectively. Furthermore, expression of the Klebsiella ALS is under the control of an inducible trp promoter system. Shake-flask experiments showed a linear induction response (the ALS activity changes from about 9 to 223 U/mg of protein when the inducer concentration [IAA] varied from 0 to 40 mg/L). Chemostat experiments showed a similar induction response. Interactions between the branched reactions catalyzed by the PFL, LDH, and the ALS enzymes at the pyruvate node were examined. The results indicate the importance of in vivo enzyme activities in the redistribution of metabolic fluxes.

Expression vectors for Methanococcus maripaludis: overexpression of acetohydroxyacid synthase and beta-galactosidase.

A series of integrative and shuttle expression vectors was developed for use in Methanococcus maripaludis. The integrative expression vectors contained the Methanococcus voltae histone promoter and multiple cloning sites designed for efficient cloning of DNA. Upon transformation, they can be used to overexpress specific homologous genes in M. maripaludis. When tested with ilvBN, which encodes the large and small subunits of acetohydroxyacid synthase, transformants possessed specific activity 13-fold higher than that of the wild type. An expression shuttle vector, based on the cryptic plasmid pURB500 and the components of the integrative vector, was also developed for the expression of heterologous genes in M. maripaludis. The beta-galactosidase gene from Escherichia coli was expressed to approximately 1% of the total cellular protein using this vector. During this work, the genes for the acetohydroxyacid synthase (ilvBN) and phosphoenolpyruvate synthase (ppsA) were sequenced from a M. maripaludis genomic library.

Purification of Escherichia coli acetohydroxyacid synthase isoenzyme II and reconstitution of active enzyme from its individual pure subunits.

The first step in the biosynthesis of branched-chain amino acids is catalysed by acetohydroxyacid synthase (EC 4.1.3.18). The reaction involves the decarboxylation of pyruvate followed by condensation with either a second molecule of pyruvate or with 2-oxobutyrate. The enzyme requires as cofactors thiamine diphosphate, a divalent metal ion and, usually, FAD. In most bacteria the enzyme is a heterotetramer of two large and two small subunits. Escherichia coli contains three active isoenzymes and the present study concerns isoenzyme II, whose large and small subunits are encoded by the ilvG and ilvM genes respectively. Cloning these genes into a plasmid vector and overexpression in E. coli allowed a two-step purification procedure for the native enzyme to be developed. The level of expression is considerably higher from a vector that introduces a 50 residue N-terminal fusion containing an oligohistidine sequence on the large subunit. Purification to homogeneity was achieved in a single step by immobilized-metal-affinity chromatography. The kinetic properties of the native and fusion enzyme are indistinguishable with respect to the substrate pyruvate and the inhibitor chlorsulfuron. The individual subunits were expressed as oligohistidine-tagged fusion proteins and each was purified in a single step. Neither subunit alone has significant enzymic activity but, on mixing, the enzyme is reconstituted. The kinetic properties of the reconstituted enzyme are very similar to those of the fusion enzyme. It is proposed that the reconstitution pathway involves successive, and highly co-operative, binding of two small subunit monomers to a large subunit dimer. None of the cofactors is needed for subunit association although they are necessary for the restoration of enzymic activity.

Metabolic engineering of Lactococcus lactis: influence of the overproduction of alpha-acetolactate synthase in strains deficient in lactate dehydrogenase as a function of culture conditions.

The als gene for alpha-acetolactate synthase of Lactococcus lactis MG1363 was cloned on a multicopy plasmid under the control of the inducible L. lactis lacA promoter. More than a hundredfold overproduction of alpha-acetolactate synthase was obtained in L. lactis under inducing conditions as compared with that of the host strain, which contained a single chromosomal copy of the als gene. The effect of alpha-acetolactate synthase overproduction on the formation of end products in various L. lactis strains was studied under different fermentation conditions. Under aerobic conditions and with an initial pH of 6.0, overexpression of the als gene resulted in significant acetoin production that amounted to more than one-third of the pyruvate converted. However, the effect of the alpha-acetolactate synthase overproduction was even more pronounced in the lactate dehydrogenase-deficient strain L. lactis NZ2700. Anaerobic cultivation of this strain resulted in a doubling of the butanediol formation of up to 40% of the converted pyruvate. When cultivated aerobically at an initial pH of 6.8, overexpression of the als gene in L. lactis NZ2700 resulted in the conversion of more than 60% of the pyruvate into acetoin, while no butanediol was formed. Moreover, at an initial pH of 6.0, similar amounts of acetoin were obtained, but in addition approximately 20% of the pyruvate was converted into butanediol. These metabolic engineering studies indicate that more than 80% of the lactose can be converted via the activity of the overproduced alpha-acetolactate synthase in L. lactis.

Organization, inheritance and expression of acetohydroxyacid synthase genes in the cotton allotetraploid Gossypium hirsutum.

The acetohydroxyacid synthase (AHAS) gene family of the cotton AD allotetraploid Gossypium hirsutum has been cloned and characterized. We have identified six different AHAS genes from an analysis of genomic clones and Southern blots of genomic DNA. Four of the six genes are organized as tandem pairs, in which the genes are separated by only 2-3 kb. Conservation of restriction fragment length polymorphisms between G. hirsutum and A-genome and D-genome-containing diploid cottons was sufficient to assign the single genes in clones A5 and A19 to the A and D subgenomes, respectively. Each diploid genome has one tandem pair, but in these cases we could not make specific subgenomic assignments. DNA and deduced amino acid sequences were determined for the A5 and A19 genes, and an AHAS cDNA clone isolated from a leaf library. The sequence of the A19 gene matches that of the cDNA clone, while the A5 gene is 97.8% similar. The four genes comprising the tandem pairs are much less similar to the cDNA clone. The deduced amino acid sequences of the mature polypeptides encoded by the A5 and A19 genes are collinear with the housekeeping forms of AHAS from Arabidopsis thaliana, Nicotiana tabacum and Brassica napus. The constitutive expression of A5 and A19 was confirmed with RNase protection assays and northern blots. We conclude that these genes encode the main housekeeping forms of AHAS in G. hirsutum. Among the four AHAS genes comprising the two tandem pairs, at least two are functional. These genes exhibit either low-level constitutive expression (one or both of the 'downstream' genes of each pair), or highly specific expression in reproductive tissue (one or both of the 'upstream' genes of each pair). The AHAS gene family of G. hirsutum is more complex than that of other plants so far examined.

Metabolic engineering of Escherichia coli to enhance recombinant protein production through acetate reduction.

Genetic and metabolic engineering provide powerful and effective tools for the systematic manipulation and fine tuning of cellular metabolic activities. In this study, successful application of such techniques to enhance recombinant protein production by reducing acetate accumulation in Escherichia coli is presented. The alsS gene from Bacillus subtilis encoding the enzyme acetolactate synthase was introduced into E. coli cells using a multicopy plasmid. This newly introduced heterologous enzyme modifies the glycolytic fluxes by redirecting excess pyruvate away from acetate to acetolactate. Acetolactate is then converted to a nonacidic and less harmful byproduct acetoin, which appears in the broth. Furthermore, comparative fermentation studies show that the reduction in acetate accumulation leads to a significant improvement of recombinant protein production. The expression of a model recombinant CadA/beta-galactosidase fusion protein, under the control of a strong pH-regulated promoter, was found to increase by about 60% for the specific protein activity (to a level of 30% of total cellular protein) and 50% in terms of the volumetric activity in a batch fermenter. In fed-batch cultivation, the engineered strain achieved a volumetric recombinant protein yield of 1.6 million units/mL (about 1.1 g/L of beta-galactosidase), which represented a 220% enhancement over the control strain. In the meantime, acetate excretion was maintained below 20 mM compared with 80 mM for the control, and the final cell density was improved by 35%.

Regulation of Caulobacter crescentus ilvBN gene expression.

As part of an effort to determine the mechanisms employed by Caulobacter crescentus to regulate gene expression, the ilvBN genes encoding the two subunits of an acetohydroxy acid synthase (AHAS) have been characterized. Analysis of the DNA sequences indicated that the C. crescentus AHAS was highly homologous to AHAS isozymes from other organisms. S1 nuclease and primer extension studies demonstrated that transcription initiation occurred 172 bp upstream of the AHAS coding region. The region between the AHAS coding region and the transcription initiation site was shown to have the properties of a transcription attenuator. Deletion analysis of the region containing the stem-loop structure of the proposed attenuator resulted in the derepression of ilvBN expression. Thus, it appears that C. crescentus uses attenuation to regulate the expression of the ilvBN operon.

Strategies in high-level expression of recombinant protein in Escherichia coli.

The accumulation of acetate is one of the most commonly encountered problems in attaining high levels of recombinant protein production using E. coli. Two different approaches are examined to reduce the rate of acetate formation. The effects of reduced acetate accumulation on recombinant protein production were also investigated. In the first approach, E. coli mutant strains deficient in enzymes involved in the acetate synthesis pathways were isolated and characterized. The level of specific production of beta-galactosidase by the mutant strain is three times higher than its parent strain. In another approach, metabolic engineering techniques were employed to fine-tune the central metabolic pathways to reduce the amount of acetate formation. The resulting strain, which carries the acetolactase synthase gene from B. subtilis, is successful in maintaining a very low level of acetate accumulation. The ALS-containing strain is also capable of producing higher levels of recombinant protein than its parent strain.