Current Progresses in Phytase Research: Three‐Dimensional Structure and Protein Engineering

Chen, Chun‐Chi; Cheng, K.-J.; Ko, Tzu‐Ping; Guo, Rey‐Ting

doi:10.1002/cben.201400026

Cited by 25 publications

(13 citation statements)

References 94 publications

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“…Microbial phytases are of interest due to high substrate specificity, thermostability, catalytic efficiency, phosphate hydrolysis and low production cost (Chen et al 2015). The structure information of the enzyme is vital for its functional role.…”

Section: Introductionmentioning

confidence: 99%

Microbial degradation of myo-inositol hexakisphosphate (IP6): specificity, kinetics, and simulation

Priyodip

Balaji

2018

3 Biotech

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Microbial degradation of -inositol hexakisphosphate (IP6) is crucial to deal with nutritional problems in monogastric animals as well as to prevent environmental phosphate pollution. The present study deals with the degradation of IP6 by microorganisms such as spp. and. These microbes were screened for phytase production under laboratory conditions. The specificity of the enzyme was tested for various phosphorylated substrates such as sodium phytate (IP6), sodium hexametaphosphate, phenyl phosphate, α-d-glucose-6 phosphate, inosine 5' monophosphate and pyridoxal 5' phosphate. These enzymes were highly specific to IP6. The influence of modulators such as phytochemicals and metal ions on the enzymatic activity was assessed. These modulators in different concentrations had varying effect on microbial phytases. Calcium (in optimal concentration of 0.5 M) played an important role in enzyme activation. The enzymes were then characterized based on their molecular weight 41~43 kDa. The phytase-producing microbes were assessed for IP6 degradation in a simulated intestinal setup. Among the selected microbes, hydrolyzed IP6 effectively, as confirmed by colorimetric time-based analysis.

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Section: Introductionmentioning

confidence: 99%

Microbial degradation of myo-inositol hexakisphosphate (IP6): specificity, kinetics, and simulation

Priyodip

Balaji

2018

3 Biotech

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“…β-Propeller phytases, also known as alkaline phytases, have been considered mainly identified in Bacillus species. More recent bioinformatics studies conducted on microbial genomes and environmental metagenomes suggested that the β-propeller phytases are distributed more widely than previously believed and may play a role in phytate–phosphorus cycling in soil and aquatic environment [ 25 ].…”

Section: Discussionmentioning

confidence: 99%

New Bacterial Phytase through Metagenomic Prospection

2018

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Alkaline phytases from uncultured microorganisms, which hydrolyze phytate to less phosphorylated myo-inositols and inorganic phosphate, have great potential as additives in agricultural industry. The development of metagenomics has stemmed from the ineluctable evidence that as-yet-uncultured microorganisms represent the vast majority of organisms in most environments on earth. In this study, a gene encoding a phytase was cloned from red rice crop residues and castor bean cake using a metagenomics strategy. The amino acid identity between this gene and its closest published counterparts is lower than 60%. The phytase was named PhyRC001 and was biochemically characterized. This recombinant protein showed activity on sodium phytate, indicating that PhyRC001 is a hydrolase enzyme. The enzymatic activity was optimal at a pH of 7.0 and at a temperature of 35 °C. β-propeller phytases possess great potential as feed additives because they are the only type of phytase with high activity at neutral pH. Therefore, to explore and exploit the underlying mechanism for β-propeller phytase functions could be of great benefit to biotechnology.

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“…Briefly, HAPs fold into two domains: the α, and the larger α/β domain. The active site is made up of the conserved RHGXRXP and HD motifs, where the histidine of the first motive and the aspartate of the HD motif take direct part in the catalytic reaction [ 64 ]. Purple acid phosphatases are metalloproteins which contain a dinuclear Fe 3+ Me 2+ center in the active site.…”

Section: Phytasesmentioning

confidence: 99%

Globoids and Phytase: The Mineral Storage and Release System in Seeds

Madsen

Brinch-Pedersen

2020

IJMS

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Phytate and phytases in seeds are the subjects of numerous studies, dating back as far as the early 20th century. Most of these studies concern the anti-nutritional properties of phytate, and the prospect of alleviating the effects of phytate with phytase. As reasonable as this may be, it has led to a fragmentation of knowledge, which hampers the appreciation of the physiological system at hand. In this review, we integrate the existing knowledge on the chemistry and biosynthesis of phytate, the globoid cellular structure, and recent advances on plant phytases. We highlight that these components make up a system that serves to store and—in due time—release the seed’s reserves of the mineral nutrients phosphorous, potassium, magnesium, and others, as well as inositol and protein. The central component of the system, the phytate anion, is inherently rich in phosphorous and inositol. The chemical properties of phytate enable it to sequester additional cationic nutrients. Compartmentalization and membrane transport processes regulate the buildup of phytate and its associated nutrients, resulting in globoid storage structures. We suggest, based on the current evidence, that the degradation of the globoid and the mobilization of the nutrients also depend on membrane transport processes, as well as the enzymatic action of phytase.

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Current Progresses in Phytase Research: Three‐Dimensional Structure and Protein Engineering

Cited by 25 publications

References 94 publications

Microbial degradation of myo-inositol hexakisphosphate (IP6): specificity, kinetics, and simulation

Microbial degradation of myo-inositol hexakisphosphate (IP6): specificity, kinetics, and simulation

New Bacterial Phytase through Metagenomic Prospection

Globoids and Phytase: The Mineral Storage and Release System in Seeds

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