Summary
Phytate is the primary storage form of phosphate in plants. Phytases from microbial sources are supplemented to feedstuff of monogastric animals to increase the uptake of phytate phosphorus. The use of microbial phytase is associated with high production cost and also requires special care in feed processing. Expression of phytase in transgenic plants is an alternative approach to the production of phytase for commercial use (organic farming) as well as for animal feed. This review summarizes the current knowledge of transgenic plants overexpressing phy gene and their potential application in animal feed. The need for alterations in the phy gene for enhanced expression, accumulation and activity of phytase in transgenic plants is also discussed.
Key words: transgenic plants, phytase, phy gene, animal feed
Introduction
Plant seeds are major source of proteins and other nutrient elements in animal feed. The majority of the phosphorus in the seeds of higher plants is stored as myo- -inositol-1,2,3,4,5,6-hexakisphosphate, otherwise known as phytic acid or phytate. Plant seeds that have high phytate content are used as animal feed ingredients such as oilseed meals, cereal grains and legumes (1). The amount of phosphorus in cereal grains and oilseed meals meets the requirement for optimal growth of animals if all the phosphorus from phytate is available. Phytase is an enzyme that catalyses the breakdown of phytate into inorganic phosphorus and myo-inositol. Since monogastric animals like poultry, pigs and fish have very low or no phytase activities in their digestive tracts, they are unable to efficiently utilize phosphorus from the feed present in the form of phytate (2,3). In addition, phytate is considered as an antinutritional factor because under acidic conditions it has strongly negative charge and chelates cations such as iron, zinc, magnesium, manganese, copper and calcium (4). At low pH, phytate binds to amine groups of proteins, resulting in phytate-protein complex, which is generally insoluble and more resistant to hydrolysis by digestive enzymes (5). Binding of minerals and proteins to phytate impacts its nutritional quality by decreasing bioavailability of essential nutrients (6). Supplementation of inorganic phosphorus to feed can solve this nutritional problem (7). As a result, additional phosphorus is often provided to the feed and unutilized organic phosphorus (phytate) leaches and persists in animal manures. Such manures if applied routinely to the fields, cause serious pollution and ecological problems known as eutrophication (8). If inorganic phosphate is substituted by phytase and provided to monogastric animals, both phosphorus in phytate and bound metals become available to animals and the phosphorus pollution problem can also be resolved to some extent.
Microbial phytase produced by fermentation is used as a feed additive to manage the nutritional and environmental problems caused by phytate. However, this approach is associated with high production costs for the enzyme and requirement of special care in feed processing and diet formulation, which limits its extensive commercial use. Many strategies have been developed for improving phosphate and mineral availability in feed and food. These comprise the pretreatment of grains to activate endogenous phytase, mutation of enzymes involved in phytate biosynthesis for reduction of seed phytate levels, genetic engineering of livestock for secretion of phytase in the saliva, and transformation of crop plants for production of microbial phytase (2). The approach to produce transgenic crops having high phytase expression is becoming a prerequisite to improve the bioavailability of phosphorus in food/feed instead of direct supplementation of microbial phytase to animal feed. As a cost-effective option, transgenic plants have been evaluated as bioreactors for the production of recombinant phytases to meet the industrial demand (9,10). Enzymes can be expressed, secreted, folded and post-translationally modified in plants to produce functional recombinant proteins at high level (11,12). This review summarizes the current knowledge of various transgenic plants overexpressing microbial phy gene and their potential application in animal feed.
Source Organisms for phy Gene
Both prokaryotic and eukaryotic microbes have been used as a source of phy gene for transformation of crop plants. Some bacterial phy genes of phyC from Bacillus subtilis (13), SrPf6 from Selenomonas ruminantium (14), and appA and appA2 from E. coli (15) have been used to develop transgenic plants. Yeast is again an excellent source of phy gene for genetic transformation studies. The phy gene from yeast (Schwanniomyces occidentalis) has been used to develop transgenic rice plants (4). This is the first and only report about the use of phy gene from yeast in genetic transformation. A long list of phytase- -producing fungi includes Aspergillus ficuum (16), A. niger (17,18), Emericella nidulans, Talaromyces thermophilus (19), A. fumigatus (20), Thermomyces lanuginosus (21), Peniophora lycii, Agrocybe pediades, Ceriporia sp. and Trametes pubescens (22). A. niger IARI 363 and A. ficuum IARI 1461 have shown to produce thermostable phytase using waste carbon source (23,24). Fungal phyA gene from A. niger and A. fumigatus has been used to develop transgenic plants such as tobacco, maize, soybean, rice, wheat, canola and alfalfa. The phy gene from fungi has been extensively employed in transformation studies since they exhibit stability in a wide range of pH and temperature.
Expression of Phytase Gene in Plants
Phytase gene from diverse microbial origin has been overexpressed in various plants such as tobacco (9,25- 31), canola (32,33), soybean (10,34-38), wheat (6,39,40), rice (4,41-43), alfalfa (44), sesame (45), Arabidopsis (28,46), maize (47-49), Trifolium repens (50), Medicago truncatula (51) and potato (52).
The first account of the engineering of active and stable recombinant phytase from Aspergillus niger in tobacco seeds was reported by Pen et al. (9). The fungal phytase gene (phyA) was fused to a plant endoplasmic reticulum-targeting sequence and was placed under the control of the constitutive 35S cauliflower mosaic virus (CaMV) promoter in a binary transformation vector. The gene was inserted into the tobacco genome by Agrobacterium- mediated transformation (25). In stably transformed plants, up to 1 % of soluble protein in seeds was active recombinant phytase. Subsequently, Ullah et al. (26) repeated the transformation of tobacco with phyA from Aspergillus ficuum and purified the recombinant protein for further biochemical characterization. Similarly, transgenic tobacco plants were generated that constitutively expressed b-propeller phytase from Bacillus subtilis (168 phyA) under the control of CaMV 35S promoter, and carrot extensin signal peptides were attached for root-specific secretion (28). Recombinant phytase accounted for 0.4 % of total soluble leaf protein. Recently, a heat-stable phytase gene from Aspergillus fumigatus (fphyA) has been introduced in tobacco by Agrobacterium-mediated transformation. Phytase gene expression was controlled by CaMV 35S promoter and secretion of recombinant phytase to extracellular fluid was established by use of signal sequence from tobacco calreticulin (31). In transformed plants, phytase accounted for 2.3 % of total soluble leaf protein.
The phyA gene was introduced in soybean using microprojectile bombardment of cell suspension culture (10). Cells were stably transformed with phyA construct containing a dually-enhanced CaMV 35S promoter fused to a signal peptide in order to secrete active phytase into the culture medium. Based on the estimated activity levels, up to 7 % of the secreted proteins were predicted to be phytase. Production of transgenic soybean expressing phytase has also been reported with linear vectorless construct without selectable markers constituting phyA gene and CaMV 35S promoter directly introduced through pollen tube pathway (35). In another study, appA gene from E. coli constructed with seed lectin promoter and a lectin signal sequence for specific expression of gene in vacuoles was transformed into soybean using Agrobacterium- mediated transformation (36). Subsequently, another phy gene from Asperigillus ficuum (AfPhyA) was transformed into soybean using Agrobacterium-mediated transformation. This phy gene was driven by the Arabidopsis Pky10 gene promoter and the carrot extension signal peptide was introduced for root-specific secretory expression of this gene (37). Recently, transgenic soybean plants have been generated using both Agrobacterium- mediated and pollen tube pathways with the phyA gene from Aspergillus ficuum (38).
The transgenic canola seeds overexpressing phytase gene (phyA) from Aspergillus niger were generated with the gene placed under the control of seed-specific cruciferin (cruA) promoter and fused to cruciferin signal peptide sequences for specific secretion into the seeds (32). These canola seeds expressed high phytase activity per mass of seed of 600 U/g. Later, transgenic canola expressing A. niger phytase gene (phyA) with codon modifications according to codon usage of Brassica napus was also developed resulting in a remarkable increase in phytase synthesis in seeds (33). For this purpose, synthetic phy gene was designed according to the codon usage of B. napus without altering the amino acid sequence of A. niger phyA gene. This codon modified phyA gene overexpressed in canola using a construct driven by CaMV 35S promoter, tobacco Ubi-U4 promoter for GUS expression, tobacco PR-S signal peptide and KDEL sequence for retention of secreted proteins in the endoplasmic reticulum (ER). Phytase accumulation in transformed mature canola seed accounted for 2.6 % of the total soluble proteins.
The phytase gene (phyA) from Aspergillus niger has been applied to generate transgenic wheat plants using biolistic approach (39,40). This phyA gene was driven by maize Ubi promoter and fused to barley a-amylase signal peptide for apoplast localization (39). Similarly, a construct was generated for phyA gene driven by endosperm- specific 1DX5 promoter (wheat high molecular mass subunit gene, glutelin promoter Glu-1D-1) fused to barley a-amylase signal peptide for apoplast localization (40). Phytase gene (phyA) from Aspergillus fumigatus has been used to transform rice. The gene was placed under the control of glutelin promoter (Gt1) and barley b-glucanase signal peptide was introduced for secretion in the endosperm (41). Likewise, phy genes from bacteria Selenomonas ruminantium (SrPf6) and E. coli (appA) have been introduced in rice under the control of a-amylase gene (aAmy8) promoter fused to aAmy8 signal peptide sequence for tissue-specific secretion (42). In a similar study, another phy gene from yeast (Schwanniomyces occidentalis) was introduced in rice (4). The codons of yeast phytase gene were modified according to their usage in rice plant without affecting the amino acid sequence and placed under the control of rice light-harvesting chlorophyll a/b-binding protein (cab) promoter together with a secretory signal sequence from rice chitinase-3 gene (Cht3-SS). This is the only report that describes the use of phy gene from yeast for development of transgenic plants. Furthermore, phytase gene (phyI) from Aspergillus niger was also employed for generating transgenic rice overexpressing phytase (43). The gene was driven by the maize ubiquitin (Ubi) promoter and tobacco pathogenesis related the protein signal sequence as well as the KDEL sequence for retention of secreted phytase into ER. This gene was transformed into a high-yielding rice cultivar via Agrobacterium-mediated transformation expressing phytase gene with an increase in phosphorus content in seeds.
Phytase gene (phyA) cloned from Aspergillus ficuum was expressed in leaves of transformed Medicago sativa (44). This gene was placed under the control of CaMV 35S promoter or Arabidopsis thaliana Rubisco small subunit (SSU) promoter with a signal peptide for apoplast localization. Phytase was produced in transgenic alfalfa at concentrations of over 1.5 % of the soluble protein. Similarly, phyA from Aspergillus niger was expressed in Trifolium repens (white clover), the gene was controlled by CaMV 35S promoter and a patatin signal peptide introduced for secretion of transgene products into intercellular space and rhizosphere (50). Furthermore, phyA from Aspergillus niger was expressed in Medicago truncatula transgenic cell suspension line (51). In another experiment, sweet potato sporamin promoter was used to control the expression of appA gene from E. coli and introduced in potato tubers, which encoded a bifunctional enzyme exhibiting both acid phosphatase and phytase activities (52).
A gene for phytase (phyA) from Aspergillus niger was stably expressed in maize seeds after transformation with the gene under the control of rice glutelin-1 seed- -specific promoter, with murine immunoglobulin leader peptide sequence incorporated for better secretion (47). In a similar study, phytase gene from Aspergillus niger was also overexpressed in maize seeds when transformed with a construct constituting the maize embryo-specific globulin-1 promoter and synthetic barley a-amylase signal peptide gene for secretion of the expressed phytase into the intercellular space (48). Another phyA gene isolated from Aspergillus niger under the control of an endosperm- -specific expression vector was also expressed in microprojectile- mediated transformed maize seeds (49). The details of the source of phy gene, promoters, signal sequences and vectors used in the development of transgenic crops overexpressing phytase enzymes are given in Table 1 (4,6,10,25-29,31-33,35-50,52,53).
Modifications of phy Gene for Expression in Plants
In most of the studies, phy gene from the microbial origin (bacterial/fungal/yeast) is used for transformation into the plants without any modifications. The expression of enzymes and proteins is often difficult outside the original host for the reason that codon usages vary significantly among different organisms (54). If more rare codons in a gene operate in the original host, it is less likely that the heterologous protein will be expressed in an alternate host at a high level (55). One of the strategies to improve the expression is to modify the codons of the gene according to the usage of host plant where the heterologous protein will be expressed. There are a few reports where the phy genes have been modified according to the codon usage in rice (4) and Brassica napus (33), without altering the amino acid sequence of native phytase gene. These studies revealed that phytase gene with preferred codons according to the target plant species leads to a remarkable increase in phytase yield as compared to the host plant. Consequently, codon modification can provide an alternative strategy to improve expression levels of non-plant-based phytases in various plant species.
Another strategy to increase the yield of the expressed protein is to direct the soluble proteins to a specific tissue (56). The fact that the functional phytase produced by fungi is a glycoprotein necessitated a strategy to direct the recombinant phytase to the plant ER for glycosylation. Almost all phy genes used for overexpression in plants were targeted to specific locations by attaching different signal sequences, such as rice chitinase- 3 gene (4), tobacco PR-S (10,25,35,43,45), soybean VSPb secretory signal sequences (26), cruciferin signal peptide (32), tobacco calreticulin signal peptide (33), barley b-glucanase signal peptide (41), barley a-amylase signal peptide (apoplast localizaton) (6,39,48), carrot extensin signal peptide (for root specific secretion) (28,29, 37) and potato patatin signal peptide (50). The tetrapeptide KDEL is commonly found at the C-terminus of soluble proteins in the ER and it contributes to their localization and stable accumulation in plant ER (57). The KDEL sequence was introduced into the phy gene construct for its endoplasmic reticulum localization in transgenic canola and rice overexpressing phytase (33, 43). It has been demonstrated that the addition of KDEL sequence with the phyA resulted in higher levels of phytase accumulation in these transgenic plants as compared to transgenic plants expressing phyA gene without KDEL sequences (33).
Glycosylation Pattern of phy Gene in Transgenic Plants
Glycosylation of phytase enzyme helps in folding of protein to generate active sites, and also aids in maintaining thermal stability and activity of the enzyme. The glycosylation has little effect on the substrate specificity of phytase but has a significant effect on the molecular mass, protein structure, thermal stability and biological synthesis. Most of the phy genes expressed in different transgenic crops exhibited lower mass as compared to the native phytase; this is attributed to the difference in the glycosylation pattern of this gene in plant and fungal systems. It has been reported that glycosylation is important for Aspergillus phytase activity, secretion and stability. The molecular mass of transformed tobacco phytase from leaves was found to be approx. 70 kDa as compared to Aspergillus enzyme of approx. 80 kDa. This difference in molecular mass of transgenic tobacco and donor of the gene Aspergillus was found to be due to the differences in glycosylation patterns (25). Phytase gene from Aspergillus niger expressed in tobacco was found to be 17 % less glycosylated as compared to the identical phy gene from fungi. Similarly, Aspergillus fumigatus phytase gene expressed in tobacco (tfphyA) was found to be 22 % less glycosylated than the native phytase gene (31). The yeast phytase expressed in rice, i.e. heterologous phytase, was 22 % less glycosylated than the original yeast phytase (4). The fungal phytase (A. ficuum) expressed in alfalfa was 16 % less glycosylated than its native form (44). In addition, similar results were obtained for the expression of fungal phyA gene in wheat, canola, rice and soybean, where recombinant phytase had low molecular mass as compared to the native phytase, revealing low glycosylation of plant-expressed phytase (10,33,35, 39,41). Furthermore, phy2A gene of Aspergillus niger when expressed in maize showed a band of 60 kDa using Western blot analysis but the same gene when expressed in yeast exhibited a band of 75 kDa, clearly showing variations in enzyme glycosylation in maize and yeast (48).
It is well documented that in planta synthesized fungal phytase is glycosylated when targeted to the apoplast and ER but the pattern of glycosylation is less complex than in fungi (6). The importance of glycosylation in folding of phytase to generate the active site was studied using A. ficuum phytase gene expressed in E. coli and Pichia pastoris. The expressed fungal phytase in the bacteria was not only devoid of any activities, but it accumulated in the inclusion bodies (58). Despite the differences in glycosylation patterns, the plant expressed phy genes (tobacco, soybean, canola, wheat, alfalfa, rice and maize), conserved the catalytic properties of the native enzyme and was found to be functionally active.
Phytase Activity in Transgenic Plants
Transgenic tobacco plants overexpressing fungal phyA gene showed 2500 ng of phytase per mg of dry mass. Phytase was found to be biologically active and to accumulate in leaves up to 14.4 % of total soluble protein during plant maturation (25). Similar results were reported for transgenic tobacco overexpressing heat- -stable phytase from Aspergillus fumigates, where phytase accumulation was 2.3 % of the total soluble protein in leaves (31). Transgenic wheat, rice, corn and soybean overexpressing fungal phytase showed phytase activity per mass of seed 1467, 16 500 and 125 U/kg and per mass of leaves 5000 U/kg (4,32,35,39,42,58). Phytase activity of leaves was found to be 389.3 nkat/g in transgenic alfalfa plants overexpressing fungal phytase (44). In transgenic canola seeds overexpressed phytase activity was as high as 15 600 U/kg and phytase accumulation was up to 2.6 % of the total soluble proteins (33). Similarly, transgenic rice overexpressing phytase gene (phyI) showed significantly higher (57 %) phosphorus content as compared to that in the untransformed wild type (43). Transgenic maize seeds expressed the fungal phytase phyA2 gene in embryos without affecting the seed germination despite the phytase activity of virtually 2200 U/kg (48). The accumulation of the phytase in all the transgenic plants overexpressing fungal phytase was stable, and functionally active. Different transgenic plants (expressing bacterial, fungal and yeast phytase) with their respective phytase activities are presented in Table 2 (4,6, 25,26,28,29,31,33,35-37,39-42,45-50,52,53).
Feed Trails for Transgenic Crops Overexpressing Phytase
The transgenic crops overexpressing phytase were used for feed trials for pigs and poultry. In a poultry feed trial, when phytase-containing alfalfa juice was added at the rate of 400 U/kg to the normal dietary supplements, the performance of chickens was at par with the group fed only with normal dietary supplements (59). The addition of phytase to the poultry and pig feed in the form of transgenic soybeans at 1200 U/kg and transgenic canola at 250, 500 and 2500 U/kg per day significantly improved the nutritional values and remarkably reduced phosphorus excretion (34,60,61). Germinated transgenic rice seeds overexpressing phytase from bacterial origin supplemented to poultry feed resulted in growth rates comparable to the growth rates of chickens fed with a standard meal supplemented with a commercial microbial phytase (42). When transgenic rice fresh leaves expressing yeast (Schwanniomyces occidentalis) phytase were ground and mixed with whole extract of seed-based feed for pigs, the release of orthophosphate increased significantly, due to phytase activity (62). For the efficacy of transgenic canola-derived phytase, the chicken trial results have shown that it is as effective as the commercial microbial phytase (33). Also, the chickens fed with phytase from transgenic canola performed at par to those fed with feed supplemented with inorganic phosphate. In another trial, differences were not observed in the utilization of P or Ca between pigs fed with 16 500 U/kg of either corn-based phytase (CBP), i.e. transgenic corn expressing a phytase gene from E. coli, or Quantum® phytase derived from E. coli (53). These findings will perhaps extend the application of transgenic plants that produce heterologous phytases as an animal feed.
Conclusion and Future Prospects
Transgenic plants expressing microbial phytase are an innovative means of delivering phytases to non-ruminants to enhance the utilization of phytate phosphorus and mineral uptake. Hence, it could be concluded that molecular organic farming of stable hydrolytic enzymes like phytase is a practical proposition. It was found that the phytase produced by fungi, bacteria or yeast and the recombinant phytase produced in transgenic plants do not show much difference. Furthermore, the use of codon modifications adjusted to the host plant in seed- and endosperm-specific promoters and the addition of signal peptides for tissue-specific secretion would have an additional effect on the production and accumulation of phytases in plants. Therefore, production of stable phytase from microbial sources in crop plants could open a new venture for commercial purposes. There is a potential in the use of these transgenic seeds and fodder as additives for the improvement of digestibility of phytic acid in animal feeds, and the reduction of phosphate excretion from poultry, pigs and dairy cattle would substantially reduce phosphates in manure.
Only a limited number of phytase genes from bacteria and yeast have been used for developing transgenic crops. Further efforts for developing new technologies and identifying the most efficient phytases from various sources and their heterologous expression in appropriate host plants for improving animal feed must continue. Since the feed ingredients are often heated at 65-80 °C during the pelleting process, phytase stable at high temperature is desirable for animal feed applications. There is an urgent need to search for thermostable phytase from different microbial sources and efforts should be focused on employing phytase genes from such microorganisms for transformation of various crops. Another approach may be to limit the phytate content of seeds by developing low phytic acid (lpa) mutant plants through knocking out of genes involved in phytic acid biosynthesis. Thus, the purpose of investigations is to know if the low phytate trait results in undesirable side effects in crops such as yield reduction and loss of seed viability. Preferably both strategies, i.e. the use of phy gene for transformation of crop plants, and the production of lpa mutant plant seeds should go hand in hand either to improve phytate utilization by monogastric animals or to reduce their exposure to phytate.
Acknowledgement
IG is grateful to the Department of Biotechnology, Ministry of Science and Technology, Government of India, New Delhi, India, for financial assistance.
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Iti Gontia, Keerti Tantwai, Lalit Prasad Singh Rajput and Sharad Tiwari*
Biotechnology Centre, J. N. Agricultural University, Jabalpur 482004, India
Received: November 25, 2010
Accepted: July 27, 2011
*Corresponding author; Phone: ++91 942 465 8241; Fax: ++91 761 268 1089; E-mail: [email protected]
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Copyright Sveuciliste u Zagrebu, Prehramheno-Biotehnoloski Fakultet 2012
Abstract
Phytate is the primary storage form of phosphate in plants. Phytases from microbial sources are supplemented to feedstuff of monogastric animals to increase the uptake of phytate phosphorus. The use of microbial phytase is associated with high production cost and also requires special care in feed processing. Expression of phytase in transgenic plants is an alternative approach to the production of phytase for commercial use (organic farming) as well as for animal feed. This review summarizes the current knowledge of transgenic plants overexpressing phy gene and their potential application in animal feed. The need for alterations in the phy gene for enhanced expression, accumulation and activity of phytase in transgenic plants is also discussed. [PUBLICATION ABSTRACT]
You have requested "on-the-fly" machine translation of selected content from our databases. This functionality is provided solely for your convenience and is in no way intended to replace human translation. Show full disclaimer
Neither ProQuest nor its licensors make any representations or warranties with respect to the translations. The translations are automatically generated "AS IS" and "AS AVAILABLE" and are not retained in our systems. PROQUEST AND ITS LICENSORS SPECIFICALLY DISCLAIM ANY AND ALL EXPRESS OR IMPLIED WARRANTIES, INCLUDING WITHOUT LIMITATION, ANY WARRANTIES FOR AVAILABILITY, ACCURACY, TIMELINESS, COMPLETENESS, NON-INFRINGMENT, MERCHANTABILITY OR FITNESS FOR A PARTICULAR PURPOSE. Your use of the translations is subject to all use restrictions contained in your Electronic Products License Agreement and by using the translation functionality you agree to forgo any and all claims against ProQuest or its licensors for your use of the translation functionality and any output derived there from. Hide full disclaimer