Pectin lyase

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pectin lyase
Identifiers
EC no. 4.2.2.10
CAS no. 9033-35-6
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Pectin lyase is a polysaccharide enzyme with a complex structure that is present in plant cell walls. It has a significant role in pectin degradation and different biotechnological and industrial applications. It can be found in many different organisms. [1]

Contents

EC number

The Pectin lyase is an enzyme whose EC number is (EC4.2.2.10). It is a numerical classification system for enzymes based on their catalyzed chemical reactions. [2]

Pectin pathway

Pectin lyase is a component that is found in plant cell walls. This enzyme creates unsaturated products by breaking the glycosidic bonds that are inside. Pectin lyase is critical for several biological processes, such as the maturation of fruits and reshaping of plant cell walls. The enzyme's reaction pathway contains binding to the substrate and active site, splitting of glycosidic bonds, unsaturated products forming, and product release. Pectin lyase is crucial to decaying plant materials and is commonly used in the food industry and biotechnology. [3]

Organisms and function

There are many organisms that contain the pectin lyase enzyme such as plants (Fruits and Vegetables), especially, during fruit maturation, some plants produce internal pectin lyases that lead to the analysis of pectin in cell walls, such as citrus, apples, and Pumpkin. The waste residues of citrus, apple, and pomelo and their peels are the major raw resources of pectin production because they are considered by-products of producing juice in the food industry. Also, it helps protect the plants from the damage that is caused by pathogenic microorganisms due to its rigidity and flexibility. In plant cell culture, it is combined with the enzyme cellulase to produce protoplasts by breaking down the plant cell walls. Pectin exhibits versatility in its chemical behavior depending on the conditions it is exposed to. It can undergo ester hydrolysis or glycosidic bond cleavage to produce galacturonic acid and alcohol when acid, alkali, or pectinase is present. When Pectin is subjected to specific conditions, such as low pH and high sugar concentration, it has the ability to form gel in the presence of sugar, acid, or calcium ions. This gel-forming property of pectin is commonly used in medication industries and food, where it acts as a thickening substance, stabilizer, and emulsifying agent in various food processing applications. Not only this but also, pectin is essential in medicine, cosmetics, and other industries, including the production of health-related products aimed at preventing and treating conditions such as diabetes and obesity are of concern. [3]

Crystal structure

The crystal structures of pectin lyase A (PNLA) from two different strains of Aspergillus niger which are N400 and 4M-147. PNLA shows that they have a parallel β sheet structure and share several structural features with pectate lyases such as amino acid stacks and an asparagine ladder. The three-dimensional structure has been used to identify the Pectin lyase B (PNLB) from Aspergillus niger structure with a resolution of 1.7Å. [1]

Crystal structure of Pectin Lyase Pectin...jpg
Crystal structure of Pectin Lyase

This image of crystal structure of pectin lyase represents the structural features of both pectin lyase (PNLA and PNLB). Letter A indicates (PNLA) from strain 4M-147. In (A), we see an overview of the pectin lyase A structure, depicted with arrows for β strands and coils for helices. The parallel β sheet 1 (PB1) is colored yellow, the green color refers to PB2, the color red refers to PB3 and the blue color indicates the antiparallel β sheet has a long T3 loop. Moving on to (PNLB), the letter B shows the backbone of pectin lyase with pink coils showing helices and arrows indicating β structures. The yellow color refers to parallel β sheet PB1, the blue color refers to PB2, and the red color refers to PB3. The orange indicates the antiparallel β structure in the first T3 turn and a short β strand in the third T3 loop. Additionally, the thick black lines represent the position of disulfide bonds. [1]

Active site

Every enzyme has an active site which is a specific area where a substrate binds and experiences a chemical reaction. This area of pectin involves special amino acid remnants that are attached to pectin, catalyze the splitting of glycosidic bonds, guarantee substrate specificity, and stabilize the reaction intermediate. The active site is pivotal to the ability of pectin lyase to efficiently break pectin which is known as a complex polysaccharide present in plant cell walls.[ citation needed ]

Nomenclature

The systematic name of this enzyme class is (1→4)-6-O-methyl-α-D-galacturonan lyase. Other names in common use include:

Biotechnology applications

The pectin lyase is playing a crucial role in many biotechnological uses including the textile industry, paper manufacturing, wastewater pretreatment of pectin, clarifying of the juice, and extraction of oil. It has the ability to efficiently break the pectin molecule's back bone by β-eliminating in order to form pectin-oligosaccharide. As a result, this method led to not producing a high level of toxic methanol and this process has the advantage of high efficiency, good enzymatic selectivity, and few by-products. [3] [1]

In addition, the presence of undesirable enzymatic activity in commercial pectinases may be detrimental to aroma because they are responsible for producing unpleasant volatile off flavor. There are many reports of fruit juice clarification by pectin lyases.

The alkaline pectinase is inappropriate for use in the food industry due to the acidic pH of fruit juices. However, they have a very high demand in the textile industries. They are used for retting of plant fibers such as ramie, sunn hemp, jute, flax and hemp. The first report on retting of sunn hemp (Crotalaria juncea) by pectin lyase produced by Aspergillus flavus MTCC 7589 was published in 2008 but this aspect of pectin lyases needs to be extensively investigated further. [4] [5] [6] [7]

Related Research Articles

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<span class="mw-page-title-main">Orange juice</span> Juice made from oranges

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<span class="mw-page-title-main">Exoenzyme</span> Enzyme that functions outside the cell it is secreted from

An exoenzyme, or extracellular enzyme, is an enzyme that is secreted by a cell and functions outside that cell. Exoenzymes are produced by both prokaryotic and eukaryotic cells and have been shown to be a crucial component of many biological processes. Most often these enzymes are involved in the breakdown of larger macromolecules. The breakdown of these larger macromolecules is critical for allowing their constituents to pass through the cell membrane and enter into the cell. For humans and other complex organisms, this process is best characterized by the digestive system which breaks down solid food via exoenzymes. The small molecules, generated by the exoenzyme activity, enter into cells and are utilized for various cellular functions. Bacteria and fungi also produce exoenzymes to digest nutrients in their environment, and these organisms can be used to conduct laboratory assays to identify the presence and function of such exoenzymes. Some pathogenic species also use exoenzymes as virulence factors to assist in the spread of these disease-causing microorganisms. In addition to the integral roles in biological systems, different classes of microbial exoenzymes have been used by humans since pre-historic times for such diverse purposes as food production, biofuels, textile production and in the paper industry. Another important role that microbial exoenzymes serve is in the natural ecology and bioremediation of terrestrial and marine environments.

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Rhamnogalacturonan-II (RG-II) is a complex polysaccharide component of pectin that is found in the primary cell walls of dicotyledonous and monocotyledonous plants and gymnosperms. It is supposed to be crucial for the plant cell wall integrity. RG-II is also likely to be present in the walls of some lower plants. Its global structure is conserved across vascular plants, albeit a number of variations within the RGII side chains have been observed between different plants. RG-II is composed of 12 different glycosyl residues including D-rhamnose, D-apiose, D-galactose, L-galactose, Kdo, D-galacturonic acid, L-arabinose, D-xylose, and L-aceric acid, linked together by at least 21 distinct glycosidic linkages. Some resides are further modified via methylation and acetylation. It moreover supports borate mediated cross-linking between different RGII side-chain apiosyl residues. The backbone consists of a linear polymer of alpha-1,4-linked D-galactopyranosiduronic acid. RG-II can be isolated from different sources, such as apple juice and red wine.

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<span class="mw-page-title-main">Glucanase</span>

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References

  1. 1 2 3 4 5 Yadav, Sangeeta; Yadav, Pramod Kumar; Yadav, Dinesh; Yadav, Kapil Deo Singh (2009-01-01). "Pectin lyase: A review". Process Biochemistry. 44 (1): 1–10. doi:10.1016/j.procbio.2008.09.012. ISSN   1359-5113.
  2. "Safety evaluation of the food enzyme pectin lyase from the genetically modified Aspergillus luchuensis strain FLOSC | EFSA". www.efsa.europa.eu. 2022-05-03. Retrieved 2023-10-24.
  3. 1 2 3 Zheng, Ling; Xu, Yinxiao; Li, Qian; Zhu, Benwei (2021-08-23). "Pectinolytic lyases: a comprehensive review of sources, category, property, structure, and catalytic mechanism of pectate lyases and pectin lyases". Bioresources and Bioprocessing. 8 (1): 79. doi: 10.1186/s40643-021-00432-z . ISSN   2197-4365. PMC   10992409 . PMID   38650254.
  4. Yadav S, Yadav PK, Yadav D, Yadav KD (2008). "Purification and characterisation of an acidic pectin lyase produced byAspergillus ficuum strain MTCC 7591 suitable for clarification of fruit juices". Annals of Microbiology. 58 (1): 61–65. doi: 10.1007/BF03179446 . S2CID   34944691.
  5. Yadav S, Yadav PK, Yadav D, Yadav KD (2008). "Purification and characterization of an alkaline pectin lyase from Aspergillus flavus". Process Biochem. 43 (5): 547–552. doi:10.1016/j.procbio.2008.01.015.
  6. Mantovani CF, Geimba MP, Brandelli A (2005). "Enzymatic clarification of fruit juices by fungal pectin lyase". Food Biotechnol. 19 (3): 173–181. doi:10.1080/08905430500316284. S2CID   83712284.
  7. Kapoor M, Beg QK, Bhushan B, Singh K, Dadhich KS, Hoondal GS (2001). "Application of alkaline thermostable polygalacturonase from Bacillus sp. MG-ep-2 in degumming of ramie (Boehemeria nivea) and sunn hemp (Crotalaria juncea) bast fibers". Process Biochem. 6: 803–807. doi:10.1016/S0032-9592(00)00282-X.

Further reading