“Industrial enzymes”的意思、由来-开放百科全书

Despite their excellent catalytic capabilities, enzymes and their properties must be improved prior to industrial implementation in many cases. Some aspects of enzymes that must be improved prior to implementation are stability, activity, inhibition by reaction products, and selectivity towards non-natural substrates. This may be accomplished through immobilization of enzymes on a solid material, such as a porous support.^[2] Immobilization of enzymes greatly simplifies the recovery process, enhances process control, and reduces operational costs. Many immobilization techniques exist, such as adsorption, covalent binding, affinity, and entrapment.^[3] Ideal immobilization processes should not use highly toxic reagents in the immobilization technique to ensure stability of the enzymes.^[4] After immobilization is complete, the enzymes are introduced into a reaction vessel for biocatalysis.

Adsorption

Enzyme adsorption onto carriers functions based on chemical and physical phenomena such as van der Waals forces, ionic interactions, and hydrogen bonding. These forces are weak, and as a result, do not affect the structure of the enzyme. A wide variety of enzyme carriers may be used. Selection of a carrier is dependent upon the surface area, particle size, pore structure, and type of functional group.^[5]

Covalent binding

Many binding chemistries may be used to adhere an enzyme to a surface to varying degrees of success. The most successful covalent binding techniques include binding via glutaraldehyde to amino groups and N-hydroxysuccinide esters. These immobilization techniques occur at ambient temperatures in mild conditions, which have limited potential to modify the structure and function of the enzyme.^[6]

Affinity

Entrapment

Immobilization using entrapment relies on trapping enzymes within gels or fibers, using non-covalent interactions. Characteristics that define a successful entrapping material include high surface area, uniform pore distribution, tunable pore size, and high adsorption capacity.^[3]

Recovery

Enzymes typically constitute a significant operational cost for industrial processes, and in many cases, must be recovered and reused to ensure economic feasibility of a process. Although some biocatalytic processes operate using organic solvents, the majority of processes occur in aqueous environments, improving the ease of separation.^[1] Most biocatalytic processes occur in batch, differentiating them from conventional chemical processes. As a result, typical bioprocesses employ a separation technique after bioconversion. In this case, product accumulation may cause inhibition of enzyme activity. Ongoing research is performed to develop in situ separation techniques, where product is removed from the batch during the conversion process. Enzyme separation may be accomplished through solid-liquid extraction techniques such as centrifugation or filtration, and the product-containing solution is fed downstream for product separation.^[1]

Enzymes as a desired product

To industrialize an enzyme, the following upstream and downstream enzyme production processes are considered:

Upstream

Selection of a suitable enzyme

An enzyme must be selected based upon the desired reaction. The selected enzyme defines the required operational properties, such as pH, temperature, activity, and substrate affinity.^[12]

Identification and selection of a suitable source for the selected enzyme

The choice of a source of enzymes is an important step in the production of enzymes. It is common to examine the role of enzymes in nature, and how they relate to the desired industrial process. Enzymes are most commonly sourced through bacteria, fungi, and yeast. Once the source of the enzyme is selected, genetic modifications may be performed to increase the expression of the gene responsible for producing the enzyme.^[12]

Process development

Process development is typically performed after genetic modification of the source organism, and involves the modification of the culture medium and growth conditions. In many cases, process development aims to reduce mRNA hydrolysis and proteolysis.^[12]

Large scale production

Scaling up of enzyme production requires optimization of the fermentation process. Most enzymes are produced under aerobic conditions, and as a result, require constant oxygen input, impacting fermenter design. Due to variations in the distribution of dissolved oxygen, as well as temperature, pH, and nutrients, the transport phenomena associated with these parameters must be considered. The highest possible productivity of the fermenter is achieved at maximum transport capacity of the fermenter.^[12]^[13]

Downstream

Downstream processes are those that contribute to separation or purification of enzymes.

Removal of insoluble materials and recovery of enzymes from the source

The procedures for enzyme recovery depend on the source organism, and whether enzymes are intracellular or extracellular. Typically, intracellular enzymes require cell lysis and separation of complex biochemical mixtures. Extracellular enzymes are released into the culture medium, and are much simpler to separate. Enzymes must maintain their native conformation to ensure their catalytic capability. Since enzymes are very sensitive to pH, temperature, and ionic strength of the medium, mild isolation conditions must be used.^[12]

Concentration and primary purification of enzymes

Depending on the intended use of the enzyme, different levels purity are required. For example, enzymes used for diagnostic purposes must be separated to a higher purity than bulk industrial enzymes to prevent catalytic activity that provides erroneous results. Enzymes used for therapeutic purposes typically require the most rigorous separation. Most commonly, a combination of chromatography steps is employed for separation.^[12]

The purified enzymes are either sold in pure form and sold to other industries, or added to consumer goods.

See also

References

1. ^¹²³{{Cite journal|last=Schmid|first=A.|last2=Dordick|first2=J. S.|last3=Hauer|first3=B.|last4=Kiener|first4=A.|last5=Wubbolts|first5=M.|last6=Witholt|first6=B.|title=Industrial biocatalysis today and tomorrow|journal=Nature|volume=409|issue=6817|pages=258–268|doi=10.1038/35051736|pmid=11196655|year=2001}}
2. ^{{Cite journal|last=Mateo|first=Cesar|last2=Fernandez-Lorente|first2=Gloria|last3=Guisan|first3=Jose|last4=Fernandez-Lafuente|first4=Roberto|year=2007|title=Improvement of enzyme activity, stability and selectivity via immobilization techniques|url=http://www.sciencedirect.com/science/article/pii/S0141022907000506|journal=Enzyme and Microbial Technology|volume=40|pages=|via=}}
3. ^¹²{{Cite journal|last=Datta|first=Sumitra|last2=Christena|first2=L. Rene|last3=Rajaram|first3=Yamuna Rani Sriramulu|date=2017-04-17|title=Enzyme immobilization: an overview on techniques and support materials|journal=3 Biotech|volume=3|issue=1|pages=1–9|doi=10.1007/s13205-012-0071-7|issn=2190-5738|pmc=3563746|pmid=28324347}}
4. ^{{Cite book|title=Immobilization of Enzymes and Cells|last=Guisan|first=Jose|publisher=Springer Science & Business Media|year=2006|isbn=|location=|pages=}}
5. ^{{Cite journal|last=Jesionowski|first=Teofil|last2=Zdarta|first2=Jakub|last3=Krajewska|first3=Barbara|date=2014-08-01|title=Enzyme immobilization by adsorption: a review|journal=Adsorption|language=en|volume=20|issue=5–6|pages=801–821|doi=10.1007/s10450-014-9623-y|issn=0929-5607}}
6. ^{{Cite book|title=Methods in Molecular Biology - New Protein Techniques|last=Walker|first=John|publisher=Humana Press|year=1988|isbn=|location=|pages=495–499}}
7. ^¹²³⁴⁵⁶{{Cite journal|last=Houde|first=Alain|last2=Kademi|first2=Ali|last3=Leblanc|first3=Danielle|date=2004-07-01|title=Lipases and their industrial applications: an overview|journal=Applied Biochemistry and Biotechnology|volume=118|issue=1–3|pages=155–170|issn=0273-2289|pmid=15304746}}
8. ^{{Cite journal|last=Sun|first=Ye|last2=Cheng|first2=Jiayang|date=2002-05-01|title=Hydrolysis of lignocellulosic materials for ethanol production: a review|url=http://www.sciencedirect.com/science/article/pii/S0960852401002127|journal=Bioresource Technology|series=Reviews Issue|volume=83|issue=1|pages=1–11|doi=10.1016/S0960-8524(01)00212-7|pmid=12058826}}
9. ^{{Cite journal|last=van der Maarel|first=Marc J. E. C|last2=van der Veen|first2=Bart|last3=Uitdehaag|first3=Joost C. M|last4=Leemhuis|first4=Hans|last5=Dijkhuizen|first5=L|date=2002-03-28|title=Properties and applications of starch-converting enzymes of the α-amylase family|url=http://www.sciencedirect.com/science/article/pii/S0168165601004072|journal=Journal of Biotechnology|volume=94|issue=2|pages=137–155|doi=10.1016/S0168-1656(01)00407-2}}
10. ^{{Cite journal|last=Bhosale|first=S. H.|last2=Rao|first2=M. B.|last3=Deshpande|first3=V. V.|date=1996-06-01|title=Molecular and industrial aspects of glucose isomerase|journal=Microbiological Reviews|volume=60|issue=2|pages=280–300|issn=0146-0749|pmc=239444|pmid=8801434}}
11. ^{{Cite journal|last=Buchholz|first=Klaus|date=2016-05-01|title=A breakthrough in enzyme technology to fight penicillin resistance—industrial application of penicillin amidase|journal=Applied Microbiology and Biotechnology|language=en|volume=100|issue=9|pages=3825–3839|doi=10.1007/s00253-016-7399-6|pmid=26960323|issn=0175-7598}}
12. ^¹²³⁴⁵{{Cite book|title=Industrial Enzymes: Trends, Scope, and Relevance|last=Sharma|first=Kumar|last2=Beniwal|first2=Vikas|publisher=Nova Science Publishers, Inc.|year=2014|isbn=|location=|pages=}}
13. ^{{Cite book|title=Industrial Biorefineries and White Biotechnology|last=Taherzadeh|first=Madhavan|last2=Nampoothiri|first2=Christian|publisher=Elsevier B.V.|year=2015|isbn=978-0-444-63453-5|location=|pages=}}
14. ^{{Cite journal|last=Bekhit|first=Alaa A.|last2=Hopkins|first2=David L.|last3=Geesink|first3=Geert|last4=Bekhit|first4=Adnan A.|last5=Franks|first5=Philip|date=2014-01-01|title=Exogenous Proteases for Meat Tenderization|journal=Critical Reviews in Food Science and Nutrition|volume=54|issue=8|pages=1012–1031|doi=10.1080/10408398.2011.623247|issn=1040-8398|pmid=24499119}}
15. ^{{Cite journal|last=Lanvers-Kaminsky|first=Claudia|date=2017-03-01|title=Asparaginase pharmacology: challenges still to be faced|journal=Cancer Chemotherapy and Pharmacology|language=en|volume=79|issue=3|pages=439–450|doi=10.1007/s00280-016-3236-y|pmid=28197753|issn=0344-5704}}
16. ^{{Cite journal|last=González-Rábade|first=Nuria|last2=Badillo-Corona|first2=Jesús Agustín|last3=Aranda-Barradas|first3=Juan Silvestre|last4=Oliver-Salvador|first4=María del Carmen|date=2011-11-01|title=Production of plant proteases in vivo and in vitro — A review|url=http://www.sciencedirect.com/science/article/pii/S0734975011001492|journal=Biotechnology Advances|volume=29|issue=6|pages=983–996|doi=10.1016/j.biotechadv.2011.08.017|pmid=21889977}}
17. ^{{Cite journal|last=Kotb|first=Essam|date=2014-05-01|title=The biotechnological potential of fibrinolytic enzymes in the dissolution of endogenous blood thrombi|journal=Biotechnology Progress|language=en|volume=30|issue=3|pages=656–672|doi=10.1002/btpr.1918|pmid=24799449|issn=1520-6033}}
18. ^{{Cite web|url=http://www.5010358128009.detergent-info.com/|title=Spar Bio Laundry Tablets|last=|first=|date=|website=|archive-url=|archive-date=|dead-url=|access-date=2017-04-18}}

Enzymes as a unit operation

Immobilization