Pichia pastoris is one of the most widely used recombinant protein expression systems. In this study, a novel method for rapid screening of P. pastoris strains capable of efficiently expressing recombinant proteins was developed. Firstly, the ability to express recombinant proteins of the modified strain GS115-E in which a functional Sec63-EGFP (Enhanced green fluorescent protein) fusion protein replaced the endogenous endoplasmic reticulum transmembrane protein Sec63 was tested. Next, the plasmids carrying different copy numbers of phytase (phy) gene or xylanase (xyn) gene were transformed into GS115-E to obtain recombinant strains with different expression levels of phytase or xylanase, and the expression levels of EGFP and recombinant proteins in different strains were tested. Finally, a flow cytometer sorter was used to separate a mixture of cells with different phytase expression levels into sub-populations according to green fluorescence intensity. A good linear correlation was found between the fluorescence intensities of EGFP and the expression levels of the recombinant proteins in the recombinant strains (0.8<|R|<1). By using the flow cytometer, high-yielding P. pastoris cells were efficiently screened from a mixture of cells. The expression level of phytase of the selected high-fluorescence strains was 4.09 times higher than that of the low-fluorescence strains after 120 h of methanol induction. By detecting the EGFP fluorescence intensity instead of detecting the expression level and activity of the recombinant proteins in the recombinant strains, the method developed by the present study possesses the greatly improved performance of convenience and versatility in screening high-yielding P. pastoris strains. Combining the method with high-throughput screening instruments and technologies, such as flow cytometer and droplet microfluidics, the speed and throughput of this method will be further increased. This method will provide a simple and rapid approach for screening and obtaining P. pastoris with high abilities to express recombinant proteins.
6-Phytase/genetics* ; Pichia/genetics* ; Plasmids ; Recombinant Proteins/genetics* ; Saccharomycetales

Production of bioethanol using starch as raw material has become a very prominent technology. However, phytate in the raw material not only decreases ethanol production efficiency, but also increases phosphorus discharge. In this study, to decrease phytate content in an ethanol fermentationprocess, Saccharomyces cerevisiae was engineered forheterologous expression of phytase on the cell surface. The phy gene encoding phytase gene was fused with the C-terminal-half region of α-agglutinin and then inserted downstream of the secretion signal gene, to produce a yeast surface-display expression vector pMGK-AG-phy, which was then transformed into S. cerevisiae. The recombinant yeast strain, PHY, successfully displayed phytase on the surface of cells producing 6.4 U/g wet cells and its properties were further characterized. The growthrate and ethanol production of the PHY strain were faster than the parent S. cerevisiae strain in the fermentation medium by simultaneous saccharification and fermentation. Moreover, the phytate concentration decreased by 91% in dry vinasse compared to the control. In summary, we constructed recombinant S. cerevisiae strain displaying phytase on the cell surface, which could effectively reduce the content of phytate, improve the utilization value of vinasse and reduce the discharge of phosphorus. The strain reported here represents a useful novel engineering platform for developing an environment-friendly system for bioethanol production from a corn substrate.
6-Phytase ; metabolism ; Biofuels ; Ethanol ; chemistry ; Fermentation ; Industrial Microbiology ; Saccharomyces cerevisiae ; metabolism ; Starch ; chemistry ; Zea mays ; chemistry

Both phytase and endoglucanase are additives in feed for mono-gastric animal known for their effects. Recombinant vector pPICZalpha-EG was constructed and transformed to GS115-phyA, a Pichia pastoris strain that had integrated with phytase gene, generating GS115-phyA-EG. Both phytase and endoglucanase activities in the supernatant were determined after methanol induction of GS115-phyA-EG. Phytase and endoglucanase activity reached 39.4% and 56.2% activity compared to GS115-phyA and GS115-EG, respectively. Properties of the mixed enzyme suggest that the optimal temperature and pH value be 55 degrees C and 5.5 respectively. Both phytase and endoglucanase showed greater than 80% activity across temperature ranges 45 degrees C to 55 degrees C and pH ranges 4.5 to 5.5. Expressing more than one enzyme in one system could save time and money during induced expression, and the mixed enzyme might apply for treating forge before feeding with poultry.
6-Phytase ; biosynthesis ; genetics ; Cellulase ; biosynthesis ; genetics ; Genetic Vectors ; Pichia ; enzymology ; genetics ; Recombinant Proteins ; biosynthesis ; genetics

Using the polymmerse chain reaction (PCR), we amplified the phytase gene phyA from Pichia pastoris GS115-phyA in Aspergillus niger NRRL3135 without the signal peptide sequence and intron sequence,. Then, it was cloned into pINA1297 vector to generate a recombinant vector of pINA1297-phyA. pINA1297-phyA was linearized and transformed into Yarrowia lipolytica po1h by the lithium acetate method. The positive transformants were obtained by YNB(casa) and PPB plates, after induced in YM medium at 28 degrees C for 6 day. The activity of the expressed phytase phyA reached 636.23 U/mL. The molecular weight of the enzyme was 130 kDa measured with SDS-PAGE analysis, whereas its molecular size reduced to 51 kDa after deglycosylation which is correspond with theoretical value. The enzymatic analysis of the recombinant phytase phyA revealed its optimal pH and temperature was 5.5 and 55 degrees C, which had high activity after incubated in pH ranged from 2.0 to 8.0 for 1 h. Moreover, its activity remained 86.08% after exposure to 90 degrees C for 10 min. It also was resistant to pepsin or trypsin treatment.
6-Phytase ; biosynthesis ; genetics ; Aspergillus niger ; genetics ; metabolism ; Pichia ; enzymology ; genetics ; Recombinant Proteins ; biosynthesis ; genetics ; Yarrowia ; genetics ; metabolism

Enzymes can degrade the anti-nutrient factors in feedstuff, increase nutrient digestibility, and reduce pollution to environment, and have been widely supplemented in animal feedstuff. However, the use of enzymes is limited because of their undesirable properties, such as thermoliability and susceptibility against protease digestions. And its commercialization is also limited by low production efficiency and high cost. Therefore, the focuses for future enzyme development will be: (1) to obtain novel enzymes with better properties by high-throughput screening of enzyme encoding genes, especially those from extreme and special environments; (2) to improve enzyme properties using directed mutagenesis and protein engineering methods; (3) to achieve high-level fermentation of enzymes by heterogonous expression and optimization of codons, vectors and fermentation conditions; (4) to determine the effect of enzymes to animals and utilize enzymes efficiently.
6-Phytase ; genetics ; metabolism ; pharmacology ; Animal Feed ; Animals ; Dietary Supplements ; Lipase ; genetics ; metabolism ; pharmacology ; Peptide Hydrolases ; genetics ; metabolism ; pharmacology ; Protein Engineering

The phyA(m) gene encoding acid phytase and optimized neutral phytase phyCs gene were inserted into expression vector pPIC9K in correct orientation and transformed into Pichia pastoris in order to expand the pH profile of phytase and decrease the cost of production. The fusion phytase phyA(m)-phyCs gene was successfully overexpressed in P. pastoris as an active and extracellular phytase. The yield of total extracellular fusion phytase activity is (25.4+/-0.53) U/ml at the flask scale and (159.1+/-2.92) U/ml for high cell-density fermentation, respectively. Purified fusion phytase exhibits an optimal temperature at 55 degrees C and an optimal pH at 5.5~6.0 and its relative activity remains at a relatively high level of above 70% in the range of pH 2.0 to 7.0. About 51% to 63% of its original activity remains after incubation at 75 degrees C to 95 degrees C for 10 min. Due to heavy glycosylation, the expressed fusion phytase shows a broad and diffuse band in SDS-PAGE (sodium dodecyl sulfate-polyacrylamide gel electrophoresis). After deglycosylation by endoglycosidase H (EndoH(f)), the enzyme has an apparent molecular size of 95 kDa. The characterization of the fusion phytase was compared with those of phyCs and phyA(m).
6-Phytase ; genetics ; isolation & purification ; metabolism ; Amino Acid Sequence ; Fermentation ; Genetic Vectors ; Molecular Sequence Data ; Pichia ; genetics ; Recombinant Fusion Proteins ; biosynthesis ; isolation & purification

Zinc (Zn) deficiency in animals became of interest until the 1950s. In this paper, progresses in researches on physiology of Zn deficiency in animals, phytate effect on bioavailability of Zn, and role of phytase in healing Zn deficiency of animals were reviewed. Several studies demonstrated that Zn is recycled via the pancreas; the problem of Zn deficiency was controlled by Zn homeostasis. The endogenous secretion of Zn is considered as an important factor influencing Zn deficiency, and the critical molar ratio is 10. Phytate (inositol hexaphosphate) constituted up to 90% of the organically bound phosphorus in seeds. Great improvement has been made in recent years on isolating and measuring phytate, and its structure is clear. Phytate is considered to reduce Zn bioavailability in animal. Phytase is the enzyme that hydrolyzes phytate and is present in yeast, rye bran, wheat bran, barley, triticale, and many bacteria and fungi. Zinc nutrition and bioavailability can be enhanced by addition of phytase to animal feeds. Therefore, using phytase as supplements, the most prevalent Zn deficiency in animals may be effectively corrected without the mining and smelting of several tons of zinc daily needed to correct this deficiency by fortification worldwide.
6-Phytase ; metabolism ; Animals ; Phytic Acid ; metabolism ; pharmacology ; Skin Diseases ; metabolism ; pathology ; Zinc ; administration & dosage ; chemistry ; deficiency ; pharmacology

Phytic acid (PA) is the primary storage compound of phosphorus in seeds accounting for up to 80% of the total seed phosphorus and contributing as much as 1.5% to the seed dry weight. The negatively charged phosphate in PA strongly binds to metallic cations of Ca, Fe, K, Mg, Mn and Zn making them insoluble and thus unavailable as nutritional factors. Phytate mainly accumulates in protein storage vacuoles as globoids, predominantly located in the aleurone layer (wheat, barley and rice) or in the embryo (maize). During germination, phytate is hydrolysed by endogenous phytase(s) and other phosphatases to release phosphate, inositol and micronutrients to support the emerging seedling. PA and its derivatives are also implicated in RNA export, DNA repair, signalling, endocytosis and cell vesicular trafficking. Our recent studies on purification of phytate globoids, their mineral composition and dephytinization by wheat phytase will be discussed. Biochemical data for purified and characterized phytases isolated from more than 23 plant species are presented, the dephosphorylation pathways of phytic acid by different classes of phytases are compared, and the application of phytase in food and feed is discussed.
6-Phytase ; chemistry ; metabolism ; Animals ; Diet ; Environment ; Humans ; Iron ; metabolism ; Neoplasms ; prevention & control ; Phytic Acid ; chemistry ; metabolism ; pharmacology

A gene appA encoding a novel phytase was firstly cloned from Hafnia alvei by PCR and sequenced. The gene was consisted of 1335 bp, encoding 444 amino acids. The calculated molecular weight of the mature APPA was about 45.2 kD. The gene appA was expressed in E. coli BL21 (DE3). Recombinant APPA was purified and its enzymatic properties were determined. The optimum pH for the enzyme was 4.5 and the optimum temperature was 60 degrees C. The pH stability of r-APPA is good, the relative phytase activity was above 80% after treated in buffers of pH 2.0-10.0. The specific activity of r-APPA is 356.7 U/mg, and the Km value was 0.49 mmol/L and Vmax of 238 U/mg. The enzyme showed resistance to pepsin and trypsin treatment.
6-Phytase ; biosynthesis ; genetics ; isolation & purification ; Amino Acid Sequence ; Cloning, Molecular ; Escherichia coli ; genetics ; metabolism ; Hafnia ; enzymology ; genetics ; Hydrogen-Ion Concentration ; Molecular Sequence Data ; Recombinant Proteins ; biosynthesis ; genetics ; isolation & purification ; metabolism ; Temperature

This research amplified the phyA gene with the designed and synthesized primers specific for the phyA gene full-length coding sequence. The phyA gene was from Aspergillus niger F246 by the polymerase chain reaction(PCR), which is selected and identified in our laboratory. After sequncing the coding sequence, it was confirmed that the construction of cloning vector was succeeded. The phyA gene fragment was recovered from the pMD18T-phyA and ligated with prokaryotic expression vector pET30a+ to construct the recombinant expression plasmid pET30a+ -phyA. It was expressed with IPTG induction in E. coli for high efficiency. A new protein band with apparent molecular weight 50 kDa was detected in the lysate of the transformed cell by using SDS-PAGE. The amount of the soluble fusion protein was about 40% of large intestine bacillus soluble protein of transformed cells, estimated by absorbance scanning of SDS-PAGE and protein quantitation. It's phytase activity was eight times over the natural phyase. So this research provides the basis of the study on obtaining large and high active phytase and developmant of the new microbial ecologicalagent.
6-Phytase ; biosynthesis ; genetics ; Aspergillus niger ; enzymology ; genetics ; Base Sequence ; Cloning, Molecular ; Escherichia coli ; genetics ; metabolism ; Genes, Fungal ; Genetic Vectors ; Molecular Sequence Data ; Recombinant Fusion Proteins ; biosynthesis ; genetics