Xylanase from Pichia pastoris, CAS No.9025-57-4

CAS: 9025-57-4 Cat. No.: np226945 EC Number: 232-800-2
AVAILABLE TO ORDER
GRADE & PURITY Technical grade ? Technical grade — industrial-quality purity with no tight impurity guarantees. Use for large-scale or non-critical processes where cost matters most. ≥100 U/mg powder
Accession #
Q96TR7,Q2PGV8
Bioactivity
≥100 U/mg powder
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Size
Status
Price
Qty
5g
np226945-5g
3
$29.90
25g
np226945-25g
3
$67.90
100g
np226945-100g
3
$125.90
500g
np226945-500g
3
$239.90
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Why this grade

technical grade, ≥100 U/mg powder Technical grade for sensitive chromatographic and analytical workflows requiring minimal baseline interference.

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Storage & shipping

Store at 2-8°C Ships Wet ice Check lot-specific COA for exact specifications.

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Quality documents

SDS, COA, datasheet, and spec sheet available for download. Lot-specific COA accessible via lot number lookup.

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Literature proof

Cited in 18 peer-reviewed publications across chromatography, organic synthesis, and cross-coupling reactions.

Overview

  Xylanase is produced from high-quality strains of Pichia pastoris through submerged fermentation and refined extraction. It is widely used in baking, feed, brewing, functional xylo-oligosaccharide production, wheat deep processing and other fields.

Mechanism

  Xylanase is a complex enzyme system that degrades xylan into xylo-oligosaccharides and xylose, mainly including β-1,4-xylanase and β-xylosidase. Generally, the former acts on xylosidic bonds inside the main chain to break down xylan into oligosaccharides, while the latter hydrolyzes the ends of xylo-oligosaccharides, mainly cleaving xylo-oligosaccharides and xylobiose, facilitating the complete degradation of xylan into xylose.

Product Characteristics
  1. Temperature range: Effective temperature range 30–65℃, optimal temperature range 45–60℃.
  2. pH range: Effective pH range 3.0–7.0, optimal pH range 4.8–5.5.
  3. Effect of metal ions on enzyme activity: K⁺, Na⁺, Ca²⁺ and Mg²⁺ have no significant effect on xylanase activity; Zn²⁺ shows an activating effect; Mn²⁺ and Fe²⁺ show inhibitory effects; Cu²⁺ exhibits activation followed by inhibition as its concentration increases.
Application Method
  1. Food-grade xylanase for baking: Appropriate dosage can accelerate dough mixing speed and improve dough handling properties, as well as enhance water retention and gas retention of dough. Recommended dosage: 0.06–0.45 kg/t flour (enzyme activity calculated as 100,000 U/g, the same below). For optimal results, combined use with fungal α-amylase or refined medium-temperature α-amylase is recommended.
  2. Compound feed enzymes: Xylanase eliminates or reduces the anti-nutritional effects of non-starch polysaccharides, improves feed performance and enhances animal immunity. Recommended dosage: 0.01–0.05 kg/t raw material.
  3. Wheat beer (saccharification), sake, wine (pressing): Addition of this enzyme reduces extract viscosity and improves starch/sugar yield. Recommended dosage: 0.05–0.25 kg/t on dry basis. For optimal results, combined use with β-glucanase or neutral protease is recommended.
  4. Fruit juice production: Improves concentration speed and significantly increases product yield and quality. Recommended dosage: 0.05–0.1 kg/t on dry basis. For optimal results, combined use with pectinase and refined medium-temperature amylase is recommended.
  5. Xylo-oligosaccharide production: Xylo-oligosaccharides are known as "superior bifidogenic factors" and widely used in functional foods, pharmaceuticals, health products and feed additives. In enzymatic production of xylo-oligosaccharides, xylanase dosage is 0.1–0.2 kg/t on dry basis, maintained for 12–24 hours under optimal reaction conditions.
Storage

  This product is a biologically active substance; high temperature, strong acid and strong alkali will cause enzyme inactivation. During transportation and storage, liquid enzyme preparations shall be protected from direct sunlight, and solid enzyme preparations shall avoid exposure to sunlight and rain. The warehouse shall be kept clean, cool and dry.

Specifications

Product Name
Xylanase from Pichia pastoris, CAS No.9025-57-4
Synonyms
4-β-D-Xylanxylanohydrolase | endo-1 | 4-β-Xylanase | 4-beta-xylanase | xynI | xynII
Grade
Technical grade
Specifications & Purity
technical grade, ≥100 U/mg powder
Bioactivity
≥100 U/mg powder
Accession #
CAS
9025-57-4
Enzyme Commission Number
EC 3.2.1.8
Molecule Type
Enzyme
Storage and Shipping
Concentration
≥100 U/mg powder
Storage
Store at 2-8°C
Shipped In
Wet ice
Stability And Storage
Store at 4-20℃ long term (1 year).
Unit definition
One unit of enzyme activity (IU) is defined as the amount of enzyme required to liberate 1 μmol of reducing sugar per minute from a 10 mg/ml oat xylan solution under the conditions of 50°C and pH 4.8, with reducing sugar expressed as xylose equivalent.‌

Documentation

📋 Safety Data Sheet (SDS)

Comprehensive hazard, handling, storage, and regulatory compliance document.

Download SDS →

✅ Certificate of Analysis (COA)

Lot-specific quality data. Enter your lot number to retrieve the exact COA.

Look up COA →

📊 Datasheet

Quick-reference summary of product specifications and applications.

View datasheet →

🔬 Specification Sheet

Full quality attributes and acceptance criteria for this grade.

View spec sheet →

Advanced Data

Taxonomic Classification

Taxonomy Tree

KingdomOrganic compounds
SuperclassBenzenoids
ClassBenzene and substituted derivatives
SubclassPhenylmethylamines
Intermediate Tree Nodes Not available
Direct ParentPhenylmethylamines
Alternative Parents P-benzoquinones  Benzylamines  Aralkylamines  Vinylogous amides  Tetraalkylammonium salts  Enamines  Dialkylamines  Organopnictogen compounds  Organic salts  Organic oxides  Hydrocarbon derivatives  Organic cations  
Molecular FrameworkAromatic homomonocyclic compounds
Substituents Benzylamine - P-benzoquinone - Phenylmethylamine - Quinone - Aralkylamine - Tetraalkylammonium salt - Vinylogous amide - Quaternary ammonium salt - Ketone - Cyclic ketone - Secondary aliphatic amine - Enamine - Secondary amine - Hydrocarbon derivative - Organic nitrogen compound - Organic oxide - Organopnictogen compound - Organic oxygen compound - Organooxygen compound - Organonitrogen compound - Organic salt - Amine - Carbonyl group - Organic cation - Aromatic homomonocyclic compound
DescriptionThis compound belongs to the class of organic compounds known as phenylmethylamines. These are compounds containing a phenylmethtylamine moiety, which consists of a phenyl group substituted by an methanamine.
External Descriptors Not available
3D Structure
Interactive Chemical Structure Model





Certificates(CoA,COO,BSE/TSE and Analysis Chart)
C of A & Other Certificates(BSE/TSE, COO):
Analytical Chart:
Documents & Articles
Citations of This Product
References
1. Fenghong Deng, Shunjing Luo, Xiuting Hu, Chengmei Liu.  (2023)  Preparation, structural characterization and properties of feruloyl oligosaccharide–rice protein hydrolysate conjugates.  FOOD RESEARCH INTERNATIONAL,      [PMID:38163734] [10.1016/j.foodres.2023.113844]
2. Yang Zhao, Luyue Zhang, Shiyu Zhang, Xing Zheng, Mingzhu Zheng, Jingsheng Liu.  (2023)  Maleic anhydride-modified xylanase and its application to the clarification of fruits juices.  Food Chemistry-X,      [PMID:37780259] [10.1016/j.fochx.2023.100830]
3. Si Zhenyuan, Cai Yang, Zhao Lang, Han Lu, Wang Feng, Yang Xiaobing, Gao Xiangdong, Lu Meiling, Liu Wei.  (2023)  Structure and function characterization of the α-L-arabinofuranosidase from the white-rot fungus Trametes hirsuta.  APPLIED MICROBIOLOGY AND BIOTECHNOLOGY,      [PMID:37178306] [10.1007/s00253-023-12561-w]
4. Fenghong Deng, Xiuting Hu, Yueru Wang, Shunjing Luo, Chengmei Liu.  (2023)  Improving the Yield of Feruloyl Oligosaccharides from Rice Bran through Enzymatic Extrusion and Its Mechanism.  Foods,  12  (7): (1369).  [PMID:37048191] [10.3390/foods12071369]
5. Sheng Li, Nannan Hu, Jinying Zhu, Mingzhu Zheng, Huimin Liu, Jingsheng Liu.  (2022)  Influence of modification methods on physicochemical and structural properties of soluble dietary fiber from corn bran.  Food Chemistry-X,      [PMID:35399582] [10.1016/j.fochx.2022.100298]
6. Yi Zhang, Xihui Kang, Feng Zhen, Zhongming Wang, Xiaoying Kong, Yongming Sun.  (2021)  Assessment of enzyme addition strategies on the enhancement of lipid yield from microalgae.  BIOCHEMICAL ENGINEERING JOURNAL,      [PMID:] [10.1016/j.bej.2021.108198]
7. Fulong Zhang, Wu Lan, Zengyong Li, Aiping Zhang, Baoling Tang, Huihui Wang, Xiaoying Wang, Junli Ren, Chuanfu Liu.  (2021)  Co-production of functional xylo-oligosaccharides and fermentable sugars from corn stover through fast and facile ball mill-assisted alkaline peroxide pretreatment.  BIORESOURCE TECHNOLOGY,      [PMID:34118741] [10.1016/j.biortech.2021.125327]
8. Yu Zhu, Chenghu He, Haixiao Fan, Zhaoxin Lu, Fengxia Lu, Haizhen Zhao.  (2018)  Modification of foxtail millet (Setaria italica) bran dietary fiber by xylanase-catalyzed hydrolysis improves its cholesterol-binding capacity.  LWT-FOOD SCIENCE AND TECHNOLOGY,      [PMID:] [10.1016/j.lwt.2018.11.052]
9. Yi Zhang, Xiaoying Kong, Zhongming Wang, Yongming Sun, Shunni Zhu, Lianhua Li, Pengmei Lv.  (2018)  Optimization of enzymatic hydrolysis for effective lipid extraction from microalgae Scenedesmus sp..  RENEWABLE ENERGY,      [PMID:] [10.1016/j.renene.2018.01.078]
10. Xiang Zou, Jing Yang, Xu Tian, Meijing Guo, Zhenghua Li, Yunzheng Li.  (2015)  Production of polymalic acid and malic acid from xylose and corncob hydrolysate by a novel Aureobasidium pullulans YJ 6–11 strain.  PROCESS BIOCHEMISTRY,      [PMID:] [10.1016/j.procbio.2015.11.018]
11. Xiang Zou, Yongkang Wang, Guangwei Tu, Zhanquan Zan, Xiaoyan Wu.  (2015)  Adaptation and Transcriptome Analysis of Aureobasidium pullulans in Corncob Hydrolysate for Increased Inhibitor Tolerance to Malic Acid Production.  PLoS One,  10  (3): (e0121416).  [PMID:25793624] [10.1371/journal.pone.0121416]
12. Xin Wang, Yang Liu, Jiali Pu, Chengrong Qin, Shuangquan Yao, Shuangfei Wang, Chen Liang.  (2024)  A comparative study on the structure of lignin-carbohydrate complexes in alkali-soluble hemicellulose from bamboo (Bambusa chungii) fibers and parenchyma cells.  INDUSTRIAL CROPS AND PRODUCTS,      [PMID:] [10.1016/j.indcrop.2024.118061]
13. Jiagang Guo, Yuhan Wu, Siyu Sun, Qian Zhu, Jingjing Du, Jiayu Gu, Song Yang, Jian Jiang.  (2025)  Effect of different extraction methods on physicochemical, functional and antioxidant properties of bamboo shoot protein.  LWT-FOOD SCIENCE AND TECHNOLOGY,      [PMID:] [10.1016/j.lwt.2025.117328]
14. Lian Li, Jia Zheng, Li Yao, Hong Wang, Yiyi Lv, Guichun Huang, Shuyi Qiu, Xiangyong Zeng, Chaoyang Wei.  (2024)  Enzyme and Microwave Coassisted Extraction, Physicochemical Properties, and Antioxidant Activity of Polysaccharides from Baijiu Distillers' Grains.  STARCH-STARKE,      [PMID:] [10.1002/star.202300302]
15. Xin Wang, Shuyu Pang, Baojie Liu, Chen Liang, Shuangquan Yao, Chengrong Qin, Shuangfei Wang, Yang Liu.  (2024)  Structural evolution and reaction kinetics of lignin-carbohydrate complex oxidized by chlorine dioxide.  CHEMICAL ENGINEERING JOURNAL,      [PMID:] [10.1016/j.cej.2024.154018]
16. Fulong Zhang, Xu Zeng, Wu Lan, Xuejin Zhang, Chuanfu Liu.  (2025)  Comprehensive study of xylobiose and cellobiose separation from corn stover enzymatic hydrolysate by adsorption.  INDUSTRIAL CROPS AND PRODUCTS,      [PMID:] [10.1016/j.indcrop.2025.120921]
17. Mengyuan Li, Binghua Sun, Li Li, Sen Ma.  (2026)  Molecular mechanisms of antifreeze activity in wheat bran arabinoxylan: The role of fine structure in modulating water-ice dynamic changes.  FOOD RESEARCH INTERNATIONAL,      [PMID:41819912] [10.1016/j.foodres.2026.118718]
18. Feiyue Liu, Gaoqi Ye, Genying Li, Ruoyan Yang, Jie Liu, Lingxiao Gong, Jing Wang.  (2026)  Pretreatment of soybean hulls hemicellulose in ionic liquid facilitates anti-inflammatory oligosaccharides preparation.  FOOD CHEMISTRY,      [PMID:] [10.1016/j.foodchem.2026.148835]
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