Biochemical characteristics of phytases from fungi and the transformed microorganism

Five sources of phytases were used to study their biochemical characteristics. Phytase E was from an original Escherichia coli (E. coli), phytase PI and PG from the transformed Pichia pastoris (P. pastoris) with phytase gene of E. coli, phytase B and R from Aspergillus niger (A. niger). The results showed that the relative phytase activities had no significant changes when temperature was below 60 °C (P>0.05), and then decreased significantly with temperature increasing (P<0.01). The fungal phytase with the phytase gene from A. niger had the higher thermostability than the bacterial phytase with the phytase gene from E. coli; i.e. at 70 °C, 27–58% of phytase activity (compared with 30 °C) was retained for the bacterial phytase, and 73–96% for the fungal phytase; at 90 °C, 20–47% was retained for the bacterial phytase, and 41–52% for the fungal phytase, especially for the most thermostable phytase R (P<0.01). The optimum pH ranges were 3.0–4.5 for the bacterial phytases and 5.0–5.5 for the fungal phytases (P<0.01). When pH levels were 1, 7 and 8, only 3–7% of phytase activity (compared with the maximum phytase activity at a pH point) was retained for both bacterial and fungal phytases. The amount of inorganic P released from soybean meal was significantly increased when the levels of phytase activity in the soybean meal increased from 0 to 1.0 U/g soybean meal (P<0.01), except for phytase PI. The maximum P released was obtained at 1 U/g soybean meal for all five kinds of phytases (P<0.01). The most economical phytase concentration for P released was 0.25 U/g for phytase PI and B, and 0.50–1.0 U/g for phytase PG, E and R. In addition, the linear and non-linear regression models were established to estimate phytase activity and its characteristics very easily and economically.     

Biophysical Characterization of Fungal Phytases (myo-Inositol Hexakisphosphate Phosphohydrolases): Molecular Size, Glycosylation Pattern, and Engineering of Proteolytic Resistance

Phytases (myo-inositol hexakisphosphate phosphohydrolases) are found naturally in plants and microorganisms, particularly fungi. Interest in these enzymes has been stimulated by the fact that phytase supplements increase the availability of phosphorus in pig and poultry feed and thereby reduce environmental pollution due to excess phosphate excretion in areas where there is intensive livestock production. The wild-type phytases from six different fungi, Aspergillus niger, Aspergillus terreus, Aspergillus fumigatus, Emericella nidulans, Myceliophthora thermophila, and Talaromyces thermophilus, were overexpressed in either filamentous fungi or yeasts and purified, and their biophysical properties were compared with those of a phytase from Escherichia coli. All of the phytases examined are monomeric proteins. While E. coli phytase is a nonglycosylated enzyme, the glycosylation patterns of the fungal phytases proved to be highly variable, differing for individual phytases, for a given phytase produced in different expression systems, and for individual batches of a given phytase produced in a particular expression system. Whereas the extents of glycosylation were moderate when the fungal phytases were expressed in filamentous fungi, they were excessive when the phytases were expressed in yeasts. However, the different extents of glycosylation had no effect on the specific activity, the thermostability, or the refolding properties of individual phytases. When expressed in A. niger, several fungal phytases were susceptible to limited proteolysis by proteases present in the culture supernatant. N-terminal sequencing of the fragments revealed that cleavage invariably occurred at exposed loops on the surface of the molecule. Site-directed mutagenesis of A. fumigatus and E. nidulans phytases at the cleavage sites yielded mutants that were considerably more resistant to proteolytic attack. Therefore, engineering of exposed surface loops may be a strategy for improving phytase stability during feed processing and in the digestive tract.     

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 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.

     

Design of Thermostable Beta-Propeller Phytases with Activity over a Broad Range of pHs and Their Overproduction by Pichia pastoris

Thermostable phytases, which are active over broad pH ranges, may be useful as feed additives, since they can resist the temperatures used in the feed-pelleting process. We designed new beta-propeller phytases, using a structure-guided consensus approach, from a set of amino acid sequences from Bacillus phytases and engineered Pichia pastoris strains to overproduce the enzymes. The recombinant phytases were N-glycosylated, had the correct amino-terminal sequence, showed activity over a pH range of 2.5 to 9, showed a high residual activity after 10 min of heat treatment at 80°C and pH 5.5 or 7.5, and were more thermostable at pH 7.5 than a recombinant form of phytase C from Bacillus subtilis (GenBank accession no. {"type":"entrez-protein","attrs":{"text":"AAC31775","term_id":"2599490","term_text":"AAC31775"}}AAC31775). A structural analysis suggested that the higher thermostability may be due to a larger number of hydrogen bonds and to the presence of P257 in a surface loop. In addition, D336 likely plays an important role in the thermostability of the phytases at pH 7.5. The recombinant phytases showed higher thermostability at pH 5.5 than at pH 7.5. This difference was likely due to a different protein total charge at pH 5.5 from that at pH 7.5. The recombinant beta-propeller phytases described here may have potential as feed additives and in the pretreatment of vegetable flours used as ingredients in animal diets.Phytases (myo-inositol hexakisphosphate phosphohydrolases; EC 3.1.3.8, EC 3.1.3.26, and EC 3.1.3.72) hydrolyze phytate (myo-inositol hexakisphosphate), the major storage form of phosphorus in feeds of plant origin (27). Monogastric and agastric animals, such as pigs, poultry, and fish, cannot utilize dietary phosphorus because their gastrointestinal tracts are deficient in enzymes with phytase activity (27, 28, 30). Therefore, these enzymes have significant value as animal feed additives.Based on the presence of a specific consensus motif and their three-dimensional structures, phytases are classified into four major classes: histidine acid, beta-propeller, cysteine, and purple acid phytases (28, 30). Most of the commercially available phytases are histidine acid phytases derived from fungi (of the genus Aspergillus) and possess catalytic activity in the pH range of 2.5 to 6. On the other hand, bacterial phytases from the genus Bacillus are beta-propeller phytases. These phytases are structurally different from the fungal phytases, possess a pH optimum close to 7, and exhibit activity within a range of pHs that is broader than that of the fungal phytases (16, 22, 23, 35). Because animal feeds are commonly pelleted, a useful phytase additive should resist the temperatures of the pelleting process.Among the protein-engineering strategies described for improving protein thermostability, data-driven protein design uses available sequences and structures to predict potential stabilizing amino acids as targets for mutation. Specifically, stabilizing amino acids can be predicted from the consensus amino acid sequence for homologous proteins, thus reducing the number of candidates to be tested experimentally. This approach has been applied successfully to engineer protein thermostability (25, 26). A further improvement is the structure-guided consensus approach, which uses structural information to further reduce the number of protein candidates to be tested for thermostability (37).The methylotrophic yeast Pichia pastoris has been developed as a host for the efficient production and secretion of foreign proteins (20). Protein-engineering strategies that use P. pastoris as the host can improve both protein thermostability and protein overproduction. Therefore, we designed new beta-propeller phytases with a high probability of being thermostable and with a broad range of pH activities. We used a structure-guided consensus approach and a set of amino acid sequences from Bacillus phytases. We engineered P. pastoris strains to introduce phytase-encoding sequences that harbor P. pastoris-preferred codons to overproduce the designed phytases. In addition, the produced phytases were characterized biochemically, and their thermostabilities were correlated with protein structures.     

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.     

Biochemical Characterization of Fungal Phytases (myo-Inositol Hexakisphosphate Phosphohydrolases): Catalytic Properties

Supplementation with phytase is an effective way to increase the availability of phosphorus in seed-based animal feed. The biochemical characteristics of an ideal phytase for this application are still largely unknown. To extend the biochemical characterization of wild-type phytases, the catalytic properties of a series of fungal phytases, as well as Escherichia coli phytase, were determined. The specific activities of the fungal phytases at 37°C ranged from 23 to 196 U · (mg of protein)⁻¹, and the pH optima ranged from 2.5 to 7.0. When excess phytase was used, all of the phytases were able to release five phosphate groups of phytic acid (myo-inositol hexakisphosphate), which left myo-inositol 2-monophosphate as the end product. A combination consisting of a phytase and Aspergillus niger pH 2.5 acid phosphatase was able to liberate all six phosphate groups. When substrate specificity was examined, the A. niger, Aspergillus terreus, and E. coli phytases were rather specific for phytic acid. On the other hand, the Aspergillus fumigatus, Emericella nidulans, and Myceliophthora thermophila phytases exhibited considerable activity with a broad range of phosphate compounds, including phenyl phosphate, p-nitrophenyl phosphate, sugar phosphates, α- and β-glycerophosphates, phosphoenolpyruvate, 3-phosphoglycerate, ADP, and ATP. Both phosphate liberation kinetics and a time course experiment in which high-performance liquid chromatography separation of the degradation intermediates was used showed that all of the myo-inositol phosphates from the hexakisphosphate to the bisphosphate were efficiently cleaved by A. fumigatus phytase. In contrast, phosphate liberation by A. niger or A. terreus phytase decreased with incubation time, and the myo-inositol tris- and bisphosphates accumulated, suggesting that these compounds are worse substrates than phytic acid is. To test whether broad substrate specificity may be advantageous for feed application, phosphate liberation kinetics were studied in vitro by using feed suspensions supplemented with 250 or 500 U of either A. fumigatus phytase or A. niger phytase (Natuphos) per kg of feed. Initially, phosphate liberation was linear and identical for the two phytases, but considerably more phosphate was liberated by the A. fumigatus phytase than by the A. niger phytase at later stages of incubation.     

Chimeric gene construct coding for bi-functional enzyme endowed with endoglucanase and phytase activities

Phytase and endoglucanase enzymes are being widely used as feed additives in poultry industry. In our earlier studies, the Bacillus phytase, when expressed in Escherichia coli, was found in inclusion bodies, whereas endoglucanase was found in active soluble form. Herein, we report the development of a chimeric gene construct coding for ~73 kDa fusion protein and its over-expression in E. coli in soluble form. The novel enzyme exhibited both endoglucanase and phytase activities across broad pH (4.0–8.0) and temperature (25–75°C) ranges. As such, the bi-functional enzyme seems promising and might serve as a potential feed additive for enhanced nutrition uptake in monogastric animals.     

Two Types of Phytases (Histidine Acid Phytase and β-Propeller Phytase) in <Emphasis Type="Italic">Serratia</Emphasis> sp. TN49 from the Gut of <Emphasis Type="Italic">Batocera horsfieldi</Emphasis> (Coleoptera) Larvae

Microbial phytases play a major role in the mineralization of organic phosphorous, especially in symbiotic plants and animals. In this study, we identified two types of phytases in Serratia sp. TN49 that was harbored in the gut of Batocera horsfieldi (Coleoptera) larvae. The two phytases, an acidic histidine acid phosphatase (PhyH49) and an alkaline β-propeller phytase (PhyB49), shared low identities with known phytases (61% at most). PhyH49 and PhyB49 produced in Escherichia coli exhibited maximal activities at pH 5.0 (60°C) and pH 7.5–8.0 (45°C), respectively, and are complementary in phytate degradation over the pH range 2.0–9.0. Serratia sp. TN49 harboring both PhyH49 and PhyB49 might make it more adaptive to environment change, corresponding to the evolution trend of microorganism.     

Impact of oxygen supply on rtPA expression in <Emphasis Type="Italic">Escherichia coli</Emphasis> BL21 (DE3): ammonia effects

A phytase with high activity at neutral pH and typical water temperatures (∼25°C) could effectively hydrolyze phytate in aquaculture. In this study, a phytase-producing strain, Pedobacter nyackensis MJ11 CGMCC 2503, was isolated from glacier soil, and the relevant gene, PhyP, was cloned using degenerate PCR and thermal asymmetric interlaced PCR. To our knowledge, this is the first report of detection of phytase activity and cloning of phytase gene from Pedobacter. PhyP belongs to beta-propeller phytase family and shares very low identity (∼28.5%) with Bacillus subtilis phytase. The purified recombinant enzyme (r-PhyP) from Escherichia coli displayed high specific activity for sodium phytate of 24.4 U mg⁻¹. The optimum pH was 7.0, and the optimum temperature was 45°C. The K _m, V _max, and k _cat values were 1.28 mM, 71.9 μmol min⁻¹ mg⁻¹, and 45.1 s⁻¹, respectively. Compared with Bacillus phytases, r-PhyP had higher relative activity at 25°C (r-PhyP (>50%), B. subtilis phytase (<8%)) and hydrolyzed phytate from soybean with greater efficacy at neutral pH. These characteristics suggest that r-PhyP might be a good candidate for an aquatic feed additive in the aquaculture industry.     

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.     

Adsorption immobilization of Escherichia coli phytase on probiotic Bacillus polyfermenticus spores

The immobilization of enzymes on edible matrix supports is of great importance for developing stabilized feed enzymes. In this study, probiotic Bacillus spores were explored as a matrix for immobilizing Escherichia coli phytase, a feed enzyme releasing phosphate from phytate. Because Bacillus spore is inherently resistant to heat, solvents and drying, they were expected to be a unique matrix for enzyme immobilization. When mixed with food-grade Bacillus polyfermenticus spores, phytases were adsorbed to their surface and became immobilized. The amount of phytase attached was 28.2 ± 0.7 mg/g spores, corresponding to a calculated activity of 63,960 U/g spores; however, the measured activity was 41,120 ± 990.1 U/g spores, reflecting a loss of activity upon adsorption. Immobilization increased the half life (t_1/2) of the enzyme three- to ten-fold at different temperatures ranging from 60 to 90 °C. Phytase was bound to the spore surface to the extent that ultrasonication treatment was not able to detach phytases from spores. Desorption of spore-immobilized phytase was only achieved by treatment with 1 M NaCl, 10% formic acid in 45% acetonitrile, SDS, or urea, suggesting that adsorption of phytase to the spore might be via hydrophobic and electrostatic interactions. We propose here that Bacillus spore is a novel immobilization matrix for enzymes that displays high binding capacity and provides food-grade safety.     

Purification and physico-chemical characterisation of genetically modified phytases expressed in Aspergillus awamori

Two heterologous phytases from Aspergillus awamori and Aspergillus fumigatus obtained from submerged cultures of genetically modified fungal strains in addition to two commercially available phytase preparations (Allzyme and Natuphos phytases) were purified to homogeneity using a combination of ultrafiltration, gel filtration and ion exchange. The purified preparations were used in subsequent characterisation studies, in which Western Immunoblot analysis, pH and temperature optima, thermal stability and substrate specificity were assessed. A. fumigatus phyA phytase expressed in A. awamori exhibited activity over a broad pH range together with an increased temperature optimum, and slightly enhanced thermal stability compared to the other phytases tested, and is thus a promising candidate for animal feed applications. This particular phytase retains activity over a wide range of pH values characteristic of the digestive tract and could conceivably be more suited to the increasingly higher feed processing temperatures being utilised today, than the corresponding phytases from Aspergillus niger.     

Glucose-1-phosphatase (AgpE) from Enterobacter cloacae displays enhanced phytase activity

Using a screening procedure developed for detection of phytate hydrolysing enzymes, the gene agpE encoding glucose-1-phosphatase was cloned from an Enterobacter cloacae VKPM B2254 plasmid library. Sequence analysis revealed 78% identity on nucleotide and 79% identity on peptide level to Escherichia coli glucose-1-phosphatase characterising the respective gene product as a representative of acid histidine phosphatases harbouring the RH(G/N)RXRP motif. The purified recombinant protein displayed maximum specific activity of 196 U mg⁻¹ protein against glucose-1-phosphate but was also active against other sugar phosphates and p-nitrophenyl phosphate. High-performance ion chromatography of hydrolysis products revealed that AgpE can act as a 3-phytase but is only able to cleave off the third phosphate group from the myo-inositol sugar ring. Based on sequence comparison and catalytic behaviour against phytate, we propose to classify bacterial acid histidine phosphatases/phytases in the three following subclasses: (1) AppA-related phytases, (2) PhyK-related phytases and (3) Agp-related phytases. A distinguished activity of 32 U mg⁻¹ of protein towards myo-inositol-hexa-phosphate, which is two times higher than that of E. coli Agp, suggests that possibly functional differences in terms of phytase activity between Agp- and AppA-like acid histidine phosphatases are fluent. Electronic supplementary material Supplementary material is available for this article at and accessible for authorised users.     

Comparison of the Thermostability Properties of Three Acid Phosphatases from Molds: Aspergillus fumigatus Phytase, A. niger Phytase, and A. niger pH 2.5 Acid Phosphatase

Enzymes that are used as animal feed supplements should be able to withstand temperatures of 60 to 90°C, which may be reached during the feed pelleting process. The thermostability properties of three histidine acid phosphatases, Aspergillus fumigatus phytase, Aspergillus niger phytase, and A. niger optimum pH 2.5 acid phosphatase, were investigated by measuring circular dichroism, fluorescence, and enzymatic activity. The phytases of A. fumigatus and A. niger were both denatured at temperatures between 50 and 70°C. After heat denaturation at temperatures up to 90°C, A. fumigatus phytase refolded completely into a nativelike, fully active conformation, while in the case of A. niger phytase exposure to 55 to 90°C was associated with an irreversible conformational change and with losses in enzymatic activity of 70 to 80%. In contrast to these two phytases, A. niger pH 2.5 acid phosphatase displayed considerably higher thermostability; denaturation, conformational changes, and irreversible inactivation were observed only at temperatures of ≥80°C. In feed pelleting experiments performed at 75°C, the recoveries of the enzymatic activities of the three acid phosphatases were similar (63 to 73%). At 85°C, however, the recovery of enzymatic activity was considerably higher for A. fumigatus phytase (51%) than for A. niger phytase (31%) or pH 2.5 acid phosphatase (14%). These findings confirm that A. niger pH 2.5 acid phosphatase is irreversibly inactivated at temperatures above 80°C and that the capacity of A. fumigatus phytase to refold properly after heat denaturation may favorably affect its pelleting stability.     

Construction and characterization of the Bacillus strain with the inactivated phytase gene

The Bacillus subtilis dphy strain with the inactivated phytase gene was obtained. The phytase genes in bacilli displayed high homology; the respective enzymes belonged to the class of β-propeller phosphatases. Physiological and morphological features of the recombinant strain were determined and its sporulation was studied. The level of biomass accumulation was characterized under different conditions of bacterial growth: at different values of pH, temperature, and medium salinity. It is concluded that phytases may participate in stress response formation.     

Does dietary supplementation with phytases affect the thermoregulatory and behavioral responses of pullets in a tropical environment?

Dietary supplementation of two types of phytases (fungal and bacterial) with different dosages (300 and 900 FTUs) was evaluated in the thermoregulatory and behavioral responses of replacement pullets in a tropical environment. 288 Hy-Line White laying birds with a mean weight of 639.60 ± 6.05 g, clinically healthy, and eight weeks old were used in the study. Respiratory rate (RR, breaths. min⁻¹), Cloacal temperature (CT, °C), Surface temperature with feathers (STWF, °C), and Surface temperature featherless (STF, °C) were measured in the morning and afternoon. Behavioral data were observed through the following activities: sitting, eating, drinking, exploring feathers (EF), non-aggressive pecking (NAP), and object pecking (OP) recorded every 10 min from 6 a.m. to 5 p.m. Environmental variables were measured along with thermoregulatory and behavioral responses. There was an interaction for RR between phytase and period of the day (P < 0.05). The lowest RR (morning) was observed in fungal phytase. STF and STWF were higher (P < 0.05) in the afternoon. Birds supplemented with fungal phytase showed lower STWF (P < 0.05). The variables that contributed to explain physiological and behavioral responses are shown in order of importance for (i) periods of day: morning (sitting, STWF, drinking, eating, and CT) and afternoon (STF, STWF, OP, drinking, eating, RR and sitting); (ii) phytases: fungal (STF, STWF, RR, sitting, eating and drinking); and bacterial (RR, STF, STWF, CT and sitting). Thermoregulatory and behavioral responses were similar between dosages, but different between types of phytases. Birds supplemented with fungal phytase used sensible heat dissipation mechanisms and exhibited thermal comfort behaviors. The 300 and 900 FTUs phytase doses did not influence the thermoregulatory and behavioral responses of birds, while they showed natural heat dissipation and heat stress behaviors in the afternoon. We recommend a dietary supplementation of 300 FTUs fungal phytases.     

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.     

Molecular and biochemical characterization of a new alkaline β-propeller phytase from the insect symbiotic bacterium <Emphasis Type="Italic">Janthinobacterium</Emphasis> sp. TN115

A phytase-encoding gene (phyA115) was cloned from Janthinobacterium sp. TN115, a symbiotic bacterial strain isolated from the gut contents of Batocera horsfieldi larvae (Coleoptera: Cerambycidae), and expressed in Escherichia coli. The 1,884-bp full-length gene encodes a 28-residue putative signal peptide and a 599-residue mature protein with a calculated mass of 64 kDa. The deduced PhyA115 shares low identity with known sequences (47% at most) and contains an N-terminal incomplete domain (residues 29–297; domain N) and a typical β-propeller phytase domain at the C terminus (residues 298–627; domain C). Distinct from other β-propeller phytases that have neutral pH optima (pH 6.0–7.5), purified recombinant PhyA115 exhibits maximal activity at pH 8.5 and 45°C in the presence of 1 mM Ca²⁺ and is highly active over a wider pH range (pH 6.0–9.0). These results indicate that PhyA115 is a β-propeller phytase that has application potential in aquaculture feed. To our knowledge, this is the first report of cloning of a phytase gene from the symbiotic microbes of an insect digestive tract and from the genus Janthinobacterium. The N-terminal incomplete domain is found to have no phytase activity but can influence the pH property of PhyA115.     

Crystal structures of Bacillus alkaline phytase in complex with divalent metal ions and inositol hexasulfate

Alkaline phytases from Bacillus species, which hydrolyze phytate to less phosphorylated myo-inositols and inorganic phosphate, have great potential as additives to animal feed. The thermostability and neutral optimum pH of Bacillus phytase are attributed largely to the presence of calcium ions. Nonetheless, no report has demonstrated directly how the metal ions coordinate phytase and its substrate to facilitate the catalytic reaction. In this study, the interactions between a phytate analog (myo-inositol hexasulfate) and divalent metal ions in Bacillus subtilis phytase were revealed by the crystal structure at 1.25 Å resolution. We found all, except the first, sulfates on the substrate analog have direct or indirect interactions with amino acid residues in the enzyme active site. The structures also unraveled two active site-associated metal ions that were not explored in earlier studies. Significantly, one metal ion could be crucial to substrate binding. In addition, binding of the fourth sulfate of the substrate analog to the active site appears to be stronger than that of the others. These results indicate that alkaline phytase starts by cleaving the fourth phosphate, instead of the third or the sixth that were proposed earlier. Our high-resolution, structural representation of Bacillus phytase in complex with a substrate analog and divalent metal ions provides new insight into the catalytic mechanism of alkaline phytases in general.