Back Article

Adetunji AI, Olaniran AO. 2021. Production strategies and biotechnological relevance of microbial lipases: a review. Brazilian Journal of Microbiology 52:1257−69

Gurung N, Ray S, Bose S, Rai V. 2013. A broader view: microbial enzymes and their relevance in industries medicine and beyond. Biomed Research International 2013:329121

Adetunji AI, Olaniran AO. 2023. Biocatalytic profiling of free and immobilized partially purified alkaline protease from an autochthonous Bacillus aryabhattai Ab15-ES. Reactions 4:231−45

Singh R, Kumar M, Mittal A, Mehta PK. 2016. Microbial enzymes: industrial progress in 21st century. 3 Biotech 6:174

Prakash D, Nawani N, Prakash M, Bodas M, Mandal A, et al. 2013. Actinomycetes: a repertory of green catalysts with a potential revenue resource. BioMed Research International 2013:264020

Kieliszek M, Pobiega K, Piwowarek K, Kot AM. 2021. Characteristics of the proteolytic enzymes produced by lactic acid bacteria. Molecules 26(7):1858

Shankar S, Rao M, Laxman RS. 2011. Purification and characterization of an alkaline protease by a new strain of Beauveria sp. Process Biochemistry 46:579−85

Ibrahim ASS, Al-Salamah AA, El-Badawi YB, El-Tayeb MA, Antranikian G. 2015. Detergent-, solvent- and salt-compatible thermoactive alkaline serine protease from halotolerant alkaliphilic Bacillus sp. NPST-AK15: purification and characterization. Extremophiles 19:961−71

Singh S, Bajaj BK. 2017. Potential application spectrum of microbial proteases for clean and green industrial production. Energy Ecology and Environment 2:370−86

Matkawala F, Nighojkar S, Kumar A, Nighojkar A. 2021. Microbial alkaline serine proteases: production, properties and applications. World Journal of Microbiology and Biotechnology 37:63

Singhal P, Nigam VK, Vidyarthi AS. 2012. Studies on production, characterization and applications of microbial alkaline proteases. International Journal Advanced Biotechnology and Research 3:653−69

Sawant R, Nagendran S. 2014. Protease: an enzyme with multiple industrial applications. World Journal of Pharmacy and Pharmaceutical Sciences 3:568−79

De Souza PM, Bittencourt MLA, Caprara CC, de Freitas M, de Almeida RPC, et al. 2015. A biotechnology perspective of fungal proteases. Brazilian Journal of Microbiology 46:337−46

Goda DA, Bassiouny AR, Abdel Monem NM, Soliman NA, Abdel Fattah YR. 2020. Effective multi-functional biotechnological applications of protease/keratinase enzyme produced by new Egyptian isolate (Laceyella sacchari YNDH). Journal of Genetic Engineering and Biotechnology 18:23

Milošević J, Vrhovac L, Đurković F, Janković B, Malkov S, et al. 2020. Isolation, identification, and stability of ficin 1c isoform from fig latex. New Journal of Chemistry 44:15716−23

Romero-Garay MG, Martínez-Montaño E, Hernández-Mendoza A, Vallejo-Cordoba B, González-Córdova AF, et al. 2020. Bromelia karatas and Bromelia pinguin: sources of plant proteases used for obtaining antioxidant hydrolysates from chicken and fish by-products. Applied Biological Chemistry 63:41

Shouket HA, Ameen I, Tursunov O, Kholikova K, Pirimov O, et al. 2020. Study on industrial applications of papain: a succinct review. IOP Conference Series: Earth Environmental Science 614:012171

Van der Hoorn RAL, Klemenčič M. 2021. Plant proteases: from molecular mechanisms to functions in development and immunity. Journal of Experimental Botany 72(9):3337−39

Rao MB, Tanksale AM, Ghatge MS, Deshpande VV. 1998. Molecular and biotechnological aspects of microbial proteases. Microbiology and Molecular Biology Reviews 62:597−635

González-Rábade N, Badillo-Corona JA, Aranda-Barradas JS, Oliver-Salvador MDC. 2011. Production of plant proteases in vivo and in vitro- a review. Biotechnology Advances 29:983−96

Singh S, Singh A, Kumar S, Mittal P, Singh IK. 2020. Protease inhibitors: recent advancement in its usage as a potential biocontrol agent for insect pest management. Insect Science 27(2):186−201

Fu Z, Akula S, Thorpe M, Hellman L. 2021. Marked difference in efficiency of the digestive enzymes pepsin, trypsin, chymotrypsin, and pancreatic elastase to cleave tightly folded proteins. Biological Chemistry 402(7):861−67

EFSA Panel on Food Contact Materials, Enzymes and Processing Aids (CEP), Silano V, Baviera JMB, Bolognesi C, et al. 2021. Safety evaluation of a food enzyme containing trypsin and chymotrypsin from porcine pancreas. EFSA Journal 19(1):e06369

Gupta R, Beg QK, Lorenz P. 2002. Bacterial alkaline proteases: molecular approaches and industrial applications. Applied Microbiology and Biotechnology 59:15−32

Haddar A, Bougatef A, Agrebi R, Sellami-Kamoun A, Nasri M. 2009. A novel surfactant-stable alkaline serine-protease from a newly isolated Bacillus mojavensis A21: purification and characterization. Process Biochemistry 44:29−35

Raval VH, Pillai S, Rawal CM, Singh SP. 2014. Biochemical and structural characterization of a detergent-stable serine alkaline protease from seawater haloalkaliphilic bacteria. Process Biochemistry 49:955−962

Kumar CG, Takagi H. 1999. Microbial alkaline proteases: from a bioindustrial viewpoint. Biotechnology Advances 17:561−594

Jisha VN, Smitha RB, Pradeep S, Sreedevi S, Unni KN, et al. 2013. Versatility of microbial proteases. Advances in Enzyme Research 1:39−51

Rieger TJ, de Oliveira CT, Pereira JQ, Brandelli PA, Daroit DJ. 2017. Proteolytic system of Bacillus sp. CL18 is capable of extensive feather degradation and hydrolysis of diverse protein substrates. British Poultry Science 58:329−35

Adetunji AI, Olaniran AO. 2020. Statistical modelling and optimization of protease production by an autochthonous Bacillus aryabhattai Ab15-ES: a response surface methodology approach. Biocatalysis and Agricultural Biotechnology 24:101528

Karray A, Alonazi M, Horchani H, Ben Bacha A. 2021. A novel thermostable and alkaline protease produced from Bacillus stearothermophilus isolated from olive oil mill sols suitable to industrial biotechnology. Molecules 26:1139

Mushtaq H, Jehangir A, Ganai SA, Farooq S, Ganai BA, et al. 2021. Biochemical characterization and functional analysis of heat stable high potential protease of Bacillus amyloliquefaciens strain HM48 from soils of Dachigam national park in Kashmir Himalaya. Biomolecules 11:117

Thebti W, Riahi Y, Belhadj O. 2016. Purification and characterization of a new thermostable, haloalkaline, solvent stable, and detergent compatible serine protease from Geobacillus toebii strain LBT 77. Biomed Research International 2016:9178962

Zhang S, Li H, Uluko H, Liu L, Pang X, et al. 2015. Investigation of protease production by Pseudomonas fluorescens BJ-10 and degradation on milk proteins. Journal of Food Processing and Preservation 39:2466−72

Silva GMM, Bezerra RP, Teixeira JA, Porto TS, Lima-Filho JL, et al. 2015. Fibrinolytic protease production by new Streptomyces sp. DPUA 1576 from Amazon lichens. Electronic Journal of Biotechnology 18:16−19

Mizuno T, Nanko A, Maehara Y, Shinoda S, Miyoshi SI. 2014. A novel extracellular protease of Vibrio mimicus that mediates maturation of an endogenous hemolysin. Microbiology and Immunology 58:503−12

Beganović J, Kos B, Pavunc AL, Uroić K, Džidara P, et al. 2013. Proteolytic activity of probiotic strain Lactobacillus helveticus M92. Anaerobe 20:58−64

Lü J, Wu X, Jiang Y, Cai X, Huang L, et al. 2014. An extremophile Microbacterium strain and its protease production under alkaline conditions. Journal of Basic Microbiology 54:378−85

Bhargavi PL, Prakasham RS. 2016. Enhanced fibrinolytic protease production by Serratia marcescens RSPB11 through Plackett-Burman and response surface methodological approaches. Journal of Applied Biology and Biotechnology 4:6−14

Shumi W, Hossain MDT, Anwar MN. 2004. Production of protease from Listeria monocytogenes. International Journal of Agriculture and Biology 6:1097−100

Rattray FP, Bockelmann W, Fox PF. 1995. Purification and characterization of an extracellular proteinase from Brevibacterium linens ATCC 9174. Applied Environmental Microbiology 61:3454−56

Yeo IO, Choi SH, Lee JS, Kim CJ. 1995. Characteristics of an alkaline protease from Alteromonas sp. Agricultural Chemistry and Biotechnology 38:106−10

Santos AF, Valle RS, Pacheco CA, Alvarez VM, Seldin L, et al. 2013. Extracellular proteases of Halobacillus blutaparonensis strain M9, a new moderately halophilic bacterium. Brazilian Journal of Microbiology 44:1299−304

Vandecandelaere I, Depuydt P, Nelis HJ, Coenye T. 2014. Protease production by Staphylococcus epidermidis and its effect on Staphylococcus aureus biofilms. Pathogens and Disease 70:321−31

Secades P, Guijarro JA. 1999. Purification and characterization of an extracellular protease from the fish pathogen Yersinia ruckeri and effect of culture conditions on production. Applied Environmental Microbiology 65:3969−75

Chang C, Gong S, Liu Z, Yan Q, Jiang Z. 2021. High level expression and biochemical characterization of an alkaline serine protease from Geobacillus stearothermophilus to prepare antihypertensive whey protein hydrolysate. BMC Biotechnology 21:21

Saba I, Qazi PH, Rather SA, Dar RA, Qadri QA, et al. 2012. Purification and characterization of a cold active alkaline protease from Stenotrophomonas sp., isolated from Kashmir, India. World Journal of Microbiology and Biotechnology 28:1071−79

Manni L, Misbah A, Zouine N, Ananou S. 2020. Biochemical characterization of a novel alkaline and detergent stable protease from Aeromonas veronii OB3. Microbiology and Biotechnology Letters 48(3):358−65

Chandrasekaran M, Sathiyabama M. 2014. Production, partial purification and characterization of protease from a phytopathogenic fungi Alternaria solani (Ell. and Mart.) Sorauer. Journal of Basic Microbiology 54:763−74

Lanka S, Anjali CH, Pydipalli M. 2017. Enhanced production of alkaline protease by Aspergillus niger DEF 1 isolated from dairy form effluent and determination of its fibrinolytic ability. African Journal of Microbiological Research 11:440−49

Benluvankar V, Jebapriya GR, Gnanadoss JJ. 2015. Protease production by Penicillium sp. LCJ228 under solid state fermentation using groundnut oilcake as substrate. International Journal of Life Science and Pharma Research 5:2250−480

Al-Askar AA, AbdulKhair WM, Rashad YM. 2014. Production, purification and optimization of protease by Fusarium solani under solid fermentation and isolation of protease inhibitor protein from Rumex vesicarius L. Journal of Pure and Applied Microbiology 8:239−50

Liu N, Huang L. 2015. Partial characterization of an acidic protease from Rhizopus stolonifer RN-11. Open Biotechnology Journal 9:199−203

Shivasharanappa K, Hanchinalmath JV, Sundeep YS, Borah D, Talluri VSSLP. 2014. Optimization and production of alkaline proteases from agro byproducts using a novel Trichoderma viridiae strain VPG 12, isolated from agro soil. International Letters of Natural Sciences 9:78−84

Alves MH, de Campos-Takaki GM, Okada K, Pessoa IHF, Milanez AI. 2005. Detection of extracellular protease in Mucor species. Revista Iberoamericana de Micologia 22:114−17

de Oliveira JM, Fernandes P, Benevides RG, de Assis SA. 2020. Characterization and immobilization of protease secreted by the fungus Moorella speciosa. 3 Biotech 10:419

Tsuchiya K, Arai T, Seki K, Kimura T. 1987. Purification and some properties of alkaline proteinases from Cephalosporium sp. KSM388. Agriculture and Biological Chemistry 51:2959−65

Schlander M, Distler U, Tenzer S, Thines E, Claus H. 2017. Purification and properties of yeast proteases secreted by Wickerhamomyces anomalus 227 and Metschnikovia pulcherrima 446 during growth in a white grape juice. Fermentation 3:2

Matoba S, Morano KA, Klionsky DJ, Kim K, Ogrydziak DM. 1997. Dipeptidyl aminopeptidase processing and biosynthesis of alkaline extracellular protease from Yarrowia lipolytica. Microbiology 143:3263−72

Hesham AEL, Alrumman SA, Al-Dayel MA, Salah HA. 2017. Screening and genetic identification of acidic and neutral protease-producing yeasts strains by 26S rRNA gene sequencing. Cytology and Genetics 51:221−29

Razzaq A, Shamsi S, Ali A, Ali Q, Sajjad M, et al. 2019. Microbial proteases applications. Frontiers in Bioengineering and Biotechnology 7:110

Vijayalakshmi S, Venkat KS, Thankamani V. 2011. Optimization and cultural characterization of Bacillus RV. B2.90 producing alkalophilic thermophilic protease. Research Journal of Biotechnology 6:26−32

Barett AJ. 1994. Proteolytic enzymes: serine and cysteine peptidases.Methods in Enzymology. vol. 244. Amsterdam: Elsevier. 765 pp. https://doi.org/10.1016/s0076-6879(00)x0290-x

Li Q, Yi L, Marek P, Iverson BL. 2013. Commercial proteases: present and future. FEBS Letters 587:1155−63

Lundqvist H, Dahlgren C. 1995. The serine protease inhibitor diisopropylfluorophosphate inhibits neutrophil NADPH-oxidase activity induced by calcium ionophore ionomycin and serum opsonised yeast particles. Inflammation Research 44:510−517

Barzkar N, Khan Z, Tamadoni Jahromi S, Pourmozaffar S, Gozari M, et al. 2021. A critical review on marine serine protease and its inhibitors: a new wave of drugs? International Journal of Biological Macromolecules 170:674−87

Ellaiah P, Srinivasulu B, Adinarayana K. 2002. A review on microbial alkaline proteases. Journal of Scientific and Industrial Research 61:690−704

Raveendran S, Parameswaran B, Ummalyma SB, Abraham A, Mathew AK, et al. 2018. Applications of microbial enzymes in food industry. Food Technology and Biotechnology 56:16−30

Singh R, Mittal A, Kumar M, Mehta PK. 2016. Microbial proteases in commercial applications. Journal of Pharmaceutical, Chemical and Biological Sciences 4:365−74

Solanki P, Putatunda C, Kumar A, Bhatia R, Walia A. 2021. Microbial proteases: ubiquitous enzymes with innumerable uses. 3 Biotech 11:428

Sundus H, Mukhtar H, Nawaz A. 2016. Industrial applications and production sources of serine alkaline proteases: a review. Journal of Bacteriology and Mycology 3:191−94

Barzkar N. 2020. Marine microbial alkaline protease: an efficient and essential tool for various industrial applications. International Journal of Biological Macromolecules 161:1216−29

Hailemichael F. 2021. Production and industrial application of microbial aspartic protease: a review. International Journal of Food Engineering and Technology 5:85−90

Vachher M, Sen A, Kapila R, Nigam A. 2021. Microbial therapeutic enzymes: a promising area of biopharmaceuticals. Current Research in Biotechnology 3:195−208

Mamo J, Assefa F. 2018. The role of microbial aspartic protease enzyme in food and beverage industries. Journal of Food Quality 2018:7957269

Srilakshmi J, Madhavi J, Lavanya S. Ammani K. 2015. Commercial potential of fungal protease: past, present and future prospects. Journal of Pharmaceutical, Chemical and Biological Sciences 2:218−34

Mukherjee AK, Adhikari H, Rai SK. 2008. Production of alkaline protease by a thermophilic Bacillus subtilis under solid-state fermentation (SSF) condition using Imperata cylindrica grass and potato peel as low-cost medium: characterization and application of enzyme in detergent formulation. Biochemical Engineering Journal 39:353−61

Reddy LVA, Wee YJ, Yun JS, Ryu HW. 2008. Optimization of alkaline protease production by batch culture of Bacillus sp. RKY3 through Plackett-Burman and response surface methodological approaches. Bioresource Technology 99:2242−49

Usman A, Mohammed S, Mamo J. 2021. Production, optimization, and characterization of an acid protease from filamentous fungus by solid-state fermentation. International Journal of Microbiology 2021:1−12

Beg QK, Saxena RK, Gupta R. 2002. De-repression and subsequent induction of protease synthesis by Bacillus mojavensis under fed-batch operations. Process Biochemistry 37:1103−9

Anandan D, Marmer WN, Dudley RL. 2007. Isolation, characterization and optimization of culture parameters for production of an alkaline protease isolated from Aspergillus tamari. Industrial Microbiology and Biotechnology 34:339−47

Bhunia B, Basak B, Dey A. 2012. A review on production of serine alkaline protease by Bacillus spp. Journal of Biochemical Technology 3:448−57

Navanneth S, Bhuvanesh S, Bhaskar V, Vijay KP, Kandaswamy SKJ, et al. 2009. Optimization of medium for the production of subtilisin from Bacillus subtilis MTCC 441. African Journal of Biotechnology 8:6327−31

Queiroga AC, Pintado ME, Malcata FX. 2012. Use of response surface methodology to optimize protease synthesis by a novel strain of Bacillus sp. isolated from Portuguese sheep wool. Journal of Applied Microbiology 113:36−43

Sharma KM, Kumar R, Vats S, Gupta A. 2014. Production, partial purification and characterization of alkaline protease from Bacillus arybhattai K3. International Journal of advanced Pharmaceutical and Biological Chemistry 3:290−98

Sharma A, Sharma V, Saxena J, Yadav B, Alam A, et al. 2015. Optimization of protease production from bacteria isolated from soil. Applied Research Journal 1:388−394

Sathish Kumar R, Ananthan G, Selva Prabhu A. 2014. Optimization of medium composition for alkaline protease production by Marinobacter sp. GA CAS9 using response surface methodology - A statistical approach. Biocatalysis and Agricultural Biotechnology 3:191−97

Badhe P, Joshi M, Adivarekar R. 2016. Optimized production of extracellular proteases by Bacillus subtilis from degraded abattoir waste. Journal of Bioscience and Biotechnology 5:29−36

Akcan N. 2012. Production of extracellular protease in submerged fermentation by Bacillus licheniformis ATCC 12759. African Journal of Biotechnology 11:1729−35

Puri S, Beg QK, Gupta R. 2002. Optimization of alkaline protease production from Bacillus sp. by response surface methodology. Current Microbiology 44:286−90

Srividya S, Mala M. 2011. Influence of process parameters on the production of detergent compatible alkaline protease by a newly isolated Bacillus sp. Y. Turkish Journal of Biology 35:177−82

Pathak AP, Deshmukh KB. 2012. Alkaline protease production, extraction and characterization from alkaliphilic Bacillus licheniformis KBDL4: a lonar soda lake isolate. Indian Journal of Experimental Biology 50:569−76

Gouda MK. 2006. Optimization and purification of alkaline proteases produced by marine Bacillus sp. MIG newly isolated from eastern harbour of Alexandria. Polish Journal of Microbiology 55:119−26

Singh SK, Tripathi VR, Jain RK, Vikram S, Garg SK. 2010. An antibiotic, heavy metal resistant and halotolerant Bacillus cereus SIU1 and its thermoalkaline protease. Microbial Cell Factories 9:59

Nisha NS, Divakaran J. 2014. Optimization of alkaline protease production from Bacillus subtilis NS isolated from sea water. African Journal of Biotechnology 13:1707−13

Jothiprakasam V, Sambantham M, Chinnathambi S. 2014. Optimization of alkaline protease production and its fibrinolytic activity from the bacterium Pseudomonas fluorescens isolated from fish waste discharged soil. African Journal of Biotechnology 13:3052−60

Jaswal RK, Kocher GS, Virk MS. 2008. Production of alkaline protease by Bacillus circulans using agricultural residues: A statistical approach. Indian Journal of Biotechnology 7:356−60

Khosravi-Darani K, Falahatpishe HR, Jalali M. 2008. Alkaline protease production on date waste by an alkalophilic Bacillus sp. 2-5 isolated from soil. African Journal of Biotechnology 7:1536−42

Lakshmi BKM, Hemalatha KPJ. 2014. Response surface optimization of medium composition for alkaline protease production by Bacillus cereus strain S8. International Journal of Pure Applied Bioscience 3:216−23

Ibrahim ASS, Al-Salamah AA, Elbadawi YB, El-Tayeb MA, Ibrahim SSS. 2015. Production of extracellular alkaline protease by new halotolerant alkaliphilic Bacillus sp. NPST-AK15 isolated from hyper saline soda lakes. Electronic Journal of Biotechnology 18:236−43

Zambare V, Nilegaonkar S, Kanekar P. 2011. A novel extracellular protease from Pseudomonas aeruginosa MCM B-327: enzyme production and its partial characterization. New Biotechnology 28:173−81

Ravishankar K, Kumar MA, Saravanan K. 2012. Isolation of alkaline protease from Bacillus subtilis AKRS3. African Journal of Biotechnology 11:13415−27

Maal KB, Emtiazi G, Nahvi I. 2009. Production of alkaline protease by Bacillus cereus and Bacillus polymyxa in new industrial culture medium and its immobilization. African Journal of Microbiological Research 3:491−97

Abusham RA, Rahman RNZR, Salleh AB, Basri M. 2009. Optimization of physical factors affecting the production of thermo-stable organic solvent-tolerant protease from a newly isolated halo tolerant Bacillus subtilis strain Rand. Microbial Cell Factories 8:20

Bezerra VHS, Cardoso SL, Fonseca-Bazzo Y, Silveira D, Magalhães PO, et al. 2021. Protease produced by endophytic fungi: a systematic review. Molecules 26:7062

Sepahy AA, Jabalameli L. 2011. Effect of culture conditions on the production of an extracellular protease by Bacillus sp. isolated from soil sample of Lavizan jungle park. Enzyme Research 2011:219628

Hammami A, Bayoudh A, Abdelhedi O, Nasri M. 2018. Low-cost culture medium for the production of proteases by Bacillus mojavensis SA and their potential use for the preparation of antioxidant protein hydrolysate from meat sausage by-products. Annals of Microbiology 68:473−84

Elgammal EW, El-Khonezy MI, Ahmed EF, Abd-Elaziz AM. 2020. Enhanced production, partial purification, and characterization of alkaline thermophilic protease from the endophytic fungus Aspergillus ochraceus BT21. Egyptian Pharmaceutical Journal 19:338−49

Suleiman AD, Abdul Rahman N, Yusof HM, Shariff FM, Yasid NA. 2020. Effect of cultural conditions on protease production by a thermophilic Geobacillus thermoglucosidasius SKF4 isolated from Sungai Klah hot spring park. Malaysia. Molecules 25:2609

Sellami-Kamoun A, Ghorbel-Frikha B, Haddar A, Nasri M. 2011. Enhanced Bacillus cereus BG1 protease production by the use of sardinelle (Sardinella aurita) powder. Annals of Microbiology 61:273−80

Gomri MA, Rico-Díaz A, Escuder-Rodríguez JJ, El Moulouk Khaldi T, González-Siso MI, et al. 2018. Production and characterization of an extracellular acid protease from thermophilic Brevibacillus sp. OA30 isolated from an Algerian hot spring. Microorganisms 6:31

Chittoor JT, Balaji L, Jayaraman G. 2016. Optimization of parameters that affect the activity of the alkaline protease from halotolerant bacterium, Bacillus acquimaris VITP4, by the application of response surface methodology and evaluation of the storage stability of the enzyme. Iranian Journal of Biotechnology 14:23−32

Mienda BS, Yahya A. 2011. Engineering of microbial proteases: improving stability and catalytic performances. IIOAB Journal 2:10−15

Rigo E, Rigoni RE, Lodea P, de Oliveira D, Freire DMG, et al. 2008. Application of different lipases as pretreatment in anaerobic treatment of wastewater. Environmental Engineering Science 25:1243−48

Mugdha A, Usha M. 2012. Enzymatic treatment of wastewater containing dyestuffs using different delivery systems. Scientific Reviews and Chemical Communications 2:31−40

Sullivan TGO, Epstein AC, Korchin SR, Beaton NC. 1984. Applications of ultrafiltration in biotechnology. Chemical Engineering Progress 80:68−75

Ratnaningsih E, Reynard R, Khoiruddin K, Wenten IG, Boopathy R. 2021. Recent advancements of UF-based separation for selective enrichment of proteins and bioactive peptides-a review. Applied Sciences 11:1078

Valério R, Crespo JG, Galinha CF, Brazinha C. 2021. Effect of ultrafiltration operating conditions for separation of ferulic acid from arabinoxylans in corn fibre alkaline extract. Sustainability 13:4682

Bell DJ, Hoare M, Dunnill P. 1983. The formation of protein precipitates and their centrifugal recovery. In Downstream Processing. Advances in Biochemical Engineering/Biotechnology. Vol 26. Heidelberg: Springer, Berlin. pp. 1−72. https://doi.org/10.1007/BFb0001860

Muthulakshmi C, Gomathi D, Kumar DG, Ravikumar G, Kalaiselvi M, et al. 2011. Production, purification and characterization of protease by Aspergillus flavus under solid state fermentation. Jordan of Biological Sciences 4:137−48

Prabhavathy G, Rajasekara Pandian M, Senthikumar B. 2013. Identification of industrially important alkaline protease producing Bacillus subtilis by 16s rRNA sequence analysis and its applications. International Journal of Research in Pharmaceutical and Biomedical Sciences 4:332−38

Iqbalsyah TM, Atikah M, Febriani F. 2019. Purification and partial characterization of a thermo-halostable protease produced by Geobacillus sp. strain PLS A isolated from undersea fumaroles. Journal of Taibah University Science 13(1):850−57

Hussain S, Rehman Au, Luckett DJ, Naqvi SMS, Blanchard CL. 2021. Protease inhibitors purified from the canola meal extracts of two genetically diverse genotypes exhibit antidiabetic and antihypertension properties. Molecules 26:2078

Boxi A, Parikh I, Radhika BS, Shryli KS. 2020. Current trends in protein purification: a review. International Journal of Scientific Research in Science and Technology 7(6):279−310

Lalli E, Silva JS, Boi C, Sarti GC. 2020. Affinity membranes and monoliths for protein purification. Membranes 10:1

Mahmoodi S, Pourhassan-Moghaddam M, Wood DW, Majdi H, Zarghami N. 2019. Current affinity approaches for purification of recombinant proteins. Cogent Biology 5:1665406

Matsuda Y, Leung M, Okuzumi T, Mendelsohn B. 2020. A purification strategy utilizing hydrophobic interaction chromatography to obtain homogeneous species from a site-specific antibody drug conjugate produced by AJICAP^TM first generation. Antibodies 9:16

Osuna-Amarillas PS, Rouzaud-Sandez O, Higuera-Barraza OA, Arias-Moscoso JL, Lόpez-Mata MA, et al. 2019. Hydrophobic interaction chromatography as a separation method of alkaline protease from viscera of Scomberomorus sierra. TIP Revista Especializada en Cienc Químico-Biologicas 22:1−10

Pereira Bresolin IRA, Lingg N, Bresolin ITL, Jungbauer A. 2020. Hydrophobic interaction chromatography as polishing step enables obtaining ultra-pure recombinant antibodies. Journal of Biotechnology 324:100020

Mohamad NR, Marzuki NHC, Buang NA, Huyop F, Wahab RA. 2015. An overview of technologies for immobilization of enzymes and surface analysis techniques for immobilized enzymes. Biotechnology and Biotechnological Equipment 29:205−20

Calzoni E, Cesaretti A, Tacchi S, Caponi S, Pellegrino RM, et al. 2021. Covalent immobilization of proteases on polylactic acid for proteins hydrolysis and waste biomass protein content valorization. Catalysts 11:167

Tischer W, Wedenkind F. 1999. Immobilized enzymes: methods and applications. In Biocatalysis - From Discovery to Application. Topics in Current Chemistry, ed. Fessner WD, Archelas A, Demirjian DC, et al. Heidelberg: Springer, Berlin. pp. 95−126. https://doi.org/10.1007/3-540-68116-7_4

Duman YA, Tekin N. 2020. Kinetic and thermodynamic properties of purified alkaline protease from Bacillus pumilus Y7 and non-covalent immobilization to poly(vinylimidazole)/clay hydrogel. Engineering in Life Sciences 20(1-2):36−49

Datta S, Rene CL, Rajaram YRS. 2013. Enzyme immobilization: an overview on techniques and support materials. 3 Biotech 3:1−9

Adetunji AI, Olaniran AO. 2018. Immobilization and characterization of lipase from an indigenous Bacillus aryabhattai SE3-PB isolated from lipid-rich wastewater. Preparative Biochemistry and Biotechnology 48(10):898−905

Kamal S, Hussain F, Bibi I, Azeem M, Ahmad T, et al. 2022. Mutagenesis and immobilization of chitB-protease for induced de-staining and goat skin dehairing potentialities. Catalysis Letters 152:12−27

Asuri P, Karajanagi SS, Sellitto E, Kim DY, Kane RS, et al. 2006. Water-soluble carbon nanotube-enzyme conjugates as functional biocatalytic formulations. Biotechnology and Bioengineering 95:804−11

Sheldon RA. 2007. Cross-linked enzyme aggregates (CLEA®s): stable and recyclable biocatalysts. Biochemical Society 35:1583−87

Tian X, Anming W, Lifeng H, Haifeng L, Zhenming C, et al. 2009. Recent advance in the support and technology used in enzyme immobilization. African Journal of Biotechnology 8:4724−33

Hernandez K, Fernandez-Lafuente R. 2011. Control of protein immobilization: coupling immobilization and site-directed mutagenesis to improve biocatalyst or biosensor performance. Enzyme and Microbial Technology 48:107−22

Saifuddin N, Raziah AZ, Junizah AR. 2013. carbon nanotubes: a review on structure and their interaction with proteins. Journal of Chemistry 2013:676815

Qamar SA, Asgher M, Bilal M. 2020. Immobilization of alkaline protease from Bacillus brevis using Ca-Alginate entrapment strategy for improved catalytic stability silver recovery, and dehairing potentialities. Catalysis Letters 150:3572−83

Soleimani M, Khani A, Najafzadeh K. 2012. Biotechnology expanding horizonsa-amylase immobilization on the silica nanoparticles for cleaning performance towards starch soils in laundry detergents. Journal of Molecular Catalysis B: Enzymatic 74:1−5

Mason RD, Detar CC, Weetall HH. 1975. Protease covalently coupled to porous glass: preparation and characterization. Biotechnology and Bioengineering 17(7):1019−27

Khan AA, Akhtar S, Husain Q. 2006. Direct immobilization of polyphenol oxidases on celite 545 from ammonium sulphate fractionated proteins of potato (Solanum tuberosum). Journal of Molecular Catalysis B 40:58−63

Ansari SA, Husain Q. 2012. Lactose hydrolysis from milk/whey in batch and continuous processes by concanavalin A-celite 545 immobilized Aspergillus oryzae β-galactosidase. Food and Bioproducts Processing 90:351−359

Wu C, Zhou G, Jiang X, Ma J, Zhang H, et al. 2012. Active biocatalysts based on Candida rugosa lipase immobilized in vesicular silica. Process Biochemistry 47:953−959

Gemenier P. 1992. Materials for enzyme engineering. In Enzyme Engineering, ed. Gemeiner P. 1st Edition. New York: Ellis Horwood. pp. 113−19

Brena BM, Viera BF. 2006. Immobilization of enzymes. In Immobilization of enzymes and cells, ed. : Guisan JM. 3rd Edition. New Jersey: Humana Press Inc. pp. 123−24. https://doi.org/10.1007/978-1-62703-550-7

Kim J, Grate JW, Wang P. 2006. Nanostructures for enzyme stabilization. Chemical and Engineering Science 61:1017−26

Lee CH, Lin TS, Mou CY. 2009. Mesoporous materials for encapsulating enzymes. Nanotoday 4:165−79

Huang XJ, Chen PC, Huang F, Ou Y, Chen MR, et al. 2011. Immobilization of Candida rugosa lipase on electrospun cellulose nanofiber membrane. Journal of Molecular Catalysis B: Enzymatic 70:95−100

Geethanjali S, Subash A. 2013. Optimization and immobilization of purified Labeo rohita visceral protease by entrapment method. Enzyme Research 2013:874050

Park JM, Kim M, Park HS, Jang M, Min J, et al. 2013. Immobilization of lysozyme-CLEA onto electrospun chitosan nanofiber for effective antimicrobial applications. International Journal of Biological Macromolecules 54:37−43

Sahin S, Ozmen I, Kir E. 2015. Purification, immobilization, and characterization of protease from local Bacillus subtilis M-11. Asia-Pacific Journal of Chemical Engineering 10:241−47

Guleria S, Walia A, Chauhan A, Shirkot CK. 2016. Immobilization of Bacillus amyloliquefaciens SP1 and its alkaline protease in various matrices for effective hydrolysis of casein. 3 Biotech 6:208

Ibrahim ASS, Al-Salamah AA, El-Toni AM, Almaary KS, El-Tayeb MA, et al. 2016. Enhancement of alkaline protease activity and stability via covalent immobilization onto hollow core-mesoporous shell silica nanospheres. International Journal of Molecular Sciences 17:184

Silva CJSM, Zhang Q, Shen J, Cavaco-Paulo A. 2006. Immobilization of proteases with a water soluble-insoluble reversible polymer for treatment of wool. Enzyme and Microbial Technology 39:634−40

Nandan A, Nampoothiri KM. 2020. Therapeutic and biotechnological applications of substrate specific microbial aminopeptidases. Applied Microbiology and Biotechnology 104:5243−57

Sharma KM, Kumar R, Panwar S, Kumar A. 2017. Microbial alkaline proteases: optimization of production parameters and their properties. Journal of Genetic Engineering and Biotechnology 15:115−26

Mothe T, Sultanpuram VR. 2016. Production, purification and characterization of a thermotolerant alkaline serine protease from a novel species Bacillus caseinilyticus. 3 Biotech 6:53

Yilmaz B, Baltaci MO, Sisecioglu M, Adiguzel A. 2016. Thermotolerant alkaline protease enzyme from Bacillus licheniformis A10: purification, characterization, effects of surfactants and organic solvents. Journal of Enzyme Inhibition and Medicinal Chemistry 31:1241−47

Nadeem M, Qazi JI, Syed Q, Gulsher M. 2013. Purification and characterization of an alkaline protease from Bacillus licheniformis UV-9 for detergent formulations. Songklanakarin Journal of Science and Technology 35:187−95

Jayakumar R, Jayashree S, Annapurna B, Seshadri S. 2012. Characterization of thermostable serine alkaline protease from an alkaliphilic strain Bacillus pumilus MCAS8 and its applications. Applied Biochemistry and Biotechnology 168:1849−66

Patil U, Mokashe N, Chaudhari A. 2016. Detergent-compatible, organic solvent-tolerant alkaline protease from Bacillus circulans MTCC 7942: purification and characterization. Preparative Biochemistry and Biotechnology 46:56−64

Sari E, Loğoğlu E, Öktemer A. 2015. Purification and characterization of organic solvent stable serine alkaline protease from newly isolated Bacillus circulans M34. Biomedical Chromatography 29:1356−63

Waghmare SR, Gurav AA, Mali SA, Nadaf NH, Jadhav DB, et al. 2015. Purification and characterization of novel organic solvent tolerant 98 kDa alkaline protease from isolated Stenotrophomonas maltophilia strain SK. Protein Expression and Purification 107:1−6

Yildirim V, Baltaci MO, Ozgencli I, Sisecioglu M, Adiguzel A, et al. 2017. Purification and biochemical characterization of a novel thermostable serine alkaline protease from Aeribacillus pallidus C10: a potential additive for detergents. Journal of Enzyme Inhibition and Medicinal Chemistry 32:468−77

Xin Y, Sun Z, Chen Q, Wang J, Wang Y, et al. 2015. Purification and characterization of a novel extracellular thermostable alkaline protease from Streptomyces sp. M30. Journal of Microbiology and Biotechnology 25:1944−53

Firouzbakht H, Zibaee A, Hoda H, Sohani MM. 2015. Purification and characterization of the cuticle-degrading proteases produced by an isolate of Beauveria bassiana using the cuticle of the predatory bug, Andrallus spinidens Fabricius (Hemiptera: Pentatomidae). Journal of Plant Protection Research 55(2):179−86

Adinarayana K, Ellaiah P, Prasad DS. 2003. Purification and partial characterization of thermostable serine alkaline protease from a newly isolated Bacillus subtilis PE-11. AAPS PharmSciTech 4:56

Jaouadi B, Ellouz-Chaabouni S, Rhimi M, Bejar S. 2008. Biochemical and molecular characterization of a detergent-stable serine alkaline protease from Bacillus pumilus CBS with high catalytic efficiency. Biochimie 90:1291−305

Akel H, Al-Quadan F, Yousef TK. 2009. Characterization of a purified thermostable protease from hyperthermophilic Bacillus strain HUTBS71. European Journal of Scientific Research 31:280−88

Sarker PK, Talukdar SA, Deb P, Sayem SMS, Mohsina K. 2013. Optimization and partial characterization of culture conditions for the production of alkaline protease from Bacillus licheniformis P003. Springerplus 2:506

Bose A, Chawdhary V, Keharia H, Subramanian RB. 2014. Production and characterization of a solvent-tolerant protease from a novel marine isolate Bacillus tequilensis P15. Annals of Microbiology 64:343−54

Maruthiah T, Esakkiraj P, Prabakaran G, Palavesam A, Immanuel G. 2013. Purification and characterization of moderately halophilic alkaline serine protease from marine Bacillus subtilis AP-MSU 6. Biocatalysis and Agricultural Biotechnology 2:116−19

Benkiar A, Nadia ZJ, Badis A, Rebzani F, Soraya BT, et al. 2013. Biochemical and molecular characterization of a thermo- and detergent-stable alkaline serine keratinolytic protease from Bacillus circulans strain DZ100 for detergent formulations and feather-biodegradation process. International Biodeterioration & Biodegradation 83:129−38

Joshi S, Satyanarayana T. 2013. Characteristics and applications of a recombinant alkaline serine protease from a novel bacterium Bacillus lehensis. Bioresource Technology 131:76−85

Annamalai N, Rajeswari MV, Balasubramanian T. 2014. Extraction, purification and application of thermostable and halostable alkaline protease from Bacillus alveayuensis CAS 5 using marine wastes. Food and Bioproducts Processing 92:335−42

Nilegaonkar SS, Zambare VP, Kanekar PP, Dhakephalkar PK, Sarnaik SS. 2007. Production and partial characterization of dehairing protease from Bacillus cereus MCM B-326. Bioresource Technology 98:1238−45

Ahmetoglu N, Bekler FM, Acer O, Guven RG, Guven K. 2015. Production, purification and characterization of thermostable metallo-protease from newly isolated Bacillus sp. KG5. EurAsian Journal of Biosciences 9:1−11

Lagzian M, Asoodeh A. 2012. An extremely thermotolerant, alkaliphilic subtilisin-like protease from hyperthermophilic Bacillus sp. MLA64. International Journal of Biological Macromolecules 51:960−67

Moradian F, Khajeh K, Naderi-Manesh H, Ahmadvand R, Sajedi RH, et al. 2006. Thiol-dependent serine alkaline proteases from Bacillus sp. HR-08 and KR-8102: isolation, production, and characterization. Applied Biochemistry and Biotechnology 134:77−87

Farhadian S, Asoodeh A, Lagzian M. 2015. Purification, biochemical characterization and structural modeling of a potential htrA-like serine protease from Bacillus subtilis DR8806. Journal of Molecular Catalysis B: Enzymatic 115:51−58

Tekİn N, Cİhan AÇ, Takaç ZS, Tüzün CY, Tunç K, et al. 2012. Alkaline protease production of Bacillus cohnii APT5. Turkish Journal of Biology 36:430−40

Ahmed I, Zia MA, Iqbal HMN. 2011. Purification and kinetic parameters characterization of an alkaline protease produced from Bacillus subtilis through submerged fermentation technique. World Applied Science Journal 12:751−57

Zhou C, Qin H, Chen X, Zhang Y, Xue Y, et al. 2018. A novel alkaline protease from alkaliphilic idiomarina sp C9-1 with potential application for eco-friendly enzymatic dehairing in the leather industry. Scientific Reports 8:16467

Sugumaran KR, Ponnusami V, Gowdhaman D, Gunasekar V, Srivastava SN. 2012. Thermostable alkaline protease production from Bacillus thuringiensis MTCC 1953: optimization and kinetic studies. International Journal of ChemTech Research 4:198−202

Subba Rao C, Sathish T, Ravichandra P, Prakasham RS. 2009. Characterization of thermo- and detergent stable serine protease from isolated Bacillus circulans and evaluation of eco-friendly applications. Process Biochemistry 44:262−68

Jain D, Pancha I, Mishra SK, Shrivastav A, Mishra S. 2012. Purification and characterization of haloalkaline thermoactive, solvent stable and SDS-induced protease from Bacillus sp.: a potential additive for laundry detergents. Bioresource Technology 115:228−36

Ghobadi Nejad Z, Yaghmaei S, Moghadam N, Sadeghein B. 2014. Some investigations on protease enzyme production kinetics using Bacillus licheniformis BBRC 100053 and effects of inhibitors on protease activity. International Journal of Chemical Engineering 2014:394860

Adetunji AI, Olaniran AO. 2018. Treatment of lipid-rich wastewater using a mixture of free or immobilized bioemulsifier and hydrolytic enzymes from indigenous bacterial isolates. Desalination and Water Treatment 132:274−80

Herman RA, Ayepa E, Zhang WX, Li ZN, Zhu X, et al. 2023. Molecular modification and biotechnological applications of microbial aspartic proteases. Critical Reviews in Biotechnology

Al-Ghanayem AA, Joseph B. 2020. Current prospective in using cold-active enzymes s eco-friendly detergent additive. Applied Microbiology and Biotechnology 104:2871−82

Dai R, Ten AS, Mrksich M. 2019. Profiling protease activity in laundry detergents with peptide arrays and SAMDI mass spectrometry. Industrial and Engineering Chemistry Research 58(25):10692−97

Grbavčić S, Bézbradica D, Izrael-Živković L, Avramović N, Milosavić N, et al. 2011. Production of lipase and protease from an indigenous Pseudomonas aeruginosa strain and their evaluation as detergent additives: compatibility study with detergent ingredients and washing performance. Bioresource Technology 102:11226−33

Baweja M, Tiwari R, Singh PK, Nain L, Shukla P. 2016. An alkaline protease from Bacillus pumilus MP 27: functional analysis of its binding model toward its applications as detergent additive. Frontiers in Microbiology 7:1195

Olsen HS, Falholt P. 1998. The role of enzymes in modern detergency. Journal of Surfactants and Detergents 1:555−67

Niyonzima FN, More S. 2015. Detergent-compatible proteases: microbial production, properties, and stain removal analysis. Preparative Biochemistry and Biotechnology 45(3):233−58

Nascimento WCAd, Martins MLL. 2006. Studies on the stability of protease from Bacillus sp. and its compatibility with commercial detergent. Brazilian Journal of Microbiology 37:307−11

Ghafoor A, Hasnain S. 2009. Characteristics of an extracellular protease isolated from Bacillus subtilis AG-1 and its performance in relation to detergent components. Annals of Microbiology 59:559−63

Abou-Elela GM, Ibrahim HAH, Hassan SW, Abd-Elnaby H, El-Toukhy NMK. 2011. Alkaline protease production by alkaliphilic marine bacteria isolated from Marsa-Matrouh (Egypt) with special emphasis on Bacillus cereus purified protease. African Journal of Biotechnology 10:4631−42

Bezawada J, Yan S, John RP, Tyagi RD, Surampalli RY. 2011. Recovery of Bacillus licheniformis alkaline protease from supernatant of fermented wastewater sludge using ultrafiltration and its characterization. Biotechnology Research International 2011:238549

Jaouadi B, Abdelmalek B, Jaouadib NZ, Bejar S. 2011. The bioengineering and industrial applications of bacterial alkaline proteases: the case of SAPB and KERAB. In Progress in Molecular and Environmental Bioengineering - From Analysis and Modeling to Technology Applications, ed. Carpi A. Rijeka: IntechOpen. http://doi.org/10.5772/23850

Mojsov K. 2011. Applications of enzymes in the textile industry: a review. 2^nd International Congress: Engineering, Ecology and Materials in the Processing Industry: Jahorina, Bosnia and Herzegovina. Tehnoloski Fakultet Zvornik. pp. 230−39

Navarro D, Wu J, Lin W, Fullana-i-Palmer P, Puig R. 2020. Life cycle assessment and leather production. Journal of Leather Science and Engineering 2(1):321−33

Choudhary RB, Jana AK, Jha MK. 2004. Enzyme technology applications in leather processing. Indian Journal of Chemical Technology 11:659−71

Famielec S. 2020. Chromium concentrate recovery from solid tannery waste in a thermal process. Materials 13(7):1533

Hasan MJ, Haque P, Rahman MM. 2022. Protease enzyme based cleaner leather processing: A review. Journal of Cleaner Production 365:132826

Adrio JL, Demain AL. 2014. Microbial enzymes: tools for biotechnological processes. Biomolecules 4:117−39

Khambhaty Y. 2020. Applications of enzymes in leather processing. Environmental Chemistry Letters 18:747−69

de Souza FR, Gutterres M. 2012. Application of enzymes in leather processing: a comparison between chemical and coenzymatic processes. Brazilian Journal of Chemical Engineering 29:471−81

Biškauskaitė R, Valeikienė V, Valeika V. 2021. Enzymes for leather processing: effect on pickling and chroming. Materials 14(6):1480

Jaouadi NZ, Rekik H, Badis A, Trabelsi S, Belhoul M, et al. 2013. Biochemical and molecular characterization of a serine keratinase from Brevibacillus brevis US575 with promising keratin-biodegradation and hide-dehairing activities. PLoS ONE 8:e76722

Arunachalam C, Sarita K. 2009. Protease enzyme: an eco-friendly alternative for leather industry. Indian Journal of Science and Technology 2:29−32

Vijayaraghavan P, Lazarus S, Vincent SGP. 2014. De-hairing protease production by an isolated Bacillus cereus strain AT under solid-state fermentation using cow dung: biosynthesis and properties. Saudi Journal of Biological Sciences 21:27−34

Kshetri P, Ningthoujam DS. 2016. Keratinolytic activities of alkaliphilic Bacillus sp. MBRL 575 from a novel habitat, limestone deposit site in Manipur, India. SpringerPlus 5:595

Ward OP. 2011. Proteases. In Comprehensive Biotechnology, ed. Moo-Young M. 2^nd Edition. Burlington: Academic Press. pp. 571−82. https://doi.org/10.1016/B978-0-08-088504-9.00222-1

Pai JS. 2003. Application of microorganisms in food biotechnology. Indian Journal of Biotechnology 2:382−86

Qureshi MA, Khare AK, Pervez A. 2015. Enzymes used in dairy industries. International Journal of Applied Research 1:523−27

Arshad MS, Kwon JH, Imran M, Sohaib M, Aslam A, et al. 2016. Plant and bacterial proteases: a key towards improving meat tenderization, a mini review. Cogent Food and Agriculture 2(1):1261780

Dahiya S, Bajaj BK, Kumar A, Tiwari SK, Singh B. 2020. A review on biotechnological potential of multifarious enzymes in bread making. Process Biochemistry 99:290−306

Meghwanshi GK, Kaur N, Verma S, Dabi NK, Vashishtha A, et al. 2020. Enzymes for pharmaceutical and therapeutic applications. Biotechnology and Applied Biochemistry 67(4):586−601

Verma A, Singh H, Anwar S, Chattopadhyay A, Tiwari KK, et al. 2017. Microbial keratinases: industrial enzymes with waste management potential. Critical Reviews in Biotechnology 37(4):476−91

Karam J, Nicell JA. 1997. Potential applications of enzymes in waste treatment. Journal of Chemical Technology and Biotechnology 69:141−53

Pandey D, Singh R, Chand D. 2011. An improved bioprocess for synthesis of acetohydroxamic acid using DTT (dithiothreitol) treated resting cells of Bacillus sp. APB-6. Bioresource Technology 102:6579−86

Venugopal V, Alur MD, Nerkar DP. 1989. Solubilization of fish proteins using immobilized microbial cells. Biotechnology and Bioengineering 33:1098−1103

Abdul Gafar A, Khayat ME, Ahmad SA, Yasid NA, Shukor MY. 2020. Response surface methodology for the optimization of keratinase production in culture medium containing feathers by Bacillus sp. UPM-AAG1. Catalysts 10:848

Nnolim NE, Udenigwe CC, Okoh AI, Nwodo UU. 2020. Microbial keratinase: next generation green catalyst and prospective applications. Frontiers in Microbiology 11:580164

Kojima M, Kanai M, Tominaga M, Kitazume S, Inoue A, et al. 2006. Isolation and characterization of a feather-degrading enzyme from Bacillus pseudofirmus FA30-01. Extremophiles 10:229−35

Cortezi M, Contiero J, de Lima CJB, Lovaglio RB, Monti R. 2008. Characterization of a feather degrading by Bacillus amyloliquefaciens protease: a new strain. World Journal of Agricultural Science 4:648−56

Ni H, Chen QH, Chen F, Fu ML, Dong YC, et al. 2011. Improved keratinase production for feather degradation by Bacillus licheniformis ZJUEL31410 in submerged cultivation. African Journal of Biotechnology 10:7236−44

Ul Haq I, Akram F, Jabbar Z. 2020. Keratinolytic enzyme-mediated biodegradation of recalcitrant poultry feathers waste by newly isolated Bacillus sp. NKSP-7 under submerged fermentation. Folia Microbiologica 65:823−34

Dalev PG. 1994. Utilisation of waste feathers from poultry slaughter for production of a protein concentrate. Bioresource Technology 48:265−67

Mukhopadhyay RP, Chandra AL. 1992. Application of Streptomycete in the removal of waste keratinous materials. In Industrial Biotechnology, eds. Malik VS, Sridhar P. New Delhi: Oxford & IBH Publishing Co. Pvt. Ltd. pp. 595−97

Takami H, Nakamura S, Aono R, Horikoshi K. 1992. Degradation of human hair by a thermostable alkaline protease from alkaliphilic Bacillus sp. no. AH-101. Bioscience, Biotechnology and Biochemistry 56:1667−69

Li Q. 2021. Structure, application, and biochemistry of microbial keratinases. Frontiers in Microbiology 12:674345

Chanalia P, Gandhi D, Jodha D, Singh J. 2011. Applications of microbial proteases in pharmaceutical industry: an overview. Reviews in Medical Microbiology 22:96−101

Kudrya VA, Simonenko IA. 1994. Alkaline serine proteinase and lectin isolation from the culture fluid of Bacillus subtilis. Applied Microbiology and Biotechnology 41:505

Altaf F, Wu S, Kasim V. 2021. Role of fibrinolytic enzymes in anti-thrombosis therapy. Frontiers in Molecular Biosciences 8:680397

Vaisar T, Pennathur S, Green PS, Gharib SA, Hoofnagle AN, et al. 2007. Shotgun proteomics implicates protease inhibition and complement activation in the antiinflammatory properties of HDL. The Journal of Clinical Investigation 117:746−56

Tamimi Z, Al Habashneh R, Hamad I, Al-Ghazawi M, Abu Roqa'a A, et al. 2021. Efficacy of serratiopeptidase after impacted third molar surgery: a randomized controlled clinical trial. BMC Oral Health 21:91

Fossati A. 1999. Antiinflammatory effects of seaprose-S on various inflammation models. Drugs under Experimental and Clinical Research 24:263−70

Watanabe K. 2004. Collagenolytic proteases from bacteria. Applied Microbiology and Biotechnology 63:520−26

Alipour H, Raz A, Zakeri S, Dinparast Djadid N. 2016. Therapeutic applications of collagenase (metalloproteases): a review. Asian Pacific Journal of Tropical Biomedicine 6(11):975−81

Wu JA, Kusuma C, Mond JJ, Kokai-Kun JF. 2003. Lysostaphin disrupts Staphylococcus aureus and Staphylococcus epidermidis biofilms on artificial surfaces. Antimicrobial Agents and Chemotherapy 47:3407−14

Bastos MCF, Coutinho BG, Coelho MLV. 2010. Lysostaphin: a staphylococcal bacteriolysin with potential clinical applications. Pharmaceuticals 3:1139−61

Jayakumar J, Kumar VA, Biswas L, Biswas R. 2021. Therapeutic applications of lysostaphin against Staphylococcus aureus. Journal of Applied Microbiology 131(3):1072−82

Pratt CB, Simone JV, Zee P, Aur RJA, Johnson WW. 1970. Comparison of daily versus weekly L-asparaginase for the treatment of childhood acute leukemia. Journal of Pediatrics 77:474−83

Siritapetawee J, Thammasirirak S, Samosornsuk W. 2012. Antimicrobial activity of a 48-kDa protease (AMP48) from Artocarpus heterophyllus latex. European Review for Medical and Pharmacological Sciences 16:132−37