Molecular Cloning of the Phytase Gene from Citrobacter braakii and its Expression in Saccharomyces cerevisiae

The gene, appA, encoding phytase was cloned from a size-selected genomic library of Citrobacter braakii YH-15 by Southern hybridization using a degenerate probe based on the N-terminal amino acid sequence of the phytase. The deduced amino acid sequence of appA contained the N-terminal RHGXRXP motif and the C-terminal HD motif, which are common in histidine acid phosphatases. It also had significant homology (60% identity) with phytase from Escherichia coli, while the physical mapping analysis of appA revealed that gene organization near appA in C. braakii was similar to that in Salmonella typhimurium genome. C. braakii AppA contained five putative N-glycosylation sites. The recombinant phytases, rAppA_Ec and rAppA_Sc, were produced in E. coli and Saccharomyces cerevisiae, respectively, with both being fused with C-terminal His-tag. After purification, rAppA_Sc was shown to be hyperglycosylated by Endo-H treatment. It had greater thermostability than the wild type phytase and rAppA_Ec.     

AppA C-terminal Plays an Important Role in its Thermostability in Escherichia coli

Due to our previous research, mainly the thermostable mutants Q307D, Y311K, and I427L, we conjectured that Escherichia coli AppA phytase’s C-terminal plays an important role in its thermostability, and AppA begins to collapse from the C-terminal when at a higher temperature. So here we constructed C-lose mutant to prove it. The residual activities of the wild-type AppA phytase and C-lose were 31.42 and 70.49 %, respectively, after being heated at 80 °C for 10 min. The C-terminal deletion mutant C-lose showed 39.07 % thermostability enhancement than the wild-type both without the pH and temperature optimum changed. It proved the C-lose plays a key role in E. coli AppA phytase’s thermostability.     

Enhancing thermostability of <Emphasis Type="Italic">Escherichia coli</Emphasis> phytase AppA2 by error-prone PCR

Phytases are used to improve phosphorus nutrition of food animals and reduce their phosphorus excretion to the environment. Due to favorable properties, Escherichia coli AppA2 phytase is of particular interest for biotechnological applications. Directed evolution was applied in the present study to improve AppA2 phytase thermostability for lowering its heat inactivation during feed pelleting (60–80°C). After a mutant library of AppA2 was generated by error-prone polymerase chain reaction, variants were expressed initially in Saccharomyces cerevisiae for screening and then in Pichia pastoris for characterizing thermostability. Compared with the wild-type enzyme, two variants (K46E and K65E/K97M/S209G) showed over 20% improvement in thermostability (80°C for 10 min), and 6–7°C increases in melting temperatures (T _m). Structural predictions suggest that substitutions of K46E and K65E might introduce additional hydrogen bonds with adjacent residues, improving the enzyme thermostability by stabilizing local interactions. Overall catalytic efficiency (k _cat / K _m) of K46E and K65E/K97M/S209G was improved by 56% and 152% than that of wild type at pH 3.5, respectively. Thus, the catalytic efficiency of these enzymes was not inversely related to their thermostability.     

Transgenic microalgae expressing <Emphasis Type="Italic">Escherichia coli</Emphasis> AppA phytase as feed additive to reduce phytate excretion in the manure of young broiler chicks

Microbial phytases are widely used as feed additive to increase phytate phosphorus utilization and to reduce fecal phytates and inorganic phosphate (iP) outputs. To facilitate the process of application, we engineered an Escherichia coli appA phytase gene into the chloroplast genome of the model microalga, Chlamydomonas reinhardtii, and isolated homoplasmic plastid transformants. The catalytic activity of the recombinant E. coli AppA can be directly detected in the whole-cell lysate, termed Chlasate, prepared by freeze-drying the transgenic cell paste with liquid nitrogen. The E. coli AppA in the Chlasate has a pH and temperature optima of 4.5 and 60°C, respectively, which are similar to those described in the literature. The phytase-expressed Chlasate contains 10 phytase units per gram dry matter at pH 4.5 and 37°C. Using this transgenic Chlasate at 500 U/kg of diet for young broiler chicks, the fecal phytate excretion was reduced, and the iP was increased by 43% and 41%, respectively, as compared to those of the chicks fed with only the basal diet. The effectiveness of the Chlasate to break down the dietary phytates is compatible with the commercial Natuphos fungal phytase. Our data provide the first evidence of functional expression of microbial phytase in microalgae and demonstrate the proof of concept of using transgenic microalgae as a food additive to deliver dietary enzymes with no need of protein purification.     

Cloning and Expression of Phytase appA Gene from Shigella sp. CD2 in Pichia pastoris and Comparison of Properties with Recombinant Enzyme Expressed in E. coli

The phytase gene appA_S was isolated from Shigella sp. CD2 genomic library. The 3.8 kb DNA fragment contained 1299 bp open reading frame encoding 432 amino acid protein (AppA_S) with 22 amino acid signal peptide at N-terminal and three sites of N-glycosylation. AppA_S contained the active site RHGXRXP and HDTN sequence motifs, which are conserved among histidine acid phosphatases. It showed maximum identity with phytase AppA of Escherichia coli and Citrobacter braakii. The appA_S was expressed in Pichia pastoris and E. coli to produce recombinant phytase rAppA_P and rAppA_E, respectively. Purified glycosylated rAppA_P and nonglycosylated rAppA_E had specific activity of 967 and 2982 U mg^-1, respectively. Both had pH optima of 5.5 and temperature optima of 60°C. Compared with rAppA_E, rAppA_P was 13 and 17% less active at pH 3.5 and 7.5 and 11 and 18% less active at temperature 37 and 50°C, respectively; however, it was more active at higher incubation temperatures. Thermotolerance of rAppA_P was 33% greater at 60°C and 24% greater at 70°C, when compared with rAppA_E. Both the recombinant enzymes showed high specificity to phytate and resistance to trypsin. To our knowledge, this is the first report on cloning and expression of phytase from Shigella sp.     

A multi-factors rational design strategy for enhancing the thermostability of Escherichia coli AppA phytase

Despite recent advances in our understanding of the importance of protein surface properties for protein thermostability,there are seldom studies on multi-factors rational design strategy, so a more scientific, simple and effective rational strategy is urgent for protein engineering. Here, we first attempted to use a three-factors rational design strategy combining three common structural features, protein flexibility, protein surface, and salt bridges. Escherichia coli AppA phytase was used as a model enzyme to improve its thermostability. Moreover, the structure and enzyme features of the thermostable mutants designed by our strategy were analyzed roundly. For the single mutants, two (Q206E and Y311K), in five exhibited thermostable property with a higher success rate of prediction (40 %). For the multiple mutants, the themostable sites were combined with another site, I427L, we obtained by directed evolution, Q206E/I427L, Y311K/I427L, and Q206E/Y311K/I427L, all exhibited thermostable property. The Y311K/I427L doubled thermostability (61.7 %, and was compared to 30.97 % after being heated at 80 °C for 10 min) and catalytic efficiency (4.46 was compared to 2.37) improved more than the wild-type AppA phytase almost without hampering catalytic activity. These multi-factors of rational design strategy can be applied practically as a thermostabilization strategy instead of the conventional single-factor approach.     

Mutational analysis of a catalytically important loop containing active site and substrate-binding site in Escherichia coli phytase AppA

A phytase from Escherichia coli, AppA, has been the target of protein engineering to reduce the amount of undigested phosphates from livestock manure by making phosphorous from phytic acid available as a nutrient. To understand the contribution of each amino acid in the active site loop to the AppA activity, alanine and glycine scanning mutagenesis was undertaken. The results of phytase activity assay demonstrated loss of activity by mutations at charged residues within the conserved motif, supporting their importance in catalytic activity. In contrast, both conserved, non-polar residues and non-conserved residues tended to be tolerant to Ala and/or Gly mutations. Correlation analyses of chemical/structural characteristics of each mutation site against mutant activity revealed that the loop residues located closer to the substrate have greater contribution to the activity of AppA. These results may be useful in efficiently engineering AppA to improve its catalytic activity.

Abbreviations: AppA: pH 2.5 acid phosphatase; CSU: contacts of structural units; HAPs: histidine acid phosphatases; SASA: solvent accessible surface area; SDS-PAGE: sodium dodecyl sulfate-polyacrylamide gel electrophoresis; SSM: site-saturation mutagenesis; WT: wild type     

Cloning, Sequencing and Characterization of a Novel Phosphatase Gene, phoI, from Soil Bacterium Enterobacter sp. 4

A gene, phoI, coding for a phosphatase from Enterobacter sp. 4 was cloned in Escherichia coli and sequenced. Analysis of the sequence revealed one open reading frame (ORF) that encodes a 269–amino acid protein with a calculated molecular mass of 29 kDa. PhoI belongs to family B acid phosphatase and exhibits 49.4% identity and 62.4% homology to the hel gene from Heamophilus influenzae, which encoded an outer membrane protein (P4). The optimum pH and temperature for phosphatase activity were pH 5.5 and 40°C, respectively. Its specific activity on ρ-nitrophenyl phosphatate was 70 U/mg at pH 5.5 and 40°C. Enzyme activity was inhibited by Al³⁺, EDTA, and DTT, but fivefold activated by Cu²⁺ ion (350 U/mg). PhoI showed a strong synergistic effect when used with a purified E. coli phytase, AppA, to estimate combination effects. Seung Ha Kang and Kwang Keun Cho contributed equally to this work.     

Expression of <Emphasis Type="Italic">Escherichia coli</Emphasis> AppA2 phytase in four yeast systems

To develop an effective fermentation system for producing Escherichia coliphytase AppA2, we expressed the enzyme in three inducible yeast systems: Saccharomyces cerevisiae (pYES2), Schizosaccharomyces pombe (pDS472a), and Pichia pastoris (pPICZ A), and one constitutive system: P. pastoris (pGAPZA). All four systems produced an extracellular functional AppA2 phytase with apparent molecular masses ranging from 51.5 to 56 kDa. During 8-day batch fermentation in shaking flasks, the inducible Pichia system produced the highest activity (272 units ml^–1 medium), whereas the Schizo. pombesystem produced the lowest activity (2.8 units ml^–1). The AppA2 phytase expressed in Schizo. pombehad 60–75% lower K_mfor sodium phytate and 28% higher heat-stability at 65 °C than that expressed in other three systems. However, all four recombinant AppA2 phytases had pH optimum at 3.5 and temperature optimum at 55 °C and similar efficacy in hydrolyzing phytate–phosphate from soybean meal.Revisions requested 18 November 2004; Revisions received 7 January 2005     

Development of an Escherichia coli expression system and thermostability screening assay for libraries of mutant xylanase

A thermostability screening assay was developed using an Escherichia coli expression system to express Streptomyces lividans xylanase A (XlnA). The screening system was tested using mutants randomized at position 49 of the S. lividans XlnA gene, a position previously shown to confer thermostability with a I49P point mutation. The library was cloned into an E. coli expression vector and transformed into XL1-blue bacteria. The resulting clones were screened for increased thermostability with respect to wild-type XlnA. Using this assay, we isolated the I49P mutant previously shown to be thermostable, as well as novel I49A and I49C mutants. The I49A and I49C mutants were shown to have 2.8- to 8-fold increase in thermostability over that of wild-type XlnA. The results show that the screening assay can selectively enrich for clones with increased thermostability and is suitable for screening small- to medium-sized libraries of 5000–20,000 clones. Journal of Industrial Microbiology & Biotechnology (2000) 25, 310–314. Received 18 May 2000/ Accepted in revised form 19 September 2000     

Identification of the gene appA for the acid phosphatase (pH optimum 2.5) of Escherichia coli

Summary A strain of Escherichia coli exhibiting reduced activity of the periplasmic enzyme acid phosphoanhydride phosphohydrolase (pH 2.5 acid phosphatase) was isolated. The mutation designated appA1 was located at 22.5 min on the E. coli genetic map. Acid phosphatase purified from an appA ^–transductant showed less than ten percent of the specific activity of an isogenic appA ⁺strain. The mutant enzyme was highly thermolabile and its K_m for paranitrophenyl phosphate was increased about 20-fold. The mutant protein cross-reacted with antibody to the wild-type enzyme and had the same molecular weight and concentration in extracts as the wild-type enzyme. These findings strongly suggest that appA is the structural gene of the acid phosphatase.Abbreviations PNPP paranitrophenyl phosphate - cAMP 3-5-cyclic adenosine monophosphate - Nitrosoguanidine N-methyl-N'-nitro-N-nitrosoguanidine - TCY tetracycline - KAN kanamycin - STR streptomycin     

Overexpression of phyA and appA Genes Improves Soil Organic Phosphorus Utilisation and Seed Phytase Activity in Brassica napus

Phytate is the major storage form of organic phosphorus in soils and plant seeds, and phosphorus (P) in this form is unavailable to plants or monogastric animals. In the present study, the phytase genes phyA and appA were introduced into Brassica napus cv Westar with a signal peptide sequence and CaMV 35S promoter, respectively. Three independent transgenic lines, P3 and P11 from phyA and a18 from appA, were selected. The three transgenic lines exhibited significantly higher exuded phytase activity when compared to wild-type (WT) controls. A quartz sand culture experiment demonstrated that transgenic Brassica napus had significantly improved P uptake and plant biomass. A soil culture experiment revealed that seed yields of transgenic lines P11 and a18 increased by 20.9% and 59.9%, respectively, when compared to WT. When phytate was used as the sole P source, P accumulation in seeds increased by 20.6% and 46.9% with respect to WT in P11 and a18, respectively. The P3 line accumulated markedly more P in seeds than WT, while no significant difference was observed in seed yields when phytate was used as the sole P source. Phytase activities in transgenic canola seeds ranged from 1,138 to 1,605 U kg^–1 seeds, while no phytase activity was detected in WT seeds. Moreover, phytic acid content in P11 and a18 seeds was significantly lower than in WT. These results introduce an opportunity for improvement of soil and seed phytate-P bioavailability through genetic manipulation of oilseed rape, thereby increasing plant production and P nutrition for monogastric animals.     

Cloning and expression of Bacillus phytase gene (phy) in Escherichia coli and recovery of active enzyme from the inclusion bodies

Aims: To isolate, clone and express a novel phytase gene (phy) from Bacillus sp. in Escherichia coli; to recover the active enzyme from inclusion bodies; and to characterize the recombinant phytase. Methods and Results: The molecular weight of phytase was estimated as 40 kDa on SDS-polyacrylamide gel electrophoresis. A requirement of Ca²⁺ ions was found essential both for refolding and activity of the enzyme. Bacillus phytase exhibited a specific activity of 16 U mg⁻¹ protein; it also revealed broad pH and temperature ranges of 5·0 to 8·0 and 25 to 70°C, respectively. The K_m value of phytase for hydrolysis of sodium phytate has been determined as 0·392 mmol l⁻¹. The activity of enzyme has been inhibited by EDTA. The enzyme exhibited ample thermostability upon exposure to high temperatures from 75 to 95°C. After 9 h of cultivation of transformed E. coli in the bioreactor, the cell biomass reached 26·81 g wet weight (ww) per l accounting for 4289 U enzyme activity compared with 1·978 g ww per l producing 256 U activity in shake-flask cultures. In silico analysis revealed a β-propeller structure of phytase. Conclusions: This is the first report of its kind on the purification and successful in vitro refolding of Bacillus phytase from the inclusion bodies formed in the transformed E. coli. Significance and Impact of the Study: Efficient and reproducible protocols for cloning, expression, purification and in vitro refolding of Bacillus phytase enzyme from the transformed E. coli have been developed. The novel phytase, with broad pH and temperature range, renaturation ability and substrate specificity, appears promising as an ideal feed supplement. Identification of site between 179th amino acid leucine and 180th amino acid asparagine offers scope for insertion of small peptides/domains for production of chimeric genes without altering enzyme activity.     

Cloning and characterization of the pH 2.5 acid phosphatase gene, appA: Cyclic AMP mediated negative regulation

Summary The structural gene for an acid phosphatase coded for by the gene appA of Escherichia coli K12 was cloned from a cosmid library into pBR322 and the restriction map determined. Several appA deletion plasmids and a smaller appA ⁺ plasmid were constructed by in vitro recombination techniques and tested for their ability to complement an appA1 mutation. The appA gene was localized within a 2.1 kb segment. Its orientation was determined by construction of a hybrid plasmid carrying an appA-lacZ fusion. -galactosidase synthesized from the appA promoter was negatively regulated by cyclic AMP.     

Comparison of extracellular Escherichia coli AppA phytases expressed in Streptomyces lividans and Pichia pastoris

A phytase gene (appA) from Escherichia coli was cloned into Streptomyces lividans and expressed as an extracellular protein which was then compared with the same enzyme expressed in Pichia pastoris. The phytase expressed in S. lividans was not glycosylated and had a molecular mass of 45 kDa. Compared with the glycosylated phytase expressed in P. pastoris, this non-glycosylated phytase was 25–50% less active (p<0.05) at pH 2 to 3.5 or at 45 and 55 °C, but 50% more active (p<0.05) at 75 °C. The thermo-tolerance of the non-glycosylated phytase was 26 and 48% higher (p<0.05) than that of the glycosylated phytase at 45 and 55 °C, but was 80 and 94% lower (p<0.05) at 65 ° and 75 °C, respectively.     

Phytase activity in rabbit cecal bacteria

The presence of phytase activity was demonstrated in 26 strains of rabbit cecal bacteria. In 25 strains a low phytase activity, 0.10–0.62 μmol phosphate released per min per mg protein, was found. High activity (2.61 μmol/min per mg protein) was found in the strain PP2 identified as Enterococcus hirae. Phytase activity was cell-associated, being higher in the cell extract than in the cell walls. Extracellular phytase activity and cell-associated phosphatase activity were not detected. Phytase activity was optimal around pH 5.0, which is below the physiological cecal pH range. The K _m determined using the Lineweaver-Burk plot was 0.19 μmol/mL. Cations Fe³⁺, Cu²⁺ and Zn²⁺ at 0.5 mmol/L decreased phytase activity in sonicated cells of E. hirae by 99.4, 90.7 and 96.5 %, respectively. In contrast, Mg²⁺ increased activity by 11.0 %. Characteristics of E. hirae phytase (pH optimum, K _m, cation sensitivity) were similar to those of other bacterial phytases reported in the literature. Other bacteria with a high phytase activity may be present in the rabbit cecum but remain to be identified.     

Characterization of phytase produced byAspergillus niger

The extracellular activity ofAspergillus niger phytase at the end of the growth phase was 132 nkat/mL in a laboratory bioreactor. The purified enzyme has molar mass approximately 100 kDa, pH optimum at 5.0, temperature optimum at 55°C and high pH and temperature stability. TheK _m for dodecasodium phytate, calcium phytate and 4-nitrophenyl phosphate are 0.44, 0.45 and 1.38 mmol/L, respectively. The enzyme is noncompetively inhibited by inorganic monophosphate (K _i=2.85 mmol/L) and by Cu²⁺, Zn²⁺, Hg²⁺, Sn²⁺, Cd²⁺ ions and strongly by F⁻ ones; it is activated by Ca²⁺, Mg²⁺ and Mn²⁺ ions. The substrate specificity of phytase is broad with the highest affinity to calcium phytate.     

Production and partial characterization of two types of phytase from Aspergillus niger NCIM 563 under submerged fermentation conditions

Novel extracellular phytase was produced by Aspergillus niger NCIM 563 under submerged fermentation conditions at 30 °C in medium containing dextrin and glucose as carbon sources along with sodium nitrate as nitrogen source. Maximum phytase activity (41.47 IU/mL at pH 2.5 and 10.71 IU/mL at pH 4.0) was obtained when dextrin was used as carbon source along with glucose and sodium nitrate as nitrogen source. Nearly 13 times increase in phytase activity was observed when phosphate in the form of KH₂PO₄ (0.004 g/100 mL) was added in the fermentation medium. Physic-chemical properties of partially purified enzyme indicate the possibility of two distinct forms of phytases, Phy I and Phy II. Optimum pH and temperature for Phy I was 2.5 and 60 °C while Phy II was 4.0 and 60 °C, respectively. Phy I was stable in the pH range 1.5–3.5 while Phy II was stable in the wider pH range, 2.0–7.0. Molecular weight of Phy I and Phy II on Sephacryl S-200 was approximately 304 kDa and 183 kDa, respectively. Phy I activity was moderately stimulated in the presence of 1 mM Mg²⁺, Mn²⁺, Ca²⁺ and Fe³⁺ ions and inhibited by Zn²⁺ and Cd²⁺ ions while Phy II activity was moderately stimulated by Fe³⁺ ions and was inhibited by Hg²⁺, Mn²⁺ and Zn²⁺ ions at 1 mM concentration in reaction mixture. The Km for Phy I and II was 3.18 and 0.514 mM while Vmax was 331.16 and 59.47 μmols/min/mg protein, respectively.     

Cloning and High-Level Expression of the Enzymatic Region of Phytase in E. coli

Phytase is an important enzyme poses great nutritional significance in humans and monogastric animals diets. The phytase production yield using wild sources, including micro-organisms, plants, and animals is sorely low. Thus, recombinant expression of phytase has received increasing interest for achieving production rate. Escherichia coli is the most preferred host for expression of heterologous proteins but overexpression of recombinant phytase in E. coli, met with limited success due to the sequestration of the enzyme into inclusion bodies. In the present study, artificial phytases gene with excellent thermostability and activity were designed by detecting the enzymatic region of the E. coli phytase gene by employing bioinformatics tools. Then, the PCR amplified recombinant gene was expressed in E. coli and the active enzyme was recovered from inclusion bodies. Employing cysteine amino acid in the dialysis buffer succeed to the superior activity of the enzyme with a specific activity of 73.8 U/mg. The optimum temperature and pH for enzyme activity were determined at 60 °C and 4, respectively. The novel recombinant enzyme illustrated perfect thermostability up to 70 °C with maintenance 75% of its activity. The enzyme was stable at pH range of 2–10. Moreover, the effects of ions and chemical compounds on enzyme stability and activity were assessed.