Enzymatic function of the nor-1 protein in aflatoxin biosynthesis in Aspergillus parasiticus

The nor-1 gene is involved in aflatoxin biosynthesis in Aspergillus parasiticus and was predicted to encode a norsolorinic acid ketoreductase. Recombinant Nor-1 expressed in Escherichia coli converted the 1' keto group of norsolorinic acid to the 1' hydroxyl group of averantin in crude E. coli cell extracts in the presence of NADPH. The results confirm that Nor-1 functions as a ketoreductase in vitro.     

Identification, Cloning, and Characterization of a Novel Ketoreductase from the Cyanobacterium Synechococcus sp. Strain PCC 7942

A new ketoreductase useful for asymmetric synthesis of chiral alcohols was identified in the cyanobacterium Synechococcus sp. strain PCC 7942. Mass spectrometry of trypsin-digested peptides identified the protein as 3-ketoacyl-[acyl-carrier-protein] reductase (KR) (EC 1.1.1.100). The gene, referred to as fabG, was cloned, functionally expressed in Escherichia coli, and subsequently purified to homogeneity. The enzyme displayed a temperature optimum at 44°C and a broad pH optimum between pH 7 and pH 9. The NADPH-dependent KR was able to asymmetrically reduce a variety of prochiral ketones with good to excellent enantioselectivities (>99.8%). The KR showed particular high specific activity for asymmetric reduction of ethyl 4-chloroacetoacetate (38.29 ± 2.15 U mg⁻¹) and 2′,3′,4′,5′,6′-pentafluoroacetophenone (8.57 ± 0.49 U mg⁻¹) to the corresponding (S)-alcohols. In comparison with an established industrial enzyme like the alcohol dehydrogenase from Lactobacillus brevis, the KR showed seven-times-higher activity toward 2′,3′,4′,5′,6′-pentafluoroacetophenone, with a remarkably higher enantiomeric excess (>99.8% [S] versus 43.3% [S]).     

Novel Carotenoid Oxidase Involved in Biosynthesis of 4,4′-Diapolycopene Dialdehyde

Biosynthesis of C₃₀ carotenoids is relatively restricted in nature but has been described in Staphylococcus and in methylotrophic bacteria. We report here identification of a novel gene (crtNb) involved in conversion of 4,4′-diapolycopene to 4,4′-diapolycopene aldehyde. An aldehyde dehydrogenase gene (ald) responsible for the subsequent oxidation of 4,4′-diapolycopene aldehyde to 4,4′-diapolycopene acid was also identified in Methylomonas. CrtNb has significant sequence homology with diapophytoene desaturases (CrtN). However, data from knockout of crtNb and expression of crtNb in Escherichia coli indicated that CrtNb is not a desaturase but rather a novel carotenoid oxidase catalyzing oxidation of the terminal methyl group(s) of 4,4′-diaponeurosporene and 4,4′-diapolycopene to the corresponding terminal aldehyde. It has moderate to low activity on neurosporene and lycopene and no activity on β-carotene or ζ-carotene. Using a combination of C₃₀ carotenoid synthesis genes from Staphylococcus and Methylomonas, 4,4′-diapolycopene dialdehyde was produced in E. coli as the predominant carotenoid. This C₃₀ dialdehyde is a dark-reddish purple pigment that may have potential uses in foods and cosmetics.     

Identification of Genes Encoding Conjugated Bile Salt Hydrolase and Transport in Lactobacillus johnsonii 100-100

Cytosolic extracts of Lactobacillus johnsonii 100-100 (previously reported as Lactobacillus sp. strain 100-100) contain four heterotrimeric isozymes composed of two peptides, α and β, with conjugated bile salt hydrolase (BSH) activity. We now report cloning, from the genome of strain 100-100, a 2,977-bp DNA segment that expresses BSH activity in Escherichia coli. The sequencing of this segment showed that it contained one complete and two partial open reading frames (ORFs). The 3′ partial ORF (927 nucleotides) was predicted by BLAST and confirmed with 5′ and 3′ deletions to be a BSH gene. Thermal asymmetric interlaced PCR was used to extend and complete the 948-nucleotide sequence of the BSH gene 3′ of the cloned segment. The predicted amino acid sequence of the 5′ partial ORF (651 nucleotides) was about 80% similar to the C-terminal half of the largest, complete ORF (1,353 nucleotides), and these two putative proteins were similar to several amine, multidrug resistance, and sugar transport proteins of the major facilitator superfamily. E. coli DH5α cells transformed with a construct containing these ORFs, in concert with an extracellular factor produced by strain 100-100, demonstrated levels of uptake of [¹⁴C]taurocholic acid that were increased as much as threefold over control levels. [¹⁴C]Cholic acid was taken up in similar amounts by strain DH5α pSportI (control) and DH5α p2000 (transport clones). These findings support a hypothesis that the ORFs are conjugated bile salt transport genes which may be arranged in an operon with BSH genes.     

Enzymatic processing of DNA containing tandem dihydrouracil by endonucleases III and VIII

Endonuclease III from Escherichia coli, yeast (yNtg1p and yNtg2p) and human and E.coli endonuclease VIII have a wide substrate specificity, and recognize oxidation products of both thymine and cytosine. DNA containing single dihydrouracil (DHU) and tandem DHU lesions were used as substrates for these repair enzymes. It was found that yNtg1p prefers DHU/G and exhibits much weaker enzymatic activity towards DNA containing a DHU/A pair. However, yNtg2p, E.coli and human endonuclease III and E.coli endonuclease VIII activities were much less sensitive to the base opposite the lesion. Although these enzymes efficiently recognize single DHU lesions, they have limited capacity for completely removing this damaged base when DHU is present on duplex DNA as a tandem pair. Both E.coli endonuclease III and yeast yNtg1p are able to remove only one DHU in DNA containing tandem lesions, leaving behind a single DHU at either the 3′- or 5′-terminus of the cleaved fragment. On the other hand, yeast yNtg2p can remove DHU remaining on the 5′-terminus of the 3′ cleaved fragment, but is unable to remove DHU remaining on the 3′-terminus of the cleaved 5′ fragment. In contrast, both human endonuclease III and E.coli endonuclease VIII can remove DHU remaining on the 3′-terminus of a cleaved 5′ fragment, but are unable to remove DHU remaining on the 5′-terminus of a cleaved 3′ fragment. Tandem lesions are known to be generated by ionizing radiation and agents that generate reactive oxygen species. The fact that these repair glycosylases have only a limited ability to remove the DHU remaining at the terminus suggests that participation of other repair enzymes is required for the complete removal of tandem lesions before repair synthesis can be efficiently performed by DNA polymerase.     

RNase activity of polynucleotide phosphorylase is critical at low temperature in Escherichia coli and is complemented by RNase II

In Escherichia coli, the cold shock response is exerted upon a temperature change from 37°C to 15°C and is characterized by induction of several cold shock proteins, including polynucleotide phosphorylase (PNPase), during acclimation phase. In E. coli, PNPase is essential for growth at low temperatures; however, its exact role in this essential function has not been fully elucidated. PNPase is a 3′-to-5′ exoribonuclease and promotes the processive degradation of RNA. Our screening of an E. coli genomic library for an in vivo counterpart of PNPase that can compensate for its absence at low temperature revealed only one protein, another 3′-to-5′ exonuclease, RNase II. Here we show that the RNase PH domains 1 and 2 of PNPase are important for its cold shock function, suggesting that the RNase activity of PNPase is critical for its essential function at low temperature. We also show that its polymerization activity is dispensable in its cold shock function. Interestingly, the third 3′-to-5′ processing exoribonuclease, RNase R of E. coli, which is cold inducible, cannot complement the cold shock function of PNPase. We further show that this difference is due to the different targets of these enzymes and stabilization of some of the PNPase-sensitive mRNAs, like fis, in the Δpnp cells has consequences, such as accumulation of ribosomal subunits in the Δpnp cells, which may play a role in the cold sensitivity of this strain.     

Galactosyl-Lactose Sialylation Using Trypanosoma cruzi trans-Sialidase as the Biocatalyst and Bovine κ-Casein-Derived Glycomacropeptide as the Donor Substrate

trans-Sialidase (TS) enzymes catalyze the transfer of sialyl (Sia) residues from Sia(α2-3)Gal(β1-x)-glycans (sialo-glycans) to Gal(β1-x)-glycans (asialo-glycans). Aiming to apply this concept for the sialylation of linear and branched (Gal)_nGlc oligosaccharide mixtures (GOS) using bovine κ-casein-derived glycomacropeptide (GMP) as the sialic acid donor, a kinetic study has been carried out with three components of GOS, i.e., 3′-galactosyl-lactose (β3′-GL), 4′-galactosyl-lactose (β4′-GL), and 6′-galactosyl-lactose (β6′-GL). This prebiotic GOS is prepared from lactose by incubation with suitable β-galactosidases, whereas GMP is a side-stream product of the dairy industry. The trans-sialidase from Trypanosoma cruzi (TcTS) was expressed in Escherichia coli and purified. Its temperature and pH optima were determined to be 25°C and pH 5.0, respectively. GMP [sialic acid content, 3.6% (wt/wt); N-acetylneuraminic acid (Neu5Ac), >99%; (α2-3)-linked Neu5Ac, 59%] was found to be an efficient sialyl donor, and up to 95% of the (α2-3)-linked Neu5Ac could be transferred to lactose when a 10-fold excess of this acceptor substrate was used. The products of the TcTS-catalyzed sialylation of β3′-GL, β4′-GL, and β6′-GL, using GMP as the sialic acid donor, were purified, and their structures were elucidated by nuclear magnetic resonance spectroscopy. Monosialylated β3′-GL and β4′-GL contained Neu5Ac connected to the terminal Gal residue; however, in the case of β6′-GL, TcTS was shown to sialylate the 3 position of both the internal and terminal Gal moieties, yielding two different monosialylated products and a disialylated structure. Kinetic analyses showed that TcTS had higher affinity for the GL substrates than lactose, while the V_max and k_cat values were higher in the case of lactose.     

Active site constraints in the hydrolysis reaction catalyzed by bacterial RNase P: analysis of precursor tRNAs with a single 3'-S-phosphorothiolate internucleotide linkage

Endonucleolytic processing of precursor tRNAs (ptRNAs) by RNase P yields 3′-OH and 5′-phosphate termini, and at least two metal ions are thought to be essential for catalysis. To determine if the hydrolysis reaction catalyzed by bacterial RNase P (RNAs) involves stabilization of the 3′-oxyanion leaving group by direct coordination to one of the catalytic metal ions, ptRNA substrates with single 3′-S-phosphorothiolate linkages at the RNase P cleavage site were synthesized. With a 3′-S-phosphorothiolate-modified ptRNA carrying a 7 nt 5′-flank, a complete shift of the cleavage site to the next unmodified phosphodiester in the 5′-direction was observed. Cleavage at the modified linkage was not restored in the presence of thiophilic metal ions, such as Mn²⁺ or Cd²⁺. To suppress aberrant cleavage, we also constructed a 3′-S-phosphorothiolate-modified ptRNA with a 1 nt 5′-flank. No detectable cleavage of this substrate was seen in reactions catalyzed by RNase P RNAs from Escherichia coli and Bacillus subtilis, independent of the presence of thiophilic metal ions. Ground state binding of modified ptRNAs was not impaired, suggesting that the 3′-S-phosphorothiolate modification specifically prevents formation of the transition state, possibly by excluding catalytic metal ions from the active site.     

A candidate prostate cancer susceptibility gene encodes tRNA 3' processing endoribonuclease

tRNA 3′ processing endoribonuclease (3′ tRNase) is an enzyme responsible for the removal of a 3′ trailer from precursor tRNA (pre-tRNA). We purified ~85 kDa 3′ tRNase from pig liver and determined its partial sequences. BLAST search of them suggested that the enzyme was the product of a candidate human prostate cancer susceptibility gene, ELAC2, the biological function of which was totally unknown. We cloned a human ELAC2 cDNA and expressed the ELAC2 protein in Escherichia coli. The recombinant ELAC2 was able to cleave human pre-tRNA^Arg efficiently. The 3′ tRNase activity of the yeast ortholog YKR079C was also observed. The C-terminal half of human ELAC2 was able to remove a 3′ trailer from pre-tRNA^Arg, while the N‐terminal half failed to do so. In the human genome exists a gene, ELAC1, which seems to correspond to the C-terminal half of 3′ tRNase from ELAC2. We showed that human ELAC1 also has 3′-tRNase activity. Furthermore, we examined eight ELAC2 variants that seem to be associated with the occurrence of prostate cancer for 3′-tRNase activity. Seven ELAC2 variants which contain one to three amino acid substitutions showed efficient 3′-tRNase activities, while one truncated variant, which lacked a C-terminal half region, had no activity.     

A key role for the mRNA leader structure in translational control of ribosomal protein S1 synthesis in gamma-proteobacteria

The translation initiation region (TIR) of the Escherichia coli rpsA mRNA coding for ribosomal protein S1 is characterized by a remarkable efficiency in driving protein synthesis despite the absence of the canonical Shine–Dalgarno element, and by a strong and specific autogenous repression in the presence of free S1 in trans. The efficient and autoregulated E.coli rpsA TIR comprises not less than 90 nt upstream of the translation start and can be unambiguously folded into three irregular hairpins (HI, HII and HIII) separated by A/U-rich single-stranded regions (ss1 and ss2). Phylogenetic comparison revealed that this specific fold is highly conserved in the γ-subdivision of proteobacteria (but not in other subdivisions), except for the Pseudomonas group. To test phylogenetic predictions experimentally, we have generated rpsA′–′lacZ translational fusions by inserting the rpsA TIRs from various γ-proteobacteria in-frame with the E.coli chromosomal lacZ gene. Measurements of their translation efficiency and negative regulation by excess protein S1 in trans have shown that only those rpsA TIRs which share the structural features with that of E.coli can govern efficient and regulated translation. We conclude that the E.coli-like mechanism for controlling the efficiency of protein S1 synthesis evolved after divergence of Pseudomona     

Increased efficiency of evolved group I intron spliceozymes by decreased side product formation

The group I intron ribozyme from Tetrahymena was recently reengineered into a trans-splicing variant that is able to remove 100-nt introns from pre-mRNA, analogous to the spliceosome. These spliceozymes were improved in this study by 10 rounds of evolution in Escherichia coli cells. One clone with increased activity in E. coli cells was analyzed in detail. Three of its 10 necessary mutations extended the substrate binding duplexes, which led to increased product formation and reduced cleavage at the 5′-splice site. One mutation in the conserved core of the spliceozyme led to a further reduction of cleavage at the 5′-splice site but an increase in cleavage side products at the 3′-splice site. The latter was partially reduced by six additional mutations. Together, the mutations increased product formation while reducing activity at the 5′-splice site and increasing activity at the 3′-splice site. These results show the adaptation of a ribozyme that evolved in nature for cis-splicing to trans-splicing, and they highlight the interdependent function of nucleotides within group I intron ribozymes. Implications for the possible use of spliceozymes as tools in research and therapy, and as a model for the evolution of the spliceosome, are discussed.     

Molecular interactions of Escherichia coli ExoIX and identification of its associated 3'-5' exonuclease activity

The flap endonucleases (FENs) participate in a wide range of processes involving the structure-specific cleavage of branched nucleic acids. They are also able to hydrolyse DNA and RNA substrates from the 5′-end, liberating mono-, di- and polynucleotides terminating with a 5′ phosphate. Exonuclease IX is a paralogue of the small fragment of Escherichia coli DNA polymerase I, a FEN with which it shares 66% similarity. Here we show that both glutathione-S-transferase-tagged and native recombinant ExoIX are able to interact with the E. coli single-stranded DNA binding protein, SSB. Immobilized ExoIX was able to recover SSB from E. coli lysates both in the presence and absence of DNA. In vitro cross-linking studies carried out in the absence of DNA showed that the SSB tetramer appears to bind up to two molecules of ExoIX. Furthermore, we found that a 3′–5′ exodeoxyribonuclease activity previously associated with ExoIX can be separated from it by extensive liquid chromatography. The associated 3′–5′ exodeoxyribonuclease activity was excised from a 2D gel and identified as exonuclease III using matrix-assisted laser-desorption ionization mass spectrometry.     

Effects of DNA3′pp5′G capping on 3′ end repair reactions and of an embedded pyrophosphate-linked guanylate on ribonucleotide surveillance

When DNA breakage results in a 3′-PO₄ terminus, the end is considered ‘dirty’ because it cannot prime repair synthesis by DNA polymerases or sealing by classic DNA ligases. The noncanonical ligase RtcB can guanylylate the DNA 3′-PO₄ to form a DNA_3′pp_5′G_OH cap. Here we show that DNA capping precludes end joining by classic ATP-dependent and NAD⁺-dependent DNA ligases, prevents template-independent nucleotide addition by mammalian terminal transferase, blocks exonucleolytic proofreading by Escherichia coli DNA polymerase II and inhibits proofreading by E. coli DNA polymerase III, while permitting templated DNA synthesis from the cap guanosine 3′-OH primer by E. coli DNA polymerase II (B family) and E. coli DNA polymerase III (C family). Human DNA polymerase β (X family) extends the cap primer predominantly by a single templated addition step. Cap-primed synthesis by templated polymerases embeds a pyrophosphate-linked ribonucleotide in DNA. We find that the embedded ppG is refractory to surveillance and incision by RNase H2.     

Characterization of an Extremely Thermostable Restriction Enzyme, PspGI, from a Pyrococcus Strain and Cloning of the PspGI Restriction-Modification System in Escherichia coli

An extremely thermostable restriction endonuclease, PspGI, was purified from Pyrococcus sp. strain GI-H. PspGI is an isoschizomer of EcoRII and cleaves DNA before the first C in the sequence 5′ ^CCWGG 3′ (W is A or T). PspGI digestion can be carried out at 65 to 85°C. To express PspGI at high levels, the PspGI restriction-modification genes (pspGIR and pspGIM) were cloned in Escherichia coli. M.PspGI contains the conserved sequence motifs of α-aminomethyltransferases; therefore, it must be an N4-cytosine methylase. M.PspGI shows 53% similarity to (44% identity with) its isoschizomer, M.MvaI from Micrococcus variabilis. In a segment of 87 amino acid residues, PspGI shows significant sequence similarity to EcoRII and to regions of SsoII and StyD4I which have a closely related recognition sequence (5′ ^CCNGG 3′). PspGI was expressed in E. coli via a T7 expression system. Recombinant PspGI was purified to near homogeneity and had a half-life of 2 h at 95°C. PspGI remained active following 30 cycles of thermocycling; thus, it can be used in DNA-based diagnostic applications.     

Biotransformation of Natural and Synthetic Isoflavonoids by Two Recombinant Microbial Enzymes

Isolation and synthesis of isoflavonoids has become a frequent endeavor, due to their interesting biological activities. The introduction of hydroxyl groups into isoflavonoids by the use of enzymes represents an attractive alternative to conventional chemical synthesis. In this study, the capabilities of biphenyl-2,3-dioxygenase (BphA) and biphenyl-2,3-dihydrodiol 2,3-dehydrogenase (BphB) of Burkholderia sp. strain LB400 to biotransform 14 isoflavonoids synthesized in the laboratory were investigated by using recombinant Escherichia coli strains containing plasmid vectors expressing the bphA1A2A3A4 or bphA1A2A3A4B genes of strain LB400. The use of BphA and BphB allowed us to biotransform 7-hydroxy-8-methylisoflavone and 7-hydroxyisoflavone into 7,2′,3′-trihydroxy-8-methylisoflavone and 7,3′,4′-trihydroxyisoflavone, respectively. The compound 2′-fluoro-7-hydroxy-8-methylisoflavone was dihydroxylated by BphA at ortho-fluorinated and meta positions of ring B, with concomitant dehalogenation leading to 7,2′,3′,-trihydroxy-8-methylisoflavone. Daidzein (7,4′-dihydroxyisoflavone) was biotransformed by BphA, generating 7,2′,4′-trihydroxyisoflavone after dehydration. Biotransformation products were analyzed by gas chromatography-mass spectrometry and nuclear magnetic resonance techniques.     

Identification and Characterization of aarF, a Locus Required for Production of Ubiquinone in Providencia stuartii and Escherichia coli and for Expression of 2′-N-Acetyltransferase in P. stuartii

Providencia stuartii contains a chromosomal 2′-N-acetyltransferase [AAC(2′)-Ia] involved in the O acetylation of peptidoglycan. The AAC(2′)-Ia enzyme is also capable of acetylating and inactivating certain aminoglycosides and confers high-level resistance to these antibiotics when overexpressed. We report the identification of a locus in P. stuartii, designated aarF, that is required for the expression of AAC(2′)-Ia. Northern (RNA) analysis demonstrated that aac(2′)-Ia mRNA levels were dramatically decreased in a P. stuartii strain carrying an aarF::Cm disruption. The aarF::Cm disruption also resulted in a deficiency in the respiratory cofactor ubiquinone. The aarF locus encoded a protein that had a predicted molecular mass of 62,559 Da and that exhibited extensive amino acid similarity to the products of two adjacent open reading frames of unknown function (YigQ and YigR), located at 86 min on the Escherichia coli chromosome. An E. coli yigR::Kan mutant was also deficient in ubiquinone content. Complementation studies demonstrated that the aarF and the E. coli yigQR loci were functionally equivalent. The aarF or yigQR genes were unable to complement ubiD and ubiE mutations that are also present at 86 min on the E. coli chromosome. This result indicates that aarF (yigQR) represents a novel locus for ubiquinone production and reveals a previously unreported connection between ubiquinone biosynthesis and the regulation of gene expression.     

A novel Nudix hydrolase for oxidized purine nucleoside triphosphates encoded by ORFYLR151c (PCD1 gene) in Saccharomyces cerevisiae

A search for candidates for a functional homologue of Escherichia coli MutT in yeast Saccharomyces cerevisiae was made in the NCBI-BLAST database using the Nudix box, a short amino acid sequence conserved among E.coli MutT, Pseudomonoas vulgaris MutT, and human, rat and mouse MTH1. Among five candidates, we focused on the open reading frame YLR151c, because it had a region with ~76% similarity to the N-terminal half of MutT including the Nudix box. We thus evaluated the ability of YLR151c as a functional homologue of E.coli MutT in S.cerevisiae. Expression of YLR151c was able to suppress the transversion from A:T to C:G caused by misincorporation of the oxidized nucleotide 8-oxo-dGTP in the E.coli mutT-deficient strain. The disruption of the YLR151c in yeast strain caused ~14-fold increase in the frequency of spontaneous mutation compared to the wild type. Additionally, biochemical analysis indicated that GST-YLR151c fusion protein possessed pyrophosphatase activity for both 7,8-dihydro-8-oxo-2′-deoxyguanosine triphosphate (8-oxo-dGTP) and 1,2-dihydro-2-hydroxy-2′-deoxyadenosine triphosphate (2-OH-dATP). The specific activity of GST-YLR151c for 8-oxo-dGTP was 5.6 × 10⁻³ μM⁻¹ s⁻¹, which was similar to that of RibA, a backup enzyme for MutT in E.coli, but was 150-fold lower than that of hMTH1. From these results, we conclude that YLR151c has an ability to prevent spontaneous mutagenesis via sanitization of oxidized nucleotides, and that it may be the functional homologue of E.coli MutT in S.cerevisiae.     

The control of sulphate reduction in bacteria

1. An enzyme from Escherichia coli 9723 that reduces adenosine 3′-phosphate 5′-sulphatophosphate to inorganic sulphite is described. Extracts of E. coli K₁₂ and Bacillus subtilis 1379 contain a similar enzyme. 2. This reductase and sulphite reductase (EC 1.8.1.2) of E. coli 9723, E. coli K₁₂ and of B. subtilis are repressed by growth in the presence of l-cystine. Cysteine synthase (EC 4.2.1.22) is unaffected. 3. Growth of E. coli 9723 on inorganic sulphite represses the sulphate-activating enzymes (EC 2.7.7.4 and 2.7.1.25) almost completely but has little effect on sulphite reductase. Growth on 0·042–0·056mm-l-cystine gives a similar result. 4. Such differential repression by cyst(e)ine prevents E. coli, when growing on sulphite, from synthesizing unnecessary enzymes.     

Production of Medium-Chain-Length Poly(3-Hydroxyalkanoates) from Gluconate by Recombinant Escherichia coli

It was shown recently that recombinant Escherichia coli, defective in the β-oxidation cycle and harboring a medium-chain-length (MCL) poly(3-hydroxyalkanoate) (PHA) polymerase-encoding gene of Pseudomonas, is able to produce MCL PHA from fatty acids but not from sugars or gluconate (S. Langenbach, B. H. A. Rehm, and A. Steinbüchel, FEMS Microbiol. Lett. 150:303–309, 1997; Q. Ren, Ph.D. thesis, ETH Zürich, Zürich, Switzerland, 1997). In this study, we report the formation of MCL PHA from gluconate by recombinant E. coli. By introduction of genes coding for an MCL PHA polymerase and the cytosolic thioesterase I (′thioesterase I) into E. coli JMU193, we were able to engineer a pathway for the synthesis of MCL PHA from gluconate. We used two expression systems, i.e., the bad promoter and alk promoter, for the ′thioesterase I- and PHA polymerase-encoding genes, respectively, which enabled us to modulate their expression independently over a range of inducer concentrations, which resulted in a maximum MCL PHA accumulation of 2.3% of cell dry weight from gluconate. We found that the amount of PHA and the ′thioesterase I activity are directly correlated. Moreover, the polymer accumulated in the recombinant E. coli consisted mainly of 3-hydroxyoctanoate monomers. On the basis of our data, we propose an MCL PHA biosynthesis pathway scheme for recombinant E. coli JMU193, harboring PHA polymerase and ′thioesterase I, when grown on gluconate, which involves both de novo fatty acid synthesis and β-oxidation.     

Phosphorylation of Nucleosides by the Mutated Acid Phosphatase from Morganella morganii

A novel nucleoside phosphorylation process using the food additive pyrophosphate as the phosphate source was investigated. The Morganella morganii gene encoding a selective nucleoside pyrophosphate phosphotransferase was cloned. It was identical to the M. morganii PhoC acid phosphatase gene. Sequential in vitro random mutagenesis was performed on the gene by error-prone PCR to construct a mutant library. The mutant library was introduced into Escherichia coli, and the transformants were screened for the production of 5′-IMP. One mutated acid phosphatase with an increased phosphotransferase reaction yield was obtained. With E. coli overproducing the mutated acid phosphatase, 101 g of 5′-IMP per liter (192 mM) was synthesized from inosine in an 88% molar yield. This improvement was achieved with two mutations, Gly to Asp at position 92 and Ile to Thr at position 171. A decreased K_m value for inosine was responsible for the increased productivity.