Purification and Characterization of Fungal Poly(3-hydroxybutyrate) Depolymerase from Paecilomyces lilacinus F4-5 and Enzymatic Degradation of Poly(3-hydroxybutyrate-co-3-hydroxyvalerate) Film

Summary Poly(3-hydroxybutyrate) [P(3HB)] depolymerase was purified from a poly(3-hydroxybutyrate-co-3-hydroxyvalerate) [P(3HB-co-3HV)]-degrading fungus, Paecilomyces lilacinus F4-5 by hydrophobic and ion exchange column chromatography, and showed a molecular mass of 45 kDa. The optimum temperature and pH of the P(3HB) depolymerase were 50 °C and 7.0, respectively. The enzyme was stable for at least 30 min at temperatures below 40 °C, while the activity abruptly decreased over 55 °C. Enzymatic P(3HB-co-3HV) degradation showed a similar degradation pattern to that of film overlaid by fungal hyphae. It reflects that the fungal degradation of P(3HB-co-3HV) in soil is mainly caused by extracellular depolymerases.     

Assay of Poly(3-Hydroxybutyrate) Depolymerase Activity and Product Determination

Two methods for accurate poly(3-hydroxybutyrate) (PHB) depolymerase activity determination and quantitative and qualitative hydrolysis product determination are described. The first method is based on online determination of NaOH consumption rates necessary to neutralize 3-hydroxybutyric acid (3HB) and/or 3HB oligomers produced during the hydrolysis reaction and requires a pH-stat apparatus equipped with a software-controlled microliter pump for rapid and accurate titration. The method is universally suitable for hydrolysis of any type of polyhydroxyalkanoate or other molecules with hydrolyzable ester bonds, allows the determination of hydrolysis rates of as low as 1 nmol/min, and has a dynamic capacity of at least 6 orders of magnitude. By applying this method, specific hydrolysis rates of native PHB granules isolated from Ralstonia eutropha H16 were determined for the first time. The second method was developed for hydrolysis product identification and is based on the derivatization of 3HB oligomers into bromophenacyl derivates and separation by high-performance liquid chromatography. The method allows the separation and quantification of 3HB and 3HB oligomers up to the octamer. The two methods were applied to investigate the hydrolysis of different types of PHB by selected PHB depolymerases.     

Identification and Characterization of a Novel Intracellular Poly(3-Hydroxybutyrate) Depolymerase from Bacillus megaterium

A gene that codes for a novel intracellular poly(3-hydroxybutyrate) (PHB) depolymerase, designated PhaZ1, has been identified in the genome of Bacillus megaterium. A native PHB (nPHB) granule-binding assay showed that purified soluble PhaZ1 had strong affinity for nPHB granules. Turbidimetric analyses revealed that PhaZ1 could rapidly degrade nPHB granules in vitro without the need for protease pretreatment of the granules to remove surface proteins. Notably, almost all the final hydrolytic products produced from the in vitro degradation of nPHB granules by PhaZ1 were 3-hydroxybutyric acid (3HB) monomers. Unexpectedly, PhaZ1 could also hydrolyze denatured semicrystalline PHB, with the generation of 3HB monomers. The disruption of the phaZ1 gene significantly affected intracellular PHB mobilization during the PHB-degrading stage in B. megaterium, as demonstrated by transmission electron microscopy and the measurement of the PHB content. These results indicate that PhaZ1 is functional in intracellular PHB mobilization in vivo. Some of these features, which are in striking contrast with those of other known nPHB granule-degrading PhaZs, may provide an advantage for B. megaterium PhaZ1 in fermentative production of the biotechnologically valuable chiral compound (R)-3HB.Polyhydroxyalkanoates (PHAs) are a group of polyesters that are produced by numerous bacteria as carbon and energy storage materials in response to nutritional stress (13, 27, 29). Poly(3-hydroxybutyrate) (PHB) is the most common and intensively studied PHA. Intracellular native PHB (nPHB) granules are composed of a hydrophobic PHB core and a surface layer consisting of proteins and phospholipids (13). The PHB of intracellular nPHB granules is in an amorphous state. When intracellular nPHB granules are exposed to extracellular environments due to cell death and lysis, the amorphous PHB is transformed into a denatured semicrystalline state. nPHB granules subjected to physical damage or solvent extraction to remove the surface layer can also crystallize into denatured PHB (dPHB) (13, 15). Artificial PHB (aPHB) granules, in which PHB is in an amorphous state, can be prepared from semicrystalline dPHB and detergents (1, 11, 23, 31).Various extracellular PHB depolymerases (PhaZs) that are secreted by many PHB-degrading bacteria have been demonstrated to specifically degrade dPHB (13, 14, 37). One exception is that PhaZ7, an extracellular PHB depolymerase secreted by Paucimonas lemoignei, displays unusual substrate specificity for amorphous PHB, with 3-hydroxybutyrate (3HB) oligomers as the main products of enzymatic hydrolysis (7). PhaZ7 exhibits no enzymatic activity toward dPHB. So far, a growing number of intracellular PHB depolymerases have been characterized. The intracellular PHB depolymerase PhaZa1 of Ralstonia eutropha (also called Cupriavidus necator) H16 has recently been established to be especially important for the intracellular mobilization of accumulated PHB (42). The main in vitro hydrolytic products of PhaZa1 degradation of amorphous aPHB are 3HB oligomers (31). PhaZd1, another intracellular PHB depolymerase of R. eutropha H16, shows no significant amino acid similarity to PhaZa1. The in vitro hydrolytic products of PhaZd1 degradation of amorphous aPHB are also 3HB oligomers. A 3HB monomer is rarely detected as a hydrolytic product (1). The intracellular PHB depolymerase PhaZ of Paracoccus denitrificans was reported previously to degrade protease-treated nPHB granules in vitro, with the release of 3HB dimers and oligomers as the main hydrolytic products (6). Recently, we have identified a novel intracellular PHB depolymerase from Bacillus thuringiensis serovar “israelensis” (39). The B. thuringiensis PhaZ shows no significant amino acid similarity to any known PHB depolymerase. This PhaZ has strong amorphous PHB-hydrolyzing activity and can release a considerable amount of 3HB monomers by the hydrolysis of trypsin-treated nPHB granules (39). It is of note that purified PhaZd1 from R. eutropha, PhaZ from P. denitrificans, and PhaZ from B. thuringiensis need pretreatment of nPHB granules with protease to remove surface proteins for PHB degradation (1, 6, 39). They show only very little or no activity toward nPHB granules without trypsin pretreatment. It has been demonstrated previously that these intracellular PHB depolymerases cannot hydrolyze dPHB (1, 31, 39).(R)-3HB, a biotechnologically valuable chiral compound, has been widely used for syntheses of antibiotics, vitamins, and pheromones (3, 30, 38). One way to produce (R)-3HB is heterologous coexpression of a PHB synthetic operon and a gene encoding an amorphous PHB-degrading PhaZ in Escherichia coli (3, 18, 25, 33, 38). A common problem encountered by this method is that oligomeric and dimeric forms of 3HB often constitute a major portion of the products of enzymatic hydrolysis, thus requiring further hydrolysis by 3HB oligomer hydrolase or heating under alkaline conditions to generate 3HB monomers (3, 18, 25, 33).Bacillus megaterium genes involved in the biosynthesis of nPHB granules have been cloned from strain ATCC 11561 and characterized previously (19, 21, 22). A gene encoding the extracellular PHB depolymerase PhaZ from B. megaterium was recently cloned from strain N-18-25-9 (34). However, little is known about B. megaterium genes involved in the intracellular mobilization of PHB. In this study, we have identified in B. megaterium ATCC 11561 an intracellular PHB depolymerase that could rapidly degrade nPHB granules in vitro without the need for trypsin pretreatment of the nPHB granules. Moreover, almost all the in vitro hydrolytic products released from the degradation of amorphous PHB by this PhaZ were 3HB monomers. This PhaZ could also hydrolyze dPHB with the generation of 3HB monomers. Thus, it appears to be a novel intracellular PHB depolymerase and may have promising potential for biotechnological application in the production of enantiomerically pure (R)-3HB monomers.     

Roles of Poly(3-Hydroxybutyrate) Depolymerase and 3HB-Oligomer Hydrolase in Bacterial PHB Metabolism

Many poly-3-hydroxybutyrate (PHB)-degrading enzymes have been studied. But biological roles of 3HB-oligomer hydrolases (3HBOHs) and how PHB depolymerases (PHBDPs) and 3HBOHs cooperate in PHB metabolism are not fully elucidated. In this study, several PHBDPs and 3HBOHs from three types of bacteria were purified, and their substrate specificity, kinetic properties, and degradation products were investigated. From the results, PHBDP and 3HBOH seemed to play a role in PHB metabolism in three types of bacteria, as follows: (A) In Ralstonia pickettii T1, an extracellular PHBDP degrades extracellular PHB to various-sized 3HB-oligomers, which an extracellular 3HBOH hydrolyzes to 3HB-monomers. (B) In Acidovorax sp. SA1, an extracellular PHBDP hydrolyzes extracellular PHB to small 3HB-oligomers (dimer and trimer), which an intracellular 3HBOH efficiently degrades to 3HB in the cell. (C) In Ralstonia eutropha H16, an intracellular 3HBOH helps in the degradation of intracellular PHB inclusions by PHBDP.     

Relationship between Succinate Transport and Production of Extracellular Poly(3-Hydroxybutyrate) Depolymerase in Pseudomonas lemoignei

The relationship between extracellular poly(3-hydroxybutyrate) (PHB) depolymerase synthesis and the unusual properties of a succinate uptake system was investigated in Pseudomonas lemoignei. Growth on and uptake of succinate were highly pH dependent, with optima at pH 5.6. Above pH 7, growth on and uptake of succinate were strongly reduced with concomitant derepression of PHB depolymerase synthesis. The specific succinate uptake rates were saturable by high concentrations of succinate, and maximal transport rates of 110 nmol/mg of cell protein per min were determined between pH 5.6 and 6.8. The apparent K_S0.5 values increased with increasing pH from 0.2 mM succinate at pH 5.6 to more than 10 mM succinate at pH 7.6. The uptake of [¹⁴C]succinate was strongly inhibited by several monocarboxylates. Dicarboxylates also inhibited the uptake of succinate but only at pH values near the dissociation constant of the second carboxylate function (pK_a2). We conclude that the succinate carrier is specific for the monocarboxylate forms of various carboxylic acids and is not able to utilize the dicarboxylic forms. The inability to take up succinate²⁻ accounts for the carbon starvation of P. lemoignei observed during growth on succinate at pH values above 7. As a consequence the bacteria produce high levels of extracellular PHB depolymerase activity in an effort to escape carbon starvation by utilization of PHB hydrolysis products.     

Removal of Endotoxin during Purification of Poly(3-Hydroxybutyrate) from Gram-Negative Bacteria

Poly(3-hydroxybutyrate) (PHB) was produced by cultivating several gram-negative bacteria, including Ralstonia eutropha, Alcaligenes latus, and recombinant Escherichia coli. PHB was recovered from these bacteria by two different methods, and the endotoxin levels were determined. When PHB was recovered by the chloroform extraction method, the endotoxin level was less than 10 endotoxin units (EU) per g of PHB irrespective of the bacterial strains employed and the PHB content in the cell. The NaOH digestion method, which was particularly effective for the recovery of PHB from recombinant E. coli, was also examined for endotoxin removal. The endotoxin level present in PHB recovered by 0.2 N NaOH digestion for 1 h at 30°C was higher than 10⁴ EU/g of PHB. Increasing the digestion time or NaOH concentration reduced the endotoxin level to less than 1 EU/g of PHB. It was concluded that PHB with a low endotoxin level, which can be used for various biomedical applications, could be produced by chloroform extraction. Furthermore, PHB with a much lower endotoxin level could be produced from recombinant E. coli by simple NaOH digestion.     

Purification and characterization of Paecilomyces lilacinus dextranase

Two dextranase isoenzymes [endo-(1,6)-α-d-glucan-6-glucanohydrolase, EC 3.2.1.11] have been isolated from a crude enzyme powder prepared from the culture supernatant of Paecilomyces lilacinus. Purification was achieved by means of a two-stage ion-exchange chromatography on DEAE-cellulose. Dextranase I was recovered with a 35.3-fold increase in specific activity and a yield of 16%; dextranase II was purified 19-fold with a yield of 4%. The characteristics of the isoenzymes were very similar; both exhibited maximum hydrolytic activity at pH 4.5 and 55°C. Activation energies for thermal inactivation were 402 and 330 kJ mol^?1 for dextranase I and II, respectively. The dextranases were not inhibited by EDTA or N-ethylmaleimide.     

Poly(3-Hydroxyvalerate) Depolymerase of Pseudomonas lemoignei

Pseudomonas lemoignei is equipped with at least five polyhydroxyalkanoate (PHA) depolymerase structural genes (phaZ1 to phaZ5) which enable the bacterium to utilize extracellular poly(3-hydroxybutyrate) (PHB), poly(3-hydroxyvalerate) (PHV), and related polyesters consisting of short-chain-length hxdroxyalkanoates (PHA_SCL) as the sole sources of carbon and energy. Four genes (phaZ1, phaZ2, phaZ3, and phaZ5) encode PHB depolymerases C, B, D, and A, respectively. It was speculated that the remaining gene, phaZ4, encodes the PHV depolymerase (D. Jendrossek, A. Frisse, A. Behrends, M. Andermann, H. D. Kratzin, T. Stanislawski, and H. G. Schlegel, J. Bacteriol. 177:596–607, 1995). However, in this study, we show that phaZ4 codes for another PHB depolymeraes (i) by disagreement of 5 out of 41 amino acids that had been determined by Edman degradation of the PHV depolymerase and of four endoproteinase GluC-generated internal peptides with the DNA-deduced sequence of phaZ4, (ii) by the lack of immunological reaction of purified recombinant PhaZ4 with PHV depolymerase-specific antibodies, and (iii) by the low activity of the PhaZ4 depolymerase with PHV as a substrate. The true PHV depolymerase-encoding structural gene, phaZ6, was identified by screening a genomic library of P. lemoignei in Escherichia coli for clearing zone formation on PHV agar. The DNA sequence of phaZ6 contained all 41 amino acids of the GluC-generated peptide fragments of the PHV depolymerase. PhaZ6 was expressed and purified from recombinant E. coli and showed immunological identity to the wild-type PHV depolymerase and had high specific activities with PHB and PHV as substrates. To our knowledge, this is the first report on a PHA_SCL depolymerase gene that is expressed during growth on PHV or odd-numbered carbon sources and that encodes a protein with high PHV depolymerase activity. Amino acid analysis revealed that PhaZ6 (relative molecular mass [M_r], 43,610 Da) resembles precursors of other extracellular PHA_SCL depolymerases (28 to 50% identical amino acids). The mature protein (M_r, 41,048) is composed of (i) a large catalytic domain including a catalytic triad of S₁₃₆, D₂₁₁, and H₂₆₉ similar to serine hydrolases; (ii) a linker region highly enriched in threonine residues and other amino acids with hydroxylated or small side chains (Thr-rich region); and (iii) a C-terminal domain similar in sequence to the substrate-binding domain of PHA_SCL depolymerases. Differences in the codon usage of phaZ6 for some codons from the average codon usage of P. lemoignei indicated that phaZ6 might be derived from other organisms by gene transfer. Multialignment of separate domains of bacterial PHA_SCL depolymerases suggested that not only complete depolymerase genes but also individual domains might have been exchanged between bacteria during evolution of PHA_SCL depolymerases.     

Modeling of Progesterone Release from Poly(3-Hydroxybutyrate) (PHB) Membranes

Poly(3-hydroxybutyrate) (PHB) biodegradable polymeric membranes were evaluated as platform for progesterone (Prg)-controlled release. In the design of new drug delivery systems, it is important to understand the mass transport mechanism involved, as well as predict the process kinetics. Drug release experiments were conducted and the experimental results were evaluated using engineering approaches that were extrapolated to the pharmaceutical field by our research group. Membranes were loaded with different Prg concentrations and characterized by scanning electron microscopy (SEM), differential scanning calorimetry (DSC), and Fourier transform infrared spectroscopy (FTIR). SEM images showed that membranes have a dense structure before and after the progesterone addition. DSC and FTIR allowed determining the influence of the therapeutic agent in the membrane properties. The in vitro experiments were performed using two different techniques: (A) returning the sample to the receptor solution (constant volume of the delivery medium) and (B) extracting total volume of the receptor solution. In this work, we present a simple and accurate “lumped” second-order kinetic model. This lumped model considers the different mass transport steps involved in drug release systems. The model fits very well the experimental data using any of the two experimental procedures, in the range 0?≤?t?≤?∞ or 0?≤?M _t ?≤?M _∞. The drug release analysis using our proposed approaches is relevant for establishing in vitro–in vivo correlations in future tests in animals.     

Effects of Mutations in the Substrate-Binding Domain of Poly[(R)-3-Hydroxybutyrate] (PHB) Depolymerase from Ralstonia pickettii T1 on PHB Degradation

Poly[(R)-3-hydroxybutyrate] (PHB) depolymerase from Ralstonia pickettii T1 (PhaZ_RpiT1) adsorbs to denatured PHB (dPHB) via its substrate-binding domain (SBD) to enhance dPHB degradation. To evaluate the amino acid residues participating in dPHB adsorption, PhaZ_RpiT1 was subjected to a high-throughput screening system consisting of PCR-mediated random mutagenesis targeted to the SBD gene and a plate assay to estimate the effects of mutations in the SBD on dPHB degradation by PhaZ_RpiT1. Genetic analysis of the isolated mutants with lowered activity showed that Ser, Tyr, Val, Ala, and Leu residues in the SBD were replaced by other residues at high frequency. Some of the mutant enzymes, which contained the residues replaced at high frequency, were applied to assays of dPHB degradation and adsorption, revealing that those residues are essential for full activity of both dPHB degradation and adsorption. These results suggested that PhaZ_RpiT1 adsorbs on the surface of dPHB not only via hydrogen bonds between hydroxyl groups of Ser in the enzyme and carbonyl groups in the PHB polymer but also via hydrophobic interaction between hydrophobic residues in the enzyme and methyl groups in the PHB polymer. The L441H enzyme, which displayed lower dPHB degradation and adsorption abilities, was purified and applied to a dPHB degradation assay to compare it with the wild-type enzyme. The kinetic analysis of the dPHB degradation suggested that lowering the affinity of the SBD towards dPHB causes a decrease in the dPHB degradation rate without the loss of its hydrolytic activity for the polymer chain.     

Biosynthesis of Poly(3-Hydroxybutyrate) and Poly(3-Hydroxybutyrate-co-3-Hydroxyvalerate) and Its Regulation in Bacteria

Recent data on the biosynthesis of poly(3-hydroxybutyrate) (PHB) and poly(3-hydroxybutyrate-co-3-hydroxyvalerate) (PHBV) and its regulation in bacteria are reviewed, with special emphasis on the properties and regulation of the relevant enzymes and their genes. Some conditions promoting the synthesis of PHB and PHBV by natural, mutant, and recombinant producers are considered.     

BSA Adsorption on Porous Scaffolds Prepared from BioPEGylated Poly(3-Hydroxybutyrate)

Porous scaffolds for tissue engineering have been prepared from poly(3-hydroxybutyrate) (PHB) and a copolymer of poly(3-hydroxybutyrate) and polyethylene glycol (PHB-PEG) produced by bioPEGylation. The morphology of the scaffolds and their capacity for adsorption of the model protein bovine serum albumin (BSA) have been studied. Scaffolds produced from bioPEGylated PHB adsorbed more BSA, whereas the share of protein irreversibly adsorbed on these scaffolds was significantly lower (33%) than in the case of PHB homopolymer-based scaffolds (47%). The effect of protein adsorption on scaffold biocompatibility in vitro was tested in an experiment that involved the cultivation of fibroblasts (line COS-1) on the scaffolds. PHB-PEG scaffolds had a higher capacity for supporting cell growth than PHB-based scaffolds. Thus, the bioPEGylated PHB-based polymer scaffolds developed in the present study have considerable potential for use in soft tissue engineering.     

Purification and characterization of a serine protease and chitinases from Paecilomyces lilacinus and detection of chitinase activity on 2D gels

The filamentous fungus Paecilomyces lilacinus is currently developed as a biocontrol agent against plant parasitic nematodes. Nematode eggs and cuticles are the infection sites for biocontrol agents that penetrate by the production of lytic enzymes. P. lilacinus was cultured in liquid media and proteases and chitinases were induced by the introduction of egg yolk and chitin, respectively. A serine protease was purified from a culture medium using Sepharose-bacitracin affinity column. The protease occurred in three forms, two of which were C-terminally truncated. Chitinase activity was also observed in the culture supernatant, and after separation by isoelectric focusing six proteins were detected that showed activity. Chitinase activity was further confirmed on non-denaturing one-dimensional (1D) and two-dimensional (2D) gels using a sandwich assay with glycol chitin as a substrate. Two of the proteins had similarities with endochitinases as shown by their N-terminal amino acid sequences.     

Purification and Properties of Poly(A) Polymerase from Vigna unguiculata

Poly(A) polymerase was purified from germinating Vigna unguiculataseeds by successive column chromatography on phosphocellulose,Toyopearl HW-55S, heparin-Sepharose and TSKgel phenyl-5PW, whichyielded two activity fractions. The first fraction was purifiedas a single polypeptide with a mol wt of 63,000 as estimatedby SDS-PAGE. The enzyme activity was highly specific for ATPand required Mn²⁺ ion; an ATP-Mn complex may be the actual substrate.The polymerization reaction required a primer, with varioustypes of RNAs, poly(A) as well as dinucleoside phosphates having3'—OH, serving as efficient primers. The two forms ofthe enzyme had very similar properties with respect to divalentcation requirement and dependency on ion strength, but theyshowed some difference in primer preference. (Received March 4, 1988; Accepted May 2, 1988)     

白腐菌产漆酶的纯化及部分酶学性质

对白腐菌W 1产生的漆酶粗酶液通过超滤浓缩、分子筛和离子交换层析进行纯化 .用SDS PAGE证明该酶的分子量大约为 6 2 4kD .等电聚焦电泳显示该酶的等电点为 3 5 .酶反应的最适温度为 5 0℃ ,最适pH值为 4 5 .此酶氧化DMP的Km 值为 3 84× 10 -5mol L .金属离子对酶活的影响很大 ,其中K+ 、Mn2 + 、Ag+ 对酶活有促进作用 ,Fe2 + 、Fe3 + 、Hg2 + 、Co2 + 、Ba2 + 等对酶活有明显的抑制作用 .酶对部分染料也有一定的脱色效果     

New Recombinant Escherichia coli Strain Tailored for the Production of Poly(3-Hydroxybutyrate) from Agroindustrial By-Products

A recombinant E. coli strain (K24K) was constructed and evaluated for poly(3-hydroxybutyrate) (PHB) production from whey and corn steep liquor as main carbon and nitrogen sources. This strain bears the pha biosynthetic genes from Azotobacter sp. strain FA8 expressed from a T5 promoter under the control of the lactose operator. K24K does not produce the lactose repressor, ensuring constitutive expression of genes involved in lactose transport and utilization. PHB was efficiently produced by the recombinant strain grown aerobically in fed-batch cultures in a laboratory scale bioreactor on a semisynthetic medium supplemented with the agroindustrial by-products. After 24 h, cells accumulated PHB to 72.9% of their cell dry weight, reaching a volumetric productivity of 2.13 g PHB per liter per hour. Physical analysis of PHB recovered from the recombinants showed that its molecular weight was similar to that of PHB produced by Azotobacter sp. strain FA8 and higher than that of the polymer from Cupriavidus necator and that its glass transition temperature was approximately 20°C higher than those of PHBs from the natural producer strains.     

Effects of Aeration on the Synthesis of Poly(3-Hydroxybutyrate) from Glycerol and Glucose in Recombinant Escherichia coli

Bioreactor cultures of Escherichia coli recombinants carrying phaBAC and phaP of Azotobacter sp. FA8 grown on glycerol under low-agitation conditions accumulated more poly(3-hydroxybutyrate) (PHB) and ethanol than at high agitation, while in glucose cultures, low agitation led to a decrease in PHB formation. Cells produced smaller amounts of acids from glycerol than from glucose. Glycerol batch cultures stirred at 125 rpm accumulated, in 24 h, 30.1% (wt/wt) PHB with a relative molecular mass of 1.9 MDa, close to that of PHB obtained using glucose.Polyhydroxyalkanoates (PHAs), accumulated as intracellular granules by many bacteria under unfavorable conditions (5, 8), are carbon and energy reserves and also act as electron sinks, enhancing the fitness of bacteria and contributing to redox balance (9, 11, 19). PHAs have thermoplastic properties, are totally biodegradable by microorganisms present in most environments, and can be produced from different renewable carbon sources (8).Poly(3-hydroxybutyrate) (PHB) is the best known PHA, and its accumulation in recombinant Escherichia coli from several carbon sources has been studied (1, 13). In the last few years, increasing production of biodiesel has caused a sharp fall in the cost of its main by-product, glycerol (22). Its use for microbial PHA synthesis has been analyzed for natural PHA producers, such as Methylobacterium rhodesianum, Cupriavidus necator (formerly called Ralstonia eutropha) (3), several Pseudomonas strains (22), the recently described bacterium Zobellella denitrificans (7), and a Bacillus sp. (18), among others. Glycerol has also been used for PHB synthesis in recombinant E. coli (12, 15). PHAs obtained from glycerol were reported to have a significantly lower molecular weight than polymer synthesized from other substrates, such as glucose or lactose (10, 23).Apart from the genes that catalyze polymer biosynthesis, natural PHA producers have several genes that are involved in granule formation and/or have regulatory functions, such as phasins, granule-associated proteins that have been shown to enhance polymer synthesis and the number and size of PHA granules (17, 24). The phasin PhaP has been shown to exert a beneficial effect on bacterial growth and PHB accumulation from glycerol in bioreactor cultures of strain K24KP, a recombinant E. coli that carries phaBAC and phaP of Azotobacter sp. FA8 (6).Because the redox state of the cells is known to affect the synthesis of PHB (1, 4, 14), the present study investigates the behavior of this recombinant strain under different aeration conditions, by using two substrates, glucose and glycerol, with different oxidation states.     

Poly(3-Hydroxybutyrate) Synthesis Genes in Azotobacter sp. Strain FA8

Genes responsible for the synthesis of poly(3-hydroxybutyrate) (PHB) in Azotobacter sp. FA8 were cloned and analyzed. A PHB polymerase gene (phbC) was found downstream from genes coding for β-ketothiolase (phbA) and acetoacetyl-coenzyme A reductase (phbB). A PHB synthase mutant was obtained by gene inactivation and used for genetic studies. The phbC gene from this strain was introduced into Ralstonia eutropha PHB-4 (phbC-negative mutant), and the recombinant accumulated PHB when either glucose or octanoate was used as a source of carbon, indicating that this PHB synthase cannot incorporate medium-chain-length hydroxyalkanoates into PHB.