Arginine deiminase: recent advances in discovery, crystal structure, and protein engineering for improved properties as an anti-tumor drug.

Arginine deiminase (ADI) is an important arginine-degrading enzyme with wide applications, in particular as an anti-cancer agent for the therapy of arginine-auxotrophic tumors. In recent years, novel ADIs with excellent properties have been identified from various organisms, and crystal structures of ADI were investigated. To satisfy the requirements of potential therapeutic applications, protein engineering has been performed to improve the activity and properties of ADIs. In this mini-review, we systematically summarized the latest progress on identification and crystal structure of ADIs, and protein engineering strategies for improved enzymatic properties, such as pH optimum, K m and k cat values, and thermostability. We also outlined the PEGylation of ADI for improved circulating half-life and immunogenicity, as well as their performance in clinical trials. Finally, perspectives on extracellular secretion and property improvement of ADI were discussed.

Composite coal fly ash solid acid catalyst in synergy with chloride for biphasic preparation of furfural from corn stover hydrolysate.

A solid acid catalyst SO42-/SnO2-Al2O3-CFA was synthesized based on industrial waste coal fly ash (CFA) as carrier and applied in the conversion of oxalic acid pretreated corn stover hydrolysate to produce furfural. Physical properties of the solid acid catalyst were characterized by SEM, FTIR, XRD, BET, EDAX, and NH3-TPD. Highly wrinkled structure of SO42-/SnO2-Al2O3-CFA could provide more specific surface area for the covalent linkage between SiO2 and SnO2. Factors influencing the efficacy of SO42-/SnO2-Al2O3-CFA were systematically explored. The highest furfural yield of 84.7% was reached in NH4Cl-toluene biphasic system at 180 °C for 30 min. The recyclability of SO42-/SnO2-Al2O3-CFA and toluene could be achieved for five batches with stable performance in transformation of xylose-rich corn stover hydrolysate. This study provided a novel solid acid catalyst with promising potential in the synthesis of furfural from corn stover.

Detoxification of furfural residues hydrolysate for butanol fermentation by Clostridium saccharobutylicum DSM 13864.

The toxicity of furfural residues (FRs) hydrolysate is a major obstacle in its application. This work focused on the detoxification of FRs hydrolysate and its application in butanol fermentation. Combination of activated carbon and resin 717 was appropriate for the detoxification of hydrolysate. Mixed sterilization of FRs hydrolysate and corn steep liquor (CSL) was better than the separate ones, since proteins in CSL could adsorb and remove toxic components during sterilization. The results further confirmed that simultaneous sterilization of activated carbon + resin and fermentation medium was more efficient for detoxification and butanol production, in which 76.4% of phenolic compounds and 99.3% of Maillard reaction products were removed, 8.48 g/L butanol and 12.61 g/L total solvent were obtained. This study provides feasible and economic approaches for the detoxification of FRs hydrolysate and its application in butanol production.

Biobutanol production from corn stover hydrolysate pretreated with recycled ionic liquid by Clostridium saccharobutylicum DSM 13864.

In this study, corn stover (CS) hydrolysates, pretreated by fresh and recycled ionic liquid (IL) [Bmim][Cl], were utilized in butanol fermentation by Clostridium saccharobutylicum DSM 13864. An efficient CS pretreatment procedure using [Bmim][Cl] was developed, giving a glucose concentration of 18.7 g L(-1) using ten times recycled [Bmim][Cl], representing about 77% of that produced with fresh IL (24.2 g L(-1)). Fermentation of hydrolysate I (pretreated by fresh IL) resulted in 7.4 g L(-1) butanol with a yield of 0.21 g g total-sugar(-1) and a productivity of 0.11 g L(-1)h(-1), while 7.9 g L(-1) butanol was achieved in fermentation using hydrolysate II (pretreated by ten times reused IL) with similar levels of acetone and ethanol, as well as yield and productivity. This study provides evidence for the efficient utilization of IL in CS pretreatment for biobutanol fermentation.

Cloning, Expression, and Characterization of budC Gene Encoding meso-2,3-Butanediol Dehydrogenase from Bacillus licheniformis.

The budC gene encoding a meso-2,3-butanediol dehydrogenase (BlBDH) from Bacillus licheniformis was cloned and overexpressed in Escherichia coli BL21(DE3). Sequence analysis reveals that this BlBDH belongs to short-chain dehydrogenase/reductase (SDR) superfamily. In the presence of NADH, BlBDH catalyzes the reduction of diacetyl to (3S)-acetoin (97.3% ee), and further to (2S,3S)-2,3-butanediol (97.3% ee and 96.5% de). Similar to other meso-2,3-BDHs, it shows oxidative activity to racemic 2,3-butanediol whereas no activity toward racemic acetoin in the presence of NAD(+). For diacetyl reduction and 2,3-butanediol oxidation, the pH optimum of BlBDH is 5.0 and 10.0, respectively. Unusually, it shows relatively high activity over a wide pH range from 5.0 to 8.0 for racemic acetoin reduction. BlBDH shows lower K m and higher catalytic efficiency toward racemic acetoin (K m = 0.47 mM, k cat /K m = 432 s(-1)·mM(-1)) when compared with 2,3-butanediol (K m = 7.25 mM, k cat /K m = 81.5 s(-1)·mM(-1)), indicating its physiological role in favor of reducing racemic acetoin into 2,3-butanediol. The enzymatic characterization of BlBDH provides evidence for the directed engineering of B. licheniformis for producing enantiopure 2,3-butanediol.

Enhancing cellulose accessibility of corn stover by deep eutectic solvent pretreatment for butanol fermentation.

In this study, an effective corn stover (CS) pretreatment method was developed for biobutanol fermentation. Deep eutectic solvents (DESs), consisted of quaternary ammonium salts and hydrogen donors, display similar properties to room temperature ionic liquid. Seven DESs with different hydrogen donors were facilely synthesized. Choline chloride:formic acid (ChCl:formic acid), an acidic DES, displayed excellent performance in the pretreatment of corn stover by removal of hemicellulose and lignin as confirmed by SEM, FTIR and XRD analysis. After optimization, glucose released from pretreated CS reached 17.0 g L(-1) and yield of 99%. The CS hydrolysate was successfully utilized in butanol fermentation by Clostridium saccharobutylicum DSM 13864, achieving butanol titer of 5.63 g L(-1) with a yield of 0.17 g g(-1) total sugar and productivity of 0.12 g L(-1)h(-1). This study demonstrates DES could be used as a promising and biocompatible pretreatment method for the conversion of lignocellulosic biomass into biofuel.

DNA microarray of global transcription factor mutant reveals membrane-related proteins involved in n-butanol tolerance in Escherichia coli.

BACKGROUND: Escherichia coli has been explored as a platform host strain for biofuels production such as butanol. However, the severe toxicity of butanol is considered to be one major limitation for butanol production from E. coli. The goal of this study is therefore to construct butanol-tolerant E. coli strains and clarify the tolerance mechanisms. RESULTS: A recombinant E. coli strain harboring σ(70) mutation capable of tolerating 2 % (v/v) butanol was isolated by the global transcription machinery engineering (gTME) approach. DNA microarrays were employed to assess the transcriptome profile of butanol-tolerant strain B8. Compared with the wild-type strain, 329 differentially expressed genes (197 up-regulated and 132 down-regulated) (p < 0.05; FC ≥ 2) were identified. These genes are involved in carbohydrate metabolism, energy metabolism, two-component signal transduction system, oxidative stress response, lipid and cell envelope biogenesis and efflux pump. CONCLUSIONS: Several membrane-related proteins were proved to be involved in butanol tolerance of E. coli. Two down-regulated genes, yibT and yghW, were identified to be capable of affecting butanol tolerance by regulating membrane fatty acid composition. Another down-regulated gene ybjC encodes a predicted inner membrane protein. In addition, a number of up-regulated genes, such as gcl and glcF, contribute to supplement metabolic intermediates for glyoxylate and TCA cycles to enhance energy supply. Our results could serve as a practical strategy for the construction of platform E. coli strains as biofuel producer.

Enhanced curdlan production with nitrogen feeding during polysaccharide synthesis by Rhizobium radiobacter.

Curdlan is a secondary metabolite synthesized by Agrobacterium sp. and some other bacteria. A newly isolated exopolysaccharide-producing strain was identified to be Rhizobium radiobacter CGMCC 12099. The polysaccharide product was confirmed to be curdlan with a molecule weight of 1.4×10(5)Da, and its molecular structure was determined by HPLC and infrared spectrum. Although nitrogen source is necessary for cell reproduction, curdlan production is largely dependent on nitrogen limitation, as well as cell vitality. Here, a nitrogen feeding strategy was investigated to elevate the curdlan production by R. radiobacter. The optimal concentration and addition time of (NH4)2HPO4 were investigated. The results showed that the enhanced cell density was correlated to the amount of (NH4)2HPO4 added. Also, nitrogen addition in earlier fermentation stage was beneficial to the cell growth and curdlan production. Furthermore, continuously feeding strategy was employed by feeding (NH4)2HPO4 at a constant rate of 1.24g/h at 35(th)h of fermentation for 9h, achieving a final curdlan production of 65.27g/L, productivity of 0.544g/L/h and glucose conversion rate of 38.89%. The curdlan production was improved by 2.1 times compared with that without nitrogen addition. This study provides a feasible and cheap nitrogen feeding strategy to enhance curdlan production.

Characterization and Soluble Expression of D-Hydantoinase from Pseudomonas fluorescens for the Synthesis of D-Amino Acids.

An active D-hydantoinase from Pseudomonas fluorescens was heterogeneously overexpressed in Escherichia coli BL21(DE3) and designated as D-PfHYD. Sequence and consensus analysis suggests that D-PfHYD belongs to the dihydropyrimidinase/hydantoinase family and possesses catalytic residues for metal ion and hydantoin binding. D-PfHYD was purified to homogeneity by nickel affinity chromatography for characterization. D-PfHYD is a homotetramer with molecular weight of 215 kDa and specific activity of 20.9 U mg(-1). D-PfHYD showed the highest activity at pH 9.0 and 60 °C. Metal ions such as Mn(2+), Fe(2+), and Fe(3+) could activate D-PfHYD with 20 % improvement. Substrate specificity analysis revealed that purified D-PfHYD preferred aliphatic to aromatic 5'-monosubstituted hydantoins. Among various strategies tested, chaperone GroES-GroEL was efficient in improving the soluble expression of D-PfHYD. Employing 1.0 g L(-1) recombinant E. coli BL21(DE3)-pET28-hyd/pGRO7 dry cells, 100 mM isobutyl hydantoin was converted into D-isoleucine with 98.7 % enantiomeric excess (ee), isolation yield of 78.3 %, and substrate to biocatalyst ratio of 15.6. Our results suggest that recombinant D-PfHYD could be potentially applied in the synthesis of D-amino acids.

Simultaneous saccharification and fermentation of dilute alkaline-pretreated corn stover for enhanced butanol production by Clostridium saccharobutylicum DSM 13864.

Simultaneous saccharification and fermentation (SSF) process was applied for biobutanol production by Clostridium saccharobutylicum DSM 13864 from corn stover (CS). The key influential factors in SSF process, including corn steep liquor concentration, dry biomass and enzyme loading, SSF temperature, inoculation size and pre-hydrolysis time were optimized. In 5-L bioreactor with SSF process, butanol titer and productivity of 12.3 g/L and 0.257 g/L/h were achieved at 48 h, which were 20.6% and 21.2% higher than those in separate hydrolysis and fermentation (SHF), respectively. The butanol yield reached 0.175 g/g pretreated CS in SSF, representing 50.9% increase than that in SHF (0.116 g/g pretreated CS). This study proves the feasibility of efficient and economic production of biobutanol from CS by SSF.

Soluble Expression of (+)-γ-Lactamase in Bacillus subtilis for the Enantioselective Preparation of Abacavir Precursor.

Chiral Vince lactam (γ-lactam) is an important precursor of many carbocyclic nucleoside analogues and pharmaceuticals. Here, a (+)-γ-lactamase encoding gene delm from Delftia sp. CGMCC 5755 was identified through genome hunting. To achieve its soluble and functional expression, Escherichia coli and Bacillus subtilis expression systems were introduced. Compared with E. coli system, recombinant (+)-γ-lactamase showed improved protein solubility and catalytic activity in B. subtilis 168. Reaction conditions for enantioselective resolution of γ-lactam were optimized to be at 30 °C, pH 9.0, and 300 rpm when employing the recombinant B. subtilis 168/pMA5-delm whole cells. Kinetic analysis showed that the apparent V max and K m were 0.595 mmol/(min · gDCW) and 378 mmol/L, respectively. No obvious substrate inhibition was observed. In a 500-mL reaction system, enantioselective resolution of 100 g/L γ-lactam was achieved with 10 g/L dry cells, resulting in 55.2 % conversion and 99 % ee of (-)-γ-lactam. All above suggested that recombinant B. subtilis 168/pMA5-delm could potentially be applied in the preparation of optically pure (-)-γ-lactam.

Hydrophobic Mutagenesis and Semi-rational Engineering of Arginine Deiminase for Markedly Enhanced Stability and Catalytic Efficiency.

Due to its systemic arginine degradation, arginine deiminase (ADI) has attracted attentions as an anti-tumor drug. Its low activity at physiological conditions among other limitations has necessitated its engineering for improved properties. The present study describes the hydrophobic mutagenesis and semi-rational engineering of ADI from Pseudomonas plecoglossicida (PpADI). Using an improved ADI variant M13 (D38H/A128T/E296K/H404R/I410L) as parent, site saturation mutagenesis at position 162 resulted in an over 20 % increase in protein solubility. Compared with M13 (15.23 U/mg), mutants M13-2 (M13+S245D) and M13-5 (M13+R243L) exhibited enhanced specific activity of 21.19 and 31.20 U/mg at physiological conditions. M13-5 displayed enhanced substrate specificity with a dramatic reduction in its K m value (from 0.52 to 0.16 mM). It is speculated that the improvements in M13-5 could mainly be attributed to the enhanced structural stability due to an R243L substitution. The hydrophobic contribution of Leu 243 was supported by mutant M13-9 (M13+A276W) generated based on the hydrophobic mutagenesis concept. M13-9 showed a specific activity of 18.68 U/mg, as well as remarkable thermal and pH stability. It retained over 90 % activity over pH range from 4.5 to 8.5. At 60 °C, the half-life of M13-9 was enhanced from 4 to 17.5 min in comparison with M13, and its specific activity at 62 °C (93.0 U/mg) was approximately fivefold of that determined at 37 °C. Our results suggest that the increased hydrophobicity around the active regions of PpADI might be crucial in improving its structural stability and ultimately catalytic efficiency.