植酸酶及其热稳定性研究进展

植酸酶能降解植物性饲料中的植酸盐类,释放出无机磷酸,对于提高饲料中磷的利用率,减轻畜禽高磷排泄物对环境的污染以及促进单胃动物对饲料中矿质营养的吸收利用有重要作用,因此植酸酶的研究有重要的科学和实用价值。获得高活性高热稳定性的植酸酶是近年来植酸酶工业的研究热点和难点,综述了植酸酶及其热稳定性研究的现状和提高植酸酶热稳定性方法的最新进展 。     

转植酸酶基因玉米的研究与安全评价

植酸酶是应用最广泛的饲料添加剂之一,它在自然界中广泛存在,能提高饲料中磷的利用率,对减轻动物高磷粪便导致的环境水域污染有着重要意义.玉米是动物饲料的主要原料,在玉米饲料中添加植酸酶易造成饲料成本升高和生产效率降低等问题.近年来随着基因工程技术的发展,已克隆出多个真菌植酸酶基因,并成功在微生物、植物系统中表达.本文主要介绍了植酸酶基因的微生物来源与相关研究成果,阐述了转基因技术的常用方法和转植酸酶基因玉米的研究进展,并详细评价了转植酸酶基因玉米的安全性.通过对转植酸酶基因玉米的深入探讨,对改善玉米的品质,降低成本及推广植酸酶在饲料工业中的应用具有重要意义.     

饲用植酸酶热稳定性的研究*

植酸酶是一种能将植物性饲料中植酸(盐)降解为肌醇和无机磷酸盐的酶类。其作为单胃动物的饲料添加剂,对提高畜禽业生产效益及降低植酸磷对环境的污染有重要意义。针对目前饲用植酸酶存在的热稳定性不高的问题,介绍了国内外近年来的研究进展,并提出了解决的方法。     

植酸酶及其基因工程研究进展

植酸酶可添加于食品与饲料中,能消除因不能降解的植酸所引起的抗营养作用,提高机体对蛋白质及多种微量元素的利用率,降低粪便中磷的含量,从而减少环境中磷的积累污染,有利于保护生态环境。弄清植酸酶的性质、基因结构和功能,了解其基因工程的研究进展,不仅具有重要的理论意义,而且在开发研究植酸酶制剂用于饲料、食品和医药等方面具有重要的实践价值。本文谨对植酸酶的性质、基因结构和功能及其基因工程的研究进展做一综述,并探讨了植酸酶的应用前景。     

转基因植物表达植酸酶研究进展

植酸是植物体内磷的主要存在形式,其绝大部分不能被单胃动物消化吸收,而随粪便排出体外造成环境污染;同时,植酸又是一种抗营养因子,它通过络合植物体内的一些营养成分而降低植物的营养价值。通过植物转基因方法使植物自身表达足量的植酸酶,以减小植酸带来的不利影响,是提高植物性饲料营养价值和控制环境磷污染的一种经济有效的措施。就转基因植物植酸酶的优势、研究现状、存在的问题及其发展前景进行了综述。     

植物植酸酶及其在饲料中的应用前景

植物植酸酶不但能分解内源植酸磷 ,对外源植酸磷同样有明显的降解作用。在饲粮中添加植酸酶活性高的植物性饲料 ,可提高猪和家禽对植酸磷的利用率 ,降低粪便中磷的排泄量 ,提高生产性能。麦类籽实中具有较高的天然植酸酶活性 ,发芽能显著提高种子中植酸酶的活性 ,因而有希望通过发芽提高麦类籽实中的植酸酶活性 ,经提纯浓缩后可达到在实际生产中应用的水平 ,从而减少在饲料中添加无机磷或价格昂贵的微生物植酸酶。     

热稳定的曲霉植酸酶

植酸(Phytic acid)在谷物、豆类、油料等作物籽粒中的含量为1％～5％,籽粒中60％～90％的磷存在于植酸中。人和单胃动物消化道中无植酸酶,粮食中大量的植酸磷不能被利用而随粪便排入环境,既浪费磷资源,又对环境造成磷污染。同时,植酸还是一种广谱性抗营养因子。据报道,饲料中添加植酸酶可使植酸磷的利用率提高到70％,鸡猪粪磷含量分别降低50％和35％,并可提高对Ca、Zn、Fe和Cu等的吸收率,而饲养效果与添加无机磷相当甚至更好,故植酸酶在饲养业及环保业展示出广阔的应用前景。本文报道耐高温植酸酶菌株的筛选及其体外去玉米、豆粕和麸皮植酸磷的效果。     

中性植酸酶的研究与前景

植酸酶在饲料工业中已经得到了广泛的重视和应用,但在我国占据重要地位的水产养殖业中应用传统的酸性植酸酶则具有较多的局限性,文章着重介绍中性的伊折叠桶植酸酶的研究现状,其在自然界磷循环中的重要作用及其在水产养殖和环境治理中的潜在作用和研发趋势。     

无鱼粉低磷饲料中添加中性蛋白酶和植酸酶对建鲤生长及营养物质利用的影响

在无鱼粉低磷饲料中添加中性蛋白酶、中性植酸酶, 考察对建鲤(Cyprinus carpio var. Jian)生长、营养物质消化率和沉积率、血浆生化指标及肠道组织学的影响。配制含鱼粉5%和磷酸二氢钙1.5%的正对照饲料、无鱼粉饲料、无鱼粉低磷饲料(磷酸二氢钙1.0%)和在无鱼粉饲料中添加175 mg/kg蛋白酶, 在无鱼粉低磷饲料中添加175 mg/kg蛋白酶+300 mg/kg植酸酶的5组等蛋白饲料, 饲喂初始体重为(52.5±2.0) g的建鲤10周。结果表明: 对照组具有最高增重率和最低饲料系数(P<0.05), 无鱼粉饲料和无鱼粉低磷饲料组的增重率、蛋白质和磷沉积率、蛋白质和钙消化率均显著下降(P<0.05); 在无鱼粉饲料中添加蛋白酶后, 提高了建鲤增重率13.1%(P<0.05), 达到和对照组基本一致的水平; 显著提高了蛋白质、钙消化率和肠绒毛高度, 降低了饲料系数(P<0.05); 在无鱼粉低磷饲料中添加蛋白酶和植酸酶后, 显著提高了脂肪、蛋白质、磷沉积率和蛋白质、钙、磷消化率(P<0.05), 增加了前肠绒毛长度和隐窝深度(P<0.05), 提高了血浆磷浓度(P<0.05)。以上结果表明, 在全植物性蛋白饲料中添加蛋白酶, 在全植物蛋白的低磷饲料中同时添加蛋白酶和植酸酶可以促进建鲤生长, 提高对营养物质的消化率和沉积率, 促进肠道生长发育。     

不同添加方式植酸酶处理豆粕对牙鲆生长和饲料利用率的影响

以初始平均体重(2.02±0.02)g的牙鲆(Paralichthys olivaceus)为实验对象,进行为期70d的摄食生长实验,研究不同添加方式的植酸酶对牙鲆生长和饲料利用的影响。在5000.0g豆粕中添加2.5g植酸酶,然后用产朊假丝酵母(Candidautilis)进行发酵预处理,得到植酸酶预处理豆粕。共制作4种等氮等能(粗蛋白49.7%、总能20.9kJ/g)饲料,对照饲料主要以鱼粉为蛋白源;在对照饲料的基础上,用豆粕蛋白替代45%的鱼粉蛋白配制成豆粕组饲料;在每千克豆粕组饲料中添加1000IU植酸酶,配制成植酸酶组饲料;用植酸酶预处理豆粕蛋白替代45%的鱼粉蛋白配制成植酸酶预处理豆粕组饲料。结果表明,与对照组相比较,用豆粕蛋白替代饲料中45%的鱼粉蛋白,若不添加植酸酶则显著降低牙鲆的特定生长率(P0.01)、饲料效率、蛋白质效率和氮贮积率(P0.05);直接添加植酸酶组、植酸酶预处理豆粕组牙鲆的特定生长率、饲料效率、蛋白质效率和氮贮积率与鱼粉对照组相比较没有出现显著差异(P0.05);与不添加植酸酶的豆粕组相比较,在含豆粕饲料中添加1000IU/kg饲料的植酸酶显著提高牙鲆的特定生长率(P0.01)、氮贮积率(P0.05)和磷贮积率(P0.01),显著降低氮排放率(P0.05)和磷排放率(P0.01),但饲料效率和蛋白质效率没有显著变化(P0.05);在豆粕中添加植酸酶进行发酵预处理,降低了豆粕中植酸含量,在饲料中添加植酸酶预处理豆粕显著提高牙鲆的特定生长率(P0.01)、饲料效率、蛋白质效率和氮贮积率(P0.05),显著降低氮(P0.05)、磷和钙的排放率(P0.01)。     

Transgenic maize plants expressing a fungal phytase gene

Maize seeds are the major ingredient of commercial pig and poultry feed. Phosphorus in maize seeds exists predominantly in the form of phytate. Phytate phosphorus is not available to monogastric animals and phosphate supplementation is required for optimal animal growth. Undigested phytate in animal manure is considered a major source of phosphorus pollution to the environment from agricultural production. Microbial phytase produced by fermentation as a feed additive is widely used to manage the nutritional and environmental problems caused by phytate, but the approach is associated with production costs for the enzyme and requirement of special cares in feed processing and diet formulation. An alternative approach would be to produce plant seeds that contain high phytase activities. We have over-expressed Aspergillus niger phyA2 gene in maize seeds using a construct driven by the maize embryo-specific globulin-1 promoter. Low-copy-number transgenic lines with simple integration patterns were identified. Western-blot analysis showed that the maize-expressed phytase protein was smaller than that expressed in yeast, apparently due to different glycosylation. Phytase activity in transgenic maize seeds reached approximately 2,200 units per kg seed, about a 50-fold increase compared to non-transgenic maize seeds. The phytase expression was stable across four generations. The transgenic seeds germinated normally. Our results show that the phytase expression lines can be used for development of new maize hybrids to improve phosphorus availability and reduce the impact of animal production on the environment.     

Studies on the dephosphorylation of phytic acid in livestock feed using phytase from Aspergillus niger van Teighem

Phytase from Aspergillus niger van Teighem efficiently hydrolyses phytate phosphorus present in various commercial live stock feeds and was not inactivated by various formulations and antibiotics present. The enzyme retained 90-95% phytase activity at 55 degrees C, pH 2.5 after 72 h of incubation with all the commercial feeds tested, thus indicating its suitability in feed application. The phytase hydrolysis increased with the increase in temperature and a significant release of 41 nmols P(i)/ml in phytase-treated feed over control sample was observed at 55 degrees C after 48 h. Besides this, the enzyme was maximally effective when used under acidic condition, releasing 21 and 42 nmols P(i)/ml at pH 1.5 and 2.5, respectively. As the pH shifted towards 5.5, significant decline in phosphorus release was observed. However, the enzyme was able to retain almost complete phytase activity in the presence of feed constituent even after 48 h over various pH tested. Thus it can be a potential candidate in animal nutrition where the ability of present phytase to retain activity over period of time in the presence of feed constituent is desired.     

Production,characteristics and applications of the cell-bound phytase of <Emphasis Type="Italic">Pichia anomala</Emphasis>

Among several yeasts isolated from dried flowers of Woodfordia fruticosa, Pichia anomala produced a high titre of cell-bound phytase. The optimization of fermentation variables led to formulation of media and selection of cultural variables that supported enhanced phytase production. The enzyme productivity was very high in fed batch fermentation in air-lift fermentor as compared to that in stirred tank fermentor. Amelioration in the cell-bound phytase activity was observed when yeast cells were permeabilized with Triton-X-100. The enzyme is thermostable and acid stable with broad substrate specificity, the characteristics that are desirable for enzymes to be used in the animal feed industry. The phytase-encoding gene was cloned and sequenced. The 3D structure of the enzyme was proposed by comparative modeling using phytase of Debaryomyces occidentalis (50% sequence identity) as template. When broiler chicks, and fresh water and marine fishes were fed with the feed supplemented with yeast biomass containing phytase, improvement in growth and phosphorus retention, and decrease in the excretion of phosphorus in the faeces were recorded. The cell-bound phytase of P. anomala could effectively dephytinize wheat flour and soymilk.     

A novel phytase from Yersinia rohdei with high phytate hydrolysis activity under low pH and strong pepsin conditions

Two novel phytase genes belonging to the histidine acid phosphatase family were cloned from Yersinia rohdei and Y. pestis and expressed in Pichia pastoris. Both the recombinant phytases had high activity at pH 1.5-6.0 (optimum pH 4.5) with an optimum temperature of 55 degrees C. Compared with the major commercial phytases from Aspergillus niger, Escherichia coli, and a potential commercial phytase from Y. intermedia, the Y. rohdei phytase was more resistant to pepsin, retained more activity under gastric conditions, and released more inorganic phosphorus (two to ten times) from soybean meal under simulated gastric conditions. These superior properties suggest that the Y. rohdei phytase is an attractive additive to animal feed. Our study indicated that, in order to better hydrolyze the phytate and release more inorganic phosphorus in the gastric passage, phytase should have high activity and stability, simultaneously, at low pH and high protease concentration.     

Phytase produced on citric byproducts: purification and characterization

Citric pulp is an agro-industrial residue from the citrus processing industry with low inorganic phosphorus content applied in animal feed. A new bioprocess was developed to produce and purify a new phytase generated on citric pulp fermentation by Aspergillus niger FS3. The phytase was purified by cationic-exchange, anionic-exchange chromatography and chromatofocusing steps. From SDS–PAGE analysis, the molecular weight of the purified phytase was calculated to be 108 kDa. The phytase had an optimum pH of 5.0–5.5 and an optimum temperature of 60°C. The phytase displayed high affinity for phytate, and the K _m was 0.52 mM. The purified phytase was sufficiently able to withstand pelleting temperatures, retaining sufficiently high phytate-degrading activity.     

A marked enhancement in phytase production by a thermophilic mould Sporotrichum thermophile using statistical designs in a cost-effective cane molasses medium

AIMS: Statistical optimization of phytase production by a thermophilic mould Sporotrichum thermophile in a cost-effective cane molasses medium. METHODS AND RESULTS: Sporotrichum thermophile secreted phytase in cane molasses medium at 45 degrees C and 250 rev min(-1) after 5 days. The important factors identified by Plackett-Burman design (magnesium sulfate, Tween 80, ammonium sulfate and incubation period) were further optimized by response surface methodology (RSM). An overall 107% improvement in phytase production was achieved due to optimization. Supplementation of the medium with inorganic phosphate repressed the enzyme synthesis. When inorganic phosphate was reduced from the cane molasses medium by treatment with calcium chloride, the enzyme production increased. The phytase activity was not affected by the enzyme treatment with trypsin and pepsin. CONCLUSIONS: A twofold increase in phytase production was achieved due to optimization using statistical designs in a cost-effective cane molasses medium. SIGNIFICANCE AND IMPACT OF THE STUDY: Phytase production was doubled due to optimization. The enzyme, being resistant to trypsin and pepsin, thermostable and acid stable, can find application in animal feed industry for improving nutritional status of the feed and combating environmental phosphorus pollution.     

Cell-surface phytase on Pichia pastoris cell wall offers great potential as a feed supplement

Cell-surface expression of phytase allows the enzyme to be expressed and anchored on the cell surface of Pichia pastoris . This avoids tedious downstream processes such as purification and separation involved with extracellular expression. In addition, yeast cells with anchored proteins can be used as a whole-cell biocatalyst with high value added. In this work, the phytase was expressed on the cell surface of P. pastoris with a glycosylphosphatidylinositol anchoring system. The recombinant phytase was shown to be located at the cell surface. The cell-surface phytase exhibited high activity with an optimal temperature at 50–55 °C and two optimal pH peaks of 3 and 5.5. The surface-displayed phytase also exhibited similar pH stability and pepsin resistance to the native and secreted phytase. In vitro digestibility test showed that P. pastoris containing cell-surface phytase released phosphorus from feedstuff at a level similar to secreted phytase. Yeast cells expressing phytase also provide additional nutrients, especially biotin and niacin. Thus, P. pastoris with phytase displayed on its surface has a great potential as a whole-cell supplement to animal feed.     

Enhancing the thermal tolerance and gastric performance of a microbial phytase for use as a phosphate-mobilizing monogastric-feed supplement

The inclusion of phytase in monogastric animal feed has the benefit of hydrolyzing indigestible plant phytate (myo-inositol 1,2,3,4,5,6-hexakis dihydrogen phosphate) to provide poultry and swine with dietary phosphorus. An ideal phytase supplement should have a high temperature tolerance, allowing it to survive the feed pelleting process, a high specific activity at low pHs, and adequate gastric performance. For this study, the performance of a bacterial phytase was optimized by the use of gene site saturation mutagenesis technology. Beginning with the appA gene from Escherichia coli, a library of clones incorporating all 19 possible amino acid changes and 32 possible codon variations in 431 residues of the sequence was generated and screened for mutants exhibiting improved thermal tolerance. Fourteen single site variants were discovered that retained as much as 10 times the residual activity of the wild-type enzyme after a heated incubation regimen. The addition of eight individual mutations into a single construct (Phy9X) resulted in a protein of maximal fitness, i.e., a highly active phytase with no loss of activity after heating at 62 degrees C for 1 h and 27% of its initial activity after 10 min at 85 degrees C, which was a significant improvement over the appA parental phytase. Phy9X also showed a 3.5-fold enhancement in gastric stability.     

Recombinant, rice-produced yeast phytase shows the ability to hydrolyze phytate derived from seed-based feed, and extreme stability during ensilage treatment

When fresh rice leaves producing yeast Schwanniomyces occidentalis phytase were grounded and mixed with the whole extract of seed-based feed for pigs, the release of orthophosphate increased significantly. More specifically, phytate, a major source of phosphorus in the seeds, was hydrolyzed by heterologous phytase. Moreover, when transgenic rice plants were ensiled for up to 12 weeks, no decrease in the phytase activity of the heterologous enzyme was observed. This result strongly suggests that transgenic rice plants producing yeast phytase can be stored as silage without any loss of enzyme activity until usage as a feed additive.