A novel collagenolytic protease from <i>Mucor subtilissimus</i> UCP 1262: Comparative analysis of production and extraction in submerged and stated-solid fermentation

SOUZA, KESSIA P.S.; CUNHA, MÁRCIA N.C.; BATISTA, JUANIZE M.S.; OLIVEIRA, VAGNE M.; NASCIMENTO, THIAGO P.; CONNIFF, AMANDA E.S.; COSTA, ROMERO M.P.B.; PORTO, TATIANA S.; PORTO, CAMILA S.; PORTO, ANA LÚCIA F.

doi:10.1590/0001-3765202220201438

Abstract

This work aimed to compare the production of collagenolytic proteases produced by M. subtilissimus UCP1262 in submerged fermentation (SF) and solid-state fermentation (SSF) as well as extracting in aqueous two-phase system (ATPS). Collagenolytic protease production was performed in using MS-2 culture medium (SF) and soybean bran as substrate (SSF). Subsequently, the fermented liquid from both fermentations were used for the extraction of enzyme by ATPS, it was verified the influence of different variables from a factorial design 2³. In SSF the highest protease and collagenolytic activities were achieved with 362.66 U/mL and 179.81 U/mL, respectively. When compared with SF (26.33 and 18.70 U/mL) higher values were obtained in the activities. The protease partitioning from SF and SSF in ATPS showed a similar profile showing higher affinity for the polymer rich phase. The highest value for the response variable purification factor (3.49) was obtained in the system using SSF. Thus, SSF shows promise as a bioprocess for extracellular production of collagenolytic proteases, using of soybean bran as substrate had used sustainable raw material, aiming application this possible enzyme in the treatment of burns and postoperative scarring.

Key words
bioprocess; ATPS; filamentous fungus; sustainability

INTRODUCTION

Proteases are one of the most economically desirable biomolecules in the world market due to their physicochemical and catalytic properties, highlighting their use in leather processing, in the formulation and production of laundry detergents and soap, in the formulation and preparation of food products and beverages, and in the pharmaceutical segment (Gurumallesh et al. 2019GURUMALLESH P, ALAGU K, RAMAKRISHNAN B & MUTHUSAMY S. 2019. A systematic reconsideration on proteases. Int J Biol Macromol 128: 254-267.). Naturally, microorganisms can produce large amounts of proteases to meet industry demand through the development of bioprocesses to allow fermentation and hence the increase in the desired protease volume. All processing is performed through easily manipulated bioreactors and low-cost production (Alipour et al. 2016ALIPOUR H, RAZ A, ZAKERI S & DINPARAST DN. 2016. Therapeutic applications of collagenase (metalloproteases): A review. Asian Pac J Trop Biomed 6: 975-981., Belmessikh et al. 2013BELMESSIKH A, BOUKHALFA H, MECHAKRA-MAZA A, GHERIBI-AOULMI Z & AMRANE A. 2013. Statistical optimization of culture medium for neutral protease production by Aspergillus oryzae. Comparative study between solid and submerged fermentations on tomato pomace. J Taiwan Inst of Chem Eng 44: 377-385., Gurumallesh et al. 2019GURUMALLESH P, ALAGU K, RAMAKRISHNAN B & MUTHUSAMY S. 2019. A systematic reconsideration on proteases. Int J Biol Macromol 128: 254-267., Viniegra-González & Favela-Torres 2006VINIEGRA-GONZÁLEZ G & FAVELA-TORRES E. 2006. Why solid-state fermentation seems to be resistant to catabolite repression? Food Technol Biotechnol 44: 397-406.).

Microbial proteases of fungal origin may be produced in submerged or solid-state fermentation, such fermentations have their own characteristics. In submerged fermentation the microorganism is exposed to hydrodynamic forces whereas in solid fermentation the growth is restricted to the surface of the solid matrix. The growth of the fungus and the production of metabolites by these microorganisms in such systems depend on the availability of nutrients, geometric configuration of the matrix and the same microorganism in different types of fermentation can produce different amounts of enzymes or even different enzymes (Oda et al. 2006ODA K, KAKIZONO D, YAMADA O, IEFUJI H, AKITA O & IWASHITA K. 2006. Proteomic Analysis of Extracellular Proteins from. Appl Enviromen Microbiol 72: 3448-3457.).

Among the proteases of industrial importance is the collagenolytic protease or simply collagenase catalyze chemical processes and the ability to cleave the different types of collagen (Alipour et al. 2016ALIPOUR H, RAZ A, ZAKERI S & DINPARAST DN. 2016. Therapeutic applications of collagenase (metalloproteases): A review. Asian Pac J Trop Biomed 6: 975-981., Amaral et al. 2020AMARAL YMS, DA SILVA OS, DE OLIVEIRA RL & PORTO TS. 2020. Production, extraction, and thermodynamics protease partitioning from Aspergillus tamarii Kita UCP 1279 using PEG/sodium citrate aqueous two-phase systems. Prep Biochem Biotechnol 50(6): 619-626., Bhagwat & Dandge 2018BHAGWAT PK & DANDGE PB. 2018. Collagen and collagenolytic proteases: A review. Biocatal Agric Biotechnol 15: 43-55., Oliveira et al. 2020OLIVEIRA VM, CARNEIRO DA CUNHA MN, ASSIS CRD, BATISTA JMS, NASCIMENTO TP, SANTOS JF, LIMA CDA, VIANA-MARQUES DA, BEZERRA RSP & PORTO ALF. 2020. Separation and partial purification of collagenolytic protease from peacock bass (Cichla ocellaris) using different protocol: Precipitation and partitioning approaches. Biocatal Agric Biotechnol 24: 105509., Wanderley et al. 2017WANDERLEY MC, WANDERLEY DUARTE NETO JM, CAMPOS ALBUQUERQUE WW, ARAÚJO-VIANA DM, ALBUQUERQUE CL, CRUZ SILVÉRIO SI, LIMA FILHO JL, COUTO-TEIXEIRA JÁ & PORTO ALF. 2017. Purification and characterization of a collagenase from Penicillium sp. UCP 1286 by polyethylene glycol-phosphate aqueous two-phase system. Protein Expres Purif 133: 8-14.). Different genus of filamentous fungi has been described as producers of collagenases, Penicillium (Lima et al. 2013LIMA CA, JÚNIOR ACVF, FILHO JLL, CONVERTI A, MARQUES DAV, CARNEIRO-DA-CUNHA MG & PORTO ALF. 2013. Two-phase partitioning and partial characterization of a collagenase from Penicillium aurantiogriseum URM 4622: Application to collagen hydrolysis. Biochem Eng J 75: 64-71.) and Aspergillus (Silva 2018SILVA RR. 2018. Exploring the Fermentation Technology for Biocatalysts Production. Princ Appl Ferm Technol 5: 181-187.). Collagen, a collagenase substrate, is a fibrous, structural and insoluble protein that has high tensile strength, and is present mainly in the skin, cartilage, bones, tendons, teeth and blood vessels and the peptides resulting from degradation of collagen, also present several biological activities of industrial interest. This protein has broad application in the leather, cosmetic, biomedical, pharmaceutical and food processing industries (Bhagwat & Dandge 2018BHAGWAT PK & DANDGE PB. 2018. Collagen and collagenolytic proteases: A review. Biocatal Agric Biotechnol 15: 43-55., Oliveira et al. 2019OLIVEIRA VM, NERI RCA, MONTE FTD, ROBERTO NA, COSTA HMS, ASSIS CRD, SANTOS JF, BEZERRA RS & PORTO ALF. 2019. Crosslink-free collagen from Cichla ocellaris: Structural characterization by FT-IR spectroscopy and densitometric evaluation. J Molecule Struct 1176: 751-758.).

For production microbial enzymes is so easy, but as limiting factor their purification. Conventional systems for separating biomolecules are often unsatisfactory. The two-phase aqueous system (ATPS) is one of the most economical and feasible processes for extraction and pretreatment of biological compounds. ATPS is commonly composed of polymers such as polyethylene glycol (PEG) and dextran or a polymer and a salt. These ATPS components are mutually incompatible hydrophilic solutes which are dissolved in water above a certain critical concentration so that the biphasic system is formed (Ferreira et al. 2009FERREIRA JF, PADILHA GS & TAMBOURGI EB. 2009. Efeitos da massa molar e do pH sobre o equilíbrio termodinâmico do sistema bifásico aquoso PEG/fosfatos. Exacta - Engenharia de Produção 7: 49-56.).

This methodology offers several advantages in the purification of biomolecules such as: ease in increasing the scale; rapid mass transfer; achieved balance with low energy resources in the form of mechanical mixing; possibility of fast and selective operation; possibility of operation at room temperature; environmentally friendly (Nainegali et al. 2020NAINEGALI BS, IYYASWAMI RD & BELUR P. 2020. Partitioning of bio-active compounds from rinds of garcinia indica using aqueous two-phase system: Process evaluation and optimization. Sep Purif Technol 253: 117520.). Therefore, the objective of the present work was to compare the production of collagenolytic protease in ATPS produced by Mucor subtillissimus UCP 1262 in different types of fermentations.

MATERIALS AND METHODS

Microorganism

The filamentous fungi Mucor subtilissimus UCP 1262 was isolated from the soil of Caatinga (Northeast, Brazil), deposited in the Universidade Católica de Pernambuco (UNICAP). The species used is registered in the Patrimônio Genético Brasileiro n°AA30B0B.

Means of maintenance and sporulation

It was maintained on Czapek medium at 30ºC for 7 days and stored in mineral oil, sterilization of the medium was performed by autoclaving at 121ºC, 1 atm pressure for 20 minutes. For sporulation the microorganism was incubated in BOD (Body Oxygen Demand) at 30ºC for 7 days.

Preparation of inoculums for submerged and solid-state fermentations

For submerged and solid-state fermentations the spores were collected using nutrient solution comprised of 0.5% yeast extract, 1% glucose and 0.01% Tween 80 diluted in sodium phosphate buffer 245 mM and pH 7.0 previously sterilized: The spores were counted in Neubauer chamber to a final concentration of 10⁷ spores/mL for state solid fermentation, but for submerged fermentation was use final concentrated 10⁴ spores/mL.

Production of collagenolytic protease by submerged fermentation (SF)

For production of collagenolytic protease in submerged fermentation was used the MS-2 medium (Porto et al. 1996PORTO ALF, CAMPOS-TAKAKI GM & LIMA-FILHO JL. 1996. Effects of culture conditions on protease production by Streptomyces clavuligerus growing on soy bean flour medium. Appl Biochem Biotech - Part A Enzyme Engineering Biotechnology 60: 115-122.) composed of: 2.0% soybean meal, MgSO₄.7H₂O, 0,1%, NH₄Cl, 0,435%, K₂HPO₄ and 0.1 mL mineral solution (100 mg FeSO₄, 100 mg MnCl₂, 100 mg of ZnSO₄, 100 mg of CaCl₂ H₂O in 100 ml of distilled water, initial pH 7.2). Therefore, a solution containing spores of Mucor subtillissimus UCP 1262 was inoculated in a 125 mL Erlenmeyer flask containing 50 mL of the autoclaving at 121ºC, 1 atm pressure for 20 min. The fermentation was carried out in an orbital shaker at 120 rpm, 30°C, for 72 hours. After the culture period the samples were centrifuged at 3500 rpm for 10 min to separate the biomass and the supernatant obtained was used to determine the enzymatic activities.

Production of collagenolytic protease by solid-state fermentation (SSF)

For production of collagenolytic protease in solid-state fermentation the soybean bran with a granulometry between 0.6 to 2.0 mm was used with 5g and the solution containing spores of Mucor subtillissimus UCP 1262 was inoculated in a 125 ml Erlenmeyer flask and the moisture of 40% at 30˚C for 72 hours for production. Thus, the enzyme extraction was realized with purpose 7.5 mL of 245 mM sodium phosphate buffer, pH 7, were added per g of substrate and the flasks were placed in an orbital shaker at 150 rpm for 90 min at room temperature (Nascimento et al. 2015NASCIMENTO TP, SALES AE, PORTO CS, BRANDÃO RMP, TAKAKI GMC, TEIXEIRA JAC, PORTO TS & PORTO ALF. 2015. Production and Characterization of New Fibrinolytic Protease from Mucor subtillissimus UCP 1262 in Solid-State Fermentation. Adv Enzyme in Res 3: 81-91.).

Preparation of aqueous two-phase systems and extraction of collagenolytic protease

For formation of ATPS was utilized concentrations phosphate buffer (PBS, 40% w/w) in pH 6.0 at room temperature (25 ± 1ºC), was addition PEG solutions (60%, w/w) with different molecular weight (200, 500, 1000) determined for 2³ experimental design de according Table I and transferred 15 ml graduated tubes and were addition 2 g sample. After these addictions were homogenized, stand by until 60 min for separated the phases. The volumes phase was measured, and determination collagenolytic activity and protein concentration were determination of two phases. The extracts of submerged and solid-state fermentations were used for extraction of collagenolytic protease in each 2³ experimental design.

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Table I
Factor levels of the 2³-experimental design used for the extraction of collagenolytic protease from M. subtilissimus UCP 1262 from by PEG/phosphate ATPS.

Sodium dodecyl sulfate-polyacrylamide gel electrophoresis (SDS-PAGE)

Sodium dodecyl sulfate-polyacrylamide gel electrophoresis (SDS-PAGE) was determined by Laemmli (1970)LAEMMLI UK. 1970. Cleavage of structural proteins during the assembly of the headof bacteriophage T4. Nature 227: 680-685.. Protein staining was done by immersing the gel in a solution containing 0.1% Coomassie Blue R-250 and then staining with silver (Fluka Fine Chemical Co., Ltd., Tokyo, Japan). The molecular mass was calibrated using as a standard a molecular mass marker (GE Healthcare 17044601, São Paulo, SP, Brazil) HMW-SDS maker kit, pageruler unstained broad range protein ladder – Thermo Scientific – 26630.

Analytical determinations

Protein determination

Total protein content of samples was determined using Coomassie Brilliant Blue G-250 as a dye and Bovine Serum Albumin as a standard (Bradford 1976BRADFORD MM. 1976. A rapid and sensitive method for the quantitation ofmicrogram quantities of protein utilizing the principle of protein-dye binding. Anal Biochem 72: 248-254.).

Protease activity

Protease activity was measured using 1% azocasein as the substrate for reaction, with 1 unit of enzymatic activity (U) varying from 0.01 at absorbance to 420 nm per 1 hour (Ginther 1979GINTHER CL. 1979. Sporulation and the production of serine protease and cephamycin C by Streptomyces lactamdurans. Antimicrob Agents Chemother 15: 522-526.).

Azocoll assay for collagenolytic enzyme activity determination

The determination of the collagenolytic activity was performed according to the methodology described by Wanderley et al. (2017)WANDERLEY MC, WANDERLEY DUARTE NETO JM, CAMPOS ALBUQUERQUE WW, ARAÚJO-VIANA DM, ALBUQUERQUE CL, CRUZ SILVÉRIO SI, LIMA FILHO JL, COUTO-TEIXEIRA JÁ & PORTO ALF. 2017. Purification and characterization of a collagenase from Penicillium sp. UCP 1286 by polyethylene glycol-phosphate aqueous two-phase system. Protein Expres Purif 133: 8-14. using as substrate Azo dye-impregnated collagen (Azocoll; Sigma Chemical Co., St Louis, MO). The reaction occurred at 37°C for one hour. After this time, each assay was centrifuged and 1mL of the supernatant was removed for spectrophotometer reading at wavelength at 520nm. One unit of enzyme activity (U) was defined as the amount of enzyme, per milliliter, necessary to increase the absorbance by 0.1.

Determination of partition coefficient (K), activity yield (Y), purification factor (PF), Mass balances (MB) for ATPS

The partition coefficient (K) of collagenolytic protease was defined as the ratio of collagenolytic activity, expressed in U/mL, in the top phase (Ca_t) to that in the bottom phase (Ca_b):

K = \frac{C a_{t}}{C a_{b}}

Where: “Ca_t” and “Ca_b” were collagenolytic activities (U/mL) in the top and bottom phases, respectively.

The activity yield (Y) collagenolytic protease in top phase was calculated from the formula below:

Y = \frac{V s . C a t_{t}}{V c e . C a_{c e}} \times 100

Where: “Vs” and “Cat_t” are volume of the top phase and collagenolytic activity (U/mL), respectively. As “Vce” and “Ca_ce” are the initial volume (crude extract) and the initial collagenolytic activity (U/mL) (crude extract) respectively.

The purification factor (PF) was calculated according to this formula:

P F = \frac{C a t / P t}{C a c e / P t c e}

Where: “Cat” and “Pt” are collagenolytic activity (U/mL) and protein concentration (mg/mL) in top phase, respectively. Thus, “Cace” e “Ptce” are collagenolytic activity (U/mL) and protein concentration (mg/mL) in crude extract.

The mass balance (MB) was certificated according to this formula:

M B = \frac{(P t . V t) + (P b . V b)}{P t c e . G c e} \times 100

Where: “Pt” and “Vt” are the protein concentration (mg/mL) and volume top phase respectively. Then, “Pb” and “Vb” are the protein concentration (mg/mL) and volume top phase, respectively. Then, “Pt_ce” and “G_ce” are the protein concentration (mg/mL) and volume of crude extract, respectively. Ultimately, “Pt” is protein concentration (mg/mL) crude extract and quantity in grams of the sample used, respectively.

Statistical analysis

Statistical analysis of results obtained through the factorial experimental design and central composite rotary design were performed using the software Statistical 8.0. In order to compare the means of the effects of inhibitors on protease activity, we used the Student t-test for independent samples. The results were considered statistically significant at p ≤ 0.05.

RESULTS AND DISCUSSION

Collagenolytic protease production by Mucor subtilissimus UCP1262 in Submerged Fermentation (SF) and Solid-State Fermentation (SSF)

The production industrial of enzymes is a process basically carried out by two fermentation system: Submerged fermentation (SF) and Solid-State Fermentation (SSF), whose differences in bioprocess and composition of the medium are determinant in the enzymatic production from microorganism (Silva 2018SILVA RR. 2018. Exploring the Fermentation Technology for Biocatalysts Production. Princ Appl Ferm Technol 5: 181-187.). In present work the collagenolytic protease production from Mucor subtilissimus UCP 1262 was evaluated using these two techniques. The total proteolytic activity of 362.66 U/mL and the collagenolytic activity 179.81 U/mL were higher in the SSF process compared to SF where the production was 26.33 U/mL and 18.70 U/mL for the total proteolytic activity and collagenolytic activity, respectively.

Around the 90% of the industrial enzymes production use the SF technique and most of the microbial collagenases reported have been produced from these process (Pal & Suresh 2016PAL GK & SURESH PV. 2016. Microbial collagenases: challenges and prospects in production and potential applications in food and nutrition. RSC Advances 6(40): 33763-33780.). SF is the mostly utilized because it provides advantages such as used a bioreactor equipped with techniques for monitoring and control (Dasari et al. 2019DASARI PR, RAMTEKE PW, KESRI S & KONGALA PR. 2019. Comparative Study of Cellulase Production Using Submerged and Solid- State Fermentation. Approaches to Enhanc Ind Prod Fungal Cell, p. 37-52.). However, the byproducts are diluted and enzyme extracts may be less stable when compared to solid-state fermentation (Gimenes et al. 2019GIMENES NC, SILVEIRA E & TAMBOURGI EB. 2019. An Overview of Proteases: Production, Downstream Processes and Industrial Applications. Sep Purif Rev 1: 1-21.). Viniegra-González & Favela-Torres (2006)VINIEGRA-GONZÁLEZ G & FAVELA-TORRES E. 2006. Why solid-state fermentation seems to be resistant to catabolite repression? Food Technol Biotechnol 44: 397-406. explain that the low enzymatic production in SF process may be related to important catabolite repression phenomenon. According to these authors, this phenomenon is the inhibition of the microbial synthesis of many enzymes that require a chemical signal, called the inducer, and are repressed when there is abundance of a ready fermentable substrate such as glucose, glycerol or other carbon sources.

A viable alternative is the SSF technique, since that, several authors related the increase in enzyme production using this bioprocess (Bhavsar et al. 2013BHAVSAR K, BUDDHIWANT P, SONI SK, DEPAN D, SARKAR S & KHIRE JM. 2013. Phytase isozymes from Aspergillus niger NCIM 563 under solid state fermentation: Biochemical characterization and their correlation with submerged phytases. Process Biochem 48: 1618-1625., Mazotto et al. 2013MAZOTTO AM, COURI S, DAMASO MCT & VERMELHO AB. 2013. Degradation of feather waste by Aspergillus niger keratinases: Comparison of submerged and solid-state fermentation. Int Biodeter Biodegr 85: 189-195.). Moreover, this type of fermentation is indicated for filamentous fungi because the cultivation conditions are similar to their natural habitat; the concentration of the products after extraction is much higher when compared to submerged fermentation and generates less liquid residue, being this process economically interesting mainly in regions with abundant agro-industrial waste (Soccol et al. 2017SOCCOL CR, COSTA ESF, LETTI LAJ, KARP SG, WOICIECHOWSKI AL & VANDENBERGHE LPS. 2017. Recent developments and innovations in solid state fermentation. Biotechnol Res and Innovation 1: 1-12.).

The total protein content found in the SSF enzymatic extract was 1800.22 mg/mL, which is higher than that obtained in SF with 344.01 mg/mL. SSF process the microorganism has greater difficulty in degrading the substrate to get nutrients, as compared to the aqueous medium (SF), where the nutrients concentration is more accessible. Thus, the microorganism was induced to increase the production of proteins (enzymes) to degrade the substrate. Several studies show a higher concentration of secreted proteins in the solid medium than in the liquid medium; and the morphology and chemical composition of the substrate used in fermentation process are very important for enzyme production (Mazotto et al. 2013MAZOTTO AM, COURI S, DAMASO MCT & VERMELHO AB. 2013. Degradation of feather waste by Aspergillus niger keratinases: Comparison of submerged and solid-state fermentation. Int Biodeter Biodegr 85: 189-195., Shivanna & Venkateswaran 2014SHIVANNA GB & VENKATESWARAN G. 2014. Phytase production by Aspergillus niger CFR 335 and Aspergillus ficuum SGA 01 through submerged and solid-state fermentation. Sci World J 1: 1-6.).

Regarding the protein profile in both types of fermentations (Figure 1) the protein profile of SSF is more complex, as it has more differentiated bands, while in SF the protein diversity is lower. Similary with the results of Oda et al. (2006)ODA K, KAKIZONO D, YAMADA O, IEFUJI H, AKITA O & IWASHITA K. 2006. Proteomic Analysis of Extracellular Proteins from. Appl Enviromen Microbiol 72: 3448-3457. who compared the amount of protein secreted in the two cultivation forms, using wheat bran as a carbon source, the study reports that solid state growth resulted in four to six times more secreted protein compared to submerged culture, resulting in a more complex protein profile. In present work the proteolytic activity obtained from SSF had a 13.7-fold increase compared to SF. Likewise, the results obtained in the present study, was reported Aspergillus oryzae protease production in submerged and solid-state fermentation and observed a 3.5-fold increase in the amount of enzyme produced in solid state using wheat bran as substrate (Sandhya et al. 2006SANDHYA C, SUMANTHA A, SZAKACS G & PANDEY A. 2006. Comparative evaluation of neutral protease production by Aspergillus oryzae in submerged and solid-state fermentation. Process Biochem 40: 2689-2694.). Corroborating with the results, Belmessikh et al. (2013)BELMESSIKH A, BOUKHALFA H, MECHAKRA-MAZA A, GHERIBI-AOULMI Z & AMRANE A. 2013. Statistical optimization of culture medium for neutral protease production by Aspergillus oryzae. Comparative study between solid and submerged fermentations on tomato pomace. J Taiwan Inst of Chem Eng 44: 377-385. in the work realized a comparison of the neutral protease production from the cultivation of Aspergillus oryzae in solid-state fermentation (SSF) and submerged fermentation (SF) using tomato pomace based medium, and reported a ratio of 9 between SSF and SF, showing the efficiency of the solid-state fermentation compared to the submerged fermentation, the nature of fermentation, submerged or solid state, influences various aspects of microorganism growth as well as enzyme production.

Figure 1
Comparison of the protein profile obtained by Mucor subtilissimus UCP 1262 in submerged (SF) and solid state (SSF) fermentation on silver nitrate stained SDS-PAGE (12%) with protein molecular mass marker (High ranger RN756E, GE Healthcare Life Sciences).

Though, the use of this fermentation technique presents challenges to be overcome such as insufﬁcient nutrient employment due to heat transfer in substrates and the low quantity of oxygen. Moreover, the challenges of scale-up, puriﬁcation of the bioproduct and biomass estimation are drawbacks of the technique that have encouraged researchers to search for better solutions (Gimenes et al. 2019GIMENES NC, SILVEIRA E & TAMBOURGI EB. 2019. An Overview of Proteases: Production, Downstream Processes and Industrial Applications. Sep Purif Rev 1: 1-21.).

Comparative extraction of collagenolytic protease from submerged fermentation (SF) and solid-state fermentation (SSF) using aqueous two-phase system

The experimental results of extraction of collagenolytic protease produced for Mucor subtilissimus UCP 1262 in SF and SSF was analyzed according to factorial design with two levels and three variables. The statistical influence was determined within 95% of confidence. The results for the response variables, partition coefficient (K), puriﬁcation factor (PF) and activity yield (Y) are summarized in Table II and Table III for collagenolytic enzyme extraction obtained by SF and SSF, respectively.

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Table II
Results of 2³-experimental design for collagenolytic protease extraction from M. subtilissimus UCP 1262 in submerged fermentation (SF) using PEG/phosphate ATPS.

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Table III
Results of 2³-experimental design collagenolytic protease extraction from Mucor subtilissimus UCP 1262 in solid-state fermentation (SFF) using PEG/phosphate ATPS.

The collagenolytic protease produced by SF and SSF partitioned preferentially for the polymeric phase (partition coefficient K > 1). According to Table IV the independents variables C_PEG and M_PEG showed significant influence under partition of collagenolytic protease obtained by SF and SSF too. The influence of C_PEG had the negative effect, the polymer concentration decrease favored the partition of the enzyme for this phase. Because the volume occupied by the polymer increases with the polymer concentration and which results in reduced space for biomolecules in the top phase (Porto et al. 2008PORTO TS, MEDEIROS E SILVA GM, PORTO CS, CAVALCANTI MTH, NETO BB, LIMA-FILHO JL, CONVERTI A, PORTO ALF & JR-PESSOA A. 2008. Liquid-Liquid Extraction of Proteases from Fermented Broth by PEG/Citrate Aqueous Two-Phase System. Chem Eng Process 47: 716-721.). On the contrary, M_PEG was positively significant for K, runs composed with higher molar mass of the polymer (1.000 g/mol) favored the enzyme partition to the upper phase. Is commonly reported that in biphasic systems formed by polymers and salts, when the polymer has a high molar mass, which is caused by the molecule size, can lead to the volume exclusion effect, when the biomolecule tends to migrate to a salt-rich phase where there is more space (Siqueira et al. 2020SIQUEIRA JGW, TORRES TMS, ALVES BMV, PORTO ALF & PORTO TS. 2020. Extraction of protease from Aspergillus tamarii URM 4634 in aqueous two-phase system under continuous and discontinuous process. Prep Biochem Biotechnol 50(6): 1-8.). In the present work or opposite behavior was observed once as microbial collagenases are generally small, with molecular weight ranging from 28 kDa to 116 kDa (Jucá et al. 2008JUCÁ M, NUNES BLBBP, MENEZES HL, GOMES EGA & MATOS D. 2008. Metalloproteinases 1 and 7 and colorectal cancer. Rev Bras Coloproctol 28: 353-362.), and indicating high affinity enzymatic for the PEG-rich phase.

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Table IV
Statistical effects calculated for the responses of collagenolytic protease from Mucor subtilissimus UCP 1262 in submerged and solid-state fermentation using PEG/phosphate ATPS performed according to the 2³ -experimental design.

The interaction of independents variables C_PEG-C_SALT (2*3) exerted significant linear positive effect (Table IV) on partition of collagenolytic protease from SSF, meaning that the simultaneous increase or decrease of PEG concentration (C_PEG) values and phosphate concentrations (C_SALT), the higher the values K values. This effect was observed in the present study, where the lowest concentration of PEG 17,5% in combination with the lowest phosphate concentration 15% (w/w) were the conditions that favored the partition of collagenolytic protease to the PEG rich phase. Low PEG concentration values associated with low phosphate concentrations favored the partition of the molecule to the upper phase, increasing the partition coefficient.

This effect was observed in the present study, where the run compound whit lowest concentration of PEG 17,5% (w/w) in combination with the lowest phosphate concentration 15% (w/w) was the conditions that favored the partition of collagenolytic protease to the upper phase, increasing the partition coefficient (K=3.45).

ATPS has great versatility in separating complex mixtures due to the large number of variables that interfere with the target molecule partition. Through the systematic manipulation of extrinsic variables, the behavior of the protein of interest and its contaminants can be modified (Tubío et al. 2007TUBÍO G, NERLI B & PICÓ G. 2007. Partitioning features of bovine trypsin and α-chymotrypsin in polyethyleneglycol-sodium citrate aqueous two-phase systems. J Chromatog B Anali Technol Biomed Life Sci 852: 244-249.). However, with this wide range of variables, and most of them being interdependent, the theoretical understanding of the behavior of the molecule of interest in ATPS becomes exceedingly difficult. As a result, the conclusions regarding collagenolytic protease partition presented in this study were based on the physicochemical characteristics of the system components and the chemical structure of the target molecule.

The partition of the enzyme produced in SF and SSF to the PEG rich phase may be justified by the hydrophobic interaction between PEG and collagenolytic protease. In this respect, it is possible to infer that such interaction occurs due to the presence of hydrophobic domains in collagenase, as well as in chitinases, cellulases and xylanases (Bockle et al. 1995BOCKLE B, GALUNSKY B & MULLER R. 1995. Characterization of a keratinolytic serine proteinase from Streptomyces pactum DSM 40530. Appl Environ Microbiol 61: 3705-3710.). The hydrophobic domains present in microbial collagenases, as well as in all metalloproteases, are formed by the methionine residues contained in these enzymes that are responsible for such hydrophobic bases (Bode et al. 1993BODE W, GOMIS-RÜTH FX & STÖCKLER W. 1993. Astacins, serralysins, snake venom and matrix metalloproteinases exhibit identical zinc-binding environments (HEXXHXXGXXH and Met-turn) and topologies and should be grouped into a common family, the “metzincins.” FEBS Letters 331: 134-140.). In addition, PEG has high hydrophobicity due to its long carbon chains and is a neutral molecule (Pereira & Coutinho 2019PEREIRA JFB & COUTINHO JAP. 2019. Aqueous two-phase systems. Liq Extr, p. 157-182.). Thus, the hydrophobic domains of collagenase interacted with the hydrophobic PEG chains allowing, through hydrophobic forces, the migration of the enzyme of interest to the upper part of the biphasic system.

The activity yield (Y) values of collagenolytic protease from SF and SSF obtained were: 198.65% and 291.94% respectively (Table II and III). Other authors using biphasic system for enzyme extraction also reported yield values above 100%, this fact can be explained by the possible decrease of the enzyme inhibitors of interest during the extraction process (Oliveira et al. 2020OLIVEIRA VM, CARNEIRO DA CUNHA MN, ASSIS CRD, BATISTA JMS, NASCIMENTO TP, SANTOS JF, LIMA CDA, VIANA-MARQUES DA, BEZERRA RSP & PORTO ALF. 2020. Separation and partial purification of collagenolytic protease from peacock bass (Cichla ocellaris) using different protocol: Precipitation and partitioning approaches. Biocatal Agric Biotechnol 24: 105509.) or the PEG phase may have promoted greater stability to the target enzyme. This behavior was also observed extracting tannase from Aspergillus tamarii where the highest activity yield, they observed was 160.4% Sena et al. (2017)SENA AR, BARROS-OLIVEIRA FM, CAMPOS-LEITE TC, NASCIMENTO ESTC, MOREIRA KA & ASSIS AS. 2017. Application of aqueous biphasic systems as strategy to purify tannase from Aspergillus tamarii URM 7115. Prep Biochem Biotechnol 21: 945-951. Oliveira et al. (2020)OLIVEIRA VM, CARNEIRO DA CUNHA MN, ASSIS CRD, BATISTA JMS, NASCIMENTO TP, SANTOS JF, LIMA CDA, VIANA-MARQUES DA, BEZERRA RSP & PORTO ALF. 2020. Separation and partial purification of collagenolytic protease from peacock bass (Cichla ocellaris) using different protocol: Precipitation and partitioning approaches. Biocatal Agric Biotechnol 24: 105509. and Wanderley et al. (2017)WANDERLEY MC, WANDERLEY DUARTE NETO JM, CAMPOS ALBUQUERQUE WW, ARAÚJO-VIANA DM, ALBUQUERQUE CL, CRUZ SILVÉRIO SI, LIMA FILHO JL, COUTO-TEIXEIRA JÁ & PORTO ALF. 2017. Purification and characterization of a collagenase from Penicillium sp. UCP 1286 by polyethylene glycol-phosphate aqueous two-phase system. Protein Expres Purif 133: 8-14. using PEG/phosphate ATPS to extract collagenolytic enzyme from peacock bass (Cichla ocellaris) and Chlorella vulgaris, reached yields of 116% and 244.0%, respectively. Values of activity yield that match those obtained in the present work.

The independent variables C_PEG and M_PEG were statistically significant on the activity yield (Y) of collagenolytic protease from SF. C_PEG showed a negative effect and M_PEG was a positive effect under for this response, in the runs 2 and 6 formed with lower concentrations and higher molar mass of the polymer, higher yield activities were obtained (Table II). Considering the results of activity yield obtained for the extraction of collagenolytic protease from SSF (Table III), all independent variables and their interactions were statistically significant on this variable response, the negative effect of the polymer concentration (C_PEG) stands out (Table IV). According to Grilo et al. (2016)GRILO AL, AIRES-BARROS MR & AZEVEDO AM. 2016. Partitioning in Aqueous Two-Phase Systems: Fundamentals, Applications and Trends. Sep Purif Rev 45: 68-80. the relationship between concentration and molecular weight of polymers is an important parameter in extract enzyme ATPS. This author reports that in biphasic system using PEG polymers, as the molecular weight decrease at a constant concentration of polymer, there will be less ethylene oxide groups per PEG molecule, and consequently the PEG-rich phase will be less hydrophobic. In contrast, obviously an increase in the molecular weight of polymer increases hydrophobicity by reducing the hydrophilic groups/hydrophobic area (Iqbal et al. 2016IQBAL M ET AL. 2016. Aqueous two-phase system (ATPS): an overview and advances in its applications. Biol Proced Online 18: 1-18.). As well as the previously discussed, in present study a hydrophobic interaction between PEG and collagenolytic protease occurred.

The highest purification factor (PF) values for collagenolytic protease produced in SSF (PF =3.495) when compared with PF values obtained in extraction of enzyme produced by in SF (PF =2.389). However, the production of collagenolytic proteases in SSF was 9.6 x greater than the production of the same enzyme using SF (described in section “Collagenolytic protease production by Mucor subtilissimus UCP1262 in Submerged Fermentation (SF) and Solid-State Fermentation (SSF)”). In solid-state fermentation at a concentration of amino acids, proteins and even larger pigments when compared to submerged fermentation and this can make the purification step more costly and, in many cases, not interesting in industrial terms (Hölker et al. 2004HÖLKER U, HÖFER M & LENZ J. 2004. Biotechnological advantages of laboratory-scale solid-state fermentation with fungi. Appl Microbiol Biotechnol 64(2): 175-186. doi: 10.1007/s00253-003-1504-3.). Because this, considered that the enzymatic purification of the crude extract from the SSF was more effective.

Relative low purification factor obtained in the extraction of the enzyme produced by SSF may be related to the complex protein pattern (Figure 1) present in the crude extract obtained in this bioprocess. Result that corroborates with the obtained by Silva et al. (2017)SILVA OS, GOMES MHG, OLIVEIRA RL, PORTO ALF, CONVERTI A & PORTO TS. 2017. Partitioning and extraction protease from Aspergillus tamarii URM 4634 using PEG-citrate aqueous two-phase systems. Biocatal Agric Biotechnol 9: 168-173. and Amaral et al. (2020)AMARAL YMS, DA SILVA OS, DE OLIVEIRA RL & PORTO TS. 2020. Production, extraction, and thermodynamics protease partitioning from Aspergillus tamarii Kita UCP 1279 using PEG/sodium citrate aqueous two-phase systems. Prep Biochem Biotechnol 50(6): 619-626. when evaluated extraction the protease produced in SSF by Aspergillus tamarii URM 4634 and Aspergillus tamarii Kita UCP 1279 using PEG-citrate aqueous two-phase system and reported puriﬁcation factor values that 3.95 and 1.6, respectively. For the collagenolytic protease from SSF the most signiﬁcant effect on PF was the positive effect one of M_PEG and was also negatively inﬂuenced by the interaction between M_PEG and C_SALT (1*3). The optimal conditions for this response were those adopted in run 4 (Figure 2) composed by 22% (w/w) PEG 1000 g/mol and 15% phosphate salts (w/w).

Figure 2
Simultaneous effects of concentrations PEG (C_PEG, %) and phosphate concentration (C_SALT, % w/w) on the purification factor (PF) the collagenolytic protease of solid-state fermentation in the top phase (PEG) ATPS.

Already in SF, biomolecules are produced in smaller quantities and the extremely aqueous culture medium favors the dilution of enzymes and consequently on its inhibitors. Stoykov et al. (2015)STOYKOV YM, PAVLOV AI & KRASTANOV AI. 2015. Review - Chitinase biotechnology: Production, puriﬁcation, and application. Eng Life Sci 15: 30-38. observed that chitinase purification in SF is generally more complex because purification steps require large volumes of metabolic liquids due to the low enzymatic concentration. That said, ATPS techniques is an attractive for the steps downstream of enzymes SSF produced. Since is recovery tool that integrates clarification, concentration and partial purification of the target molecule in a single operation (Nadar et al. 2017NADAR SS, PAWAR RG & RATHOD VK. 2017. Recent advances in enzyme extraction strategies: A comprehensive review. Int J Biol Macromol 101: 931-957., Phong et al. 2018PHONG WN, SHOW PL, CHOW YH & LING TC. 2018. Recovery of biotechnological products using aqueous two phase systems. J Biosci Bioeng 16: 273-281., Siqueira et al. 2020SIQUEIRA JGW, TORRES TMS, ALVES BMV, PORTO ALF & PORTO TS. 2020. Extraction of protease from Aspergillus tamarii URM 4634 in aqueous two-phase system under continuous and discontinuous process. Prep Biochem Biotechnol 50(6): 1-8.). The ATPS showed the highest value for PF in the conditions of the run 6 (Figure 3) M_PEG 1000 g/mol, C_PEG 17.5% (w/w), C_SALT 20% (w/w) from the collagenolytic protease produced by SF. After the results statistical analysis, it was observed that the main effects of variables were the C_SALT positive effect and C_PEG negative effect, as well as, an interaction of these variables has negatively significant effect under PF of the collagenolytic protease produced by SF. This means that the variables exerted an antagonist effect, whereby of the PF increase was observed in the tests formed by a higher phosphate concentration and lower PEG concentration. Wanderley et al. (2017)WANDERLEY MC, WANDERLEY DUARTE NETO JM, CAMPOS ALBUQUERQUE WW, ARAÚJO-VIANA DM, ALBUQUERQUE CL, CRUZ SILVÉRIO SI, LIMA FILHO JL, COUTO-TEIXEIRA JÁ & PORTO ALF. 2017. Purification and characterization of a collagenase from Penicillium sp. UCP 1286 by polyethylene glycol-phosphate aqueous two-phase system. Protein Expres Purif 133: 8-14. reported the effect of salt on the partitioning coefficient of collagenolytic enzyme produced by microalgae Chlorella vulgaris was positive meaning that high phosphate concentration makes collagenolytic enzyme migrate to the PEG rich phase. Several authors explain that a higher concentration of salt leads to a decrease in protein solubility in the salt-rich bottom phase, resulting in the migration of the protein and, hence, partition directly to polymer-rich upper phase, the interaction occurs between salt ions and oppositely charged protein groups, creating a double layer of ionic groups, this phenomenon is the salting out effect (Gimenes et al. 2019GIMENES NC, SILVEIRA E & TAMBOURGI EB. 2019. An Overview of Proteases: Production, Downstream Processes and Industrial Applications. Sep Purif Rev 1: 1-21., Goja et al. 2013GOJA AM, YANG H, CUI M & LI C. 2013. Aqueous Two-Phase Extraction Advances for Bioseparation. J Bioproc Biotech 4: 1-8., Grilo et al. 2016GRILO AL, AIRES-BARROS MR & AZEVEDO AM. 2016. Partitioning in Aqueous Two-Phase Systems: Fundamentals, Applications and Trends. Sep Purif Rev 45: 68-80.).

Figure 3
Simultaneous effects of PEG (C_PEG, %) and phosphate concentration (C_SALT, % w/w) on the purification factor (PF) the collagenolytic protease of submerged fermentation in the top phase (PEG) ATPS.

CONCLUSIONS

A collagenolytic protease with potential pharmaceutical application was successfully produced by Mucor subtilissimus UCP 1262. The results obtained in this study showed that SSF is a promising method of cultivation in obtaining of this type of biomolecule. The collagenase produced in both fermentative processes (SSF and SF) were partial purified by aqueous two phases systems PEG/phosphate. In ATPS were obtained recovery values higher than 100% and high purification factors, thus ATPS was a viable tool for the extraction of the enzyme, in addition, it is a process that can be used in large scale, constituted by components of low cost, and the conditions used in the PEG/phosphate favored the extraction of these enzymes, becoming an alternative raw material source for the global protease market.

ACKNOWLEDGMENTS

This study was financed in part by the Coordenação de Aperfeiçoamento de Pessoal de Nível Superior, Brazil (CAPES, Finance Code 8888.119817/2016-01); by Conselho Nacional de Desenvolvimento Científico e Tecnológico, Brazil (CNPq, Finance Code 155634/2018-6 PDJ), and Fundação de Ciência e Tecnologia do Estado de Pernambuco, Brazil (FACEPE, Finance Code BFP-0158-5.01/19, BFP-0079-5.05/20, BFP-0087-5.05/20).

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Publication Dates

Publication in this collection
08 July 2022
Date of issue
2022

History

Received
10 Sept 2020
Accepted
9 Dec 2020

This is an open-access article distributed under the terms of the Creative Commons Attribution License

[1] ALIPOUR H, RAZ A, ZAKERI S & DINPARAST DN. 2016. Therapeutic applications of collagenase (metalloproteases): A review. Asian Pac J Trop Biomed 6: 975-981.

[2] AMARAL YMS, DA SILVA OS, DE OLIVEIRA RL & PORTO TS. 2020. Production, extraction, and thermodynamics protease partitioning from Aspergillus tamarii Kita UCP 1279 using PEG/sodium citrate aqueous two-phase systems. Prep Biochem Biotechnol 50(6): 619-626.

[3] BELMESSIKH A, BOUKHALFA H, MECHAKRA-MAZA A, GHERIBI-AOULMI Z & AMRANE A. 2013. Statistical optimization of culture medium for neutral protease production by Aspergillus oryzae. Comparative study between solid and submerged fermentations on tomato pomace. J Taiwan Inst of Chem Eng 44: 377-385.

[4] BHAGWAT PK & DANDGE PB. 2018. Collagen and collagenolytic proteases: A review. Biocatal Agric Biotechnol 15: 43-55.

[5] BHAVSAR K, BUDDHIWANT P, SONI SK, DEPAN D, SARKAR S & KHIRE JM. 2013. Phytase isozymes from Aspergillus niger NCIM 563 under solid state fermentation: Biochemical characterization and their correlation with submerged phytases. Process Biochem 48: 1618-1625.

[6] BOCKLE B, GALUNSKY B & MULLER R. 1995. Characterization of a keratinolytic serine proteinase from Streptomyces pactum DSM 40530. Appl Environ Microbiol 61: 3705-3710.

[7] BODE W, GOMIS-RÜTH FX & STÖCKLER W. 1993. Astacins, serralysins, snake venom and matrix metalloproteinases exhibit identical zinc-binding environments (HEXXHXXGXXH and Met-turn) and topologies and should be grouped into a common family, the “metzincins.” FEBS Letters 331: 134-140.

[8] BRADFORD MM. 1976. A rapid and sensitive method for the quantitation ofmicrogram quantities of protein utilizing the principle of protein-dye binding. Anal Biochem 72: 248-254.

[9] DASARI PR, RAMTEKE PW, KESRI S & KONGALA PR. 2019. Comparative Study of Cellulase Production Using Submerged and Solid- State Fermentation. Approaches to Enhanc Ind Prod Fungal Cell, p. 37-52.

[10] FERREIRA JF, PADILHA GS & TAMBOURGI EB. 2009. Efeitos da massa molar e do pH sobre o equilíbrio termodinâmico do sistema bifásico aquoso PEG/fosfatos. Exacta - Engenharia de Produção 7: 49-56.

[11] GIMENES NC, SILVEIRA E & TAMBOURGI EB. 2019. An Overview of Proteases: Production, Downstream Processes and Industrial Applications. Sep Purif Rev 1: 1-21.

[12] GINTHER CL. 1979. Sporulation and the production of serine protease and cephamycin C by Streptomyces lactamdurans. Antimicrob Agents Chemother 15: 522-526.

[13] GOJA AM, YANG H, CUI M & LI C. 2013. Aqueous Two-Phase Extraction Advances for Bioseparation. J Bioproc Biotech 4: 1-8.

[14] GRILO AL, AIRES-BARROS MR & AZEVEDO AM. 2016. Partitioning in Aqueous Two-Phase Systems: Fundamentals, Applications and Trends. Sep Purif Rev 45: 68-80.

[15] GURUMALLESH P, ALAGU K, RAMAKRISHNAN B & MUTHUSAMY S. 2019. A systematic reconsideration on proteases. Int J Biol Macromol 128: 254-267.

[16] HÖLKER U, HÖFER M & LENZ J. 2004. Biotechnological advantages of laboratory-scale solid-state fermentation with fungi. Appl Microbiol Biotechnol 64(2): 175-186. doi: 10.1007/s00253-003-1504-3.

[17] IQBAL M ET AL. 2016. Aqueous two-phase system (ATPS): an overview and advances in its applications. Biol Proced Online 18: 1-18.

[18] JUCÁ M, NUNES BLBBP, MENEZES HL, GOMES EGA & MATOS D. 2008. Metalloproteinases 1 and 7 and colorectal cancer. Rev Bras Coloproctol 28: 353-362.

[19] LAEMMLI UK. 1970. Cleavage of structural proteins during the assembly of the headof bacteriophage T4. Nature 227: 680-685.

[20] LIMA CA, JÚNIOR ACVF, FILHO JLL, CONVERTI A, MARQUES DAV, CARNEIRO-DA-CUNHA MG & PORTO ALF. 2013. Two-phase partitioning and partial characterization of a collagenase from Penicillium aurantiogriseum URM 4622: Application to collagen hydrolysis. Biochem Eng J 75: 64-71.

[21] MAZOTTO AM, COURI S, DAMASO MCT & VERMELHO AB. 2013. Degradation of feather waste by Aspergillus niger keratinases: Comparison of submerged and solid-state fermentation. Int Biodeter Biodegr 85: 189-195.

[22] NADAR SS, PAWAR RG & RATHOD VK. 2017. Recent advances in enzyme extraction strategies: A comprehensive review. Int J Biol Macromol 101: 931-957.

[23] NAINEGALI BS, IYYASWAMI RD & BELUR P. 2020. Partitioning of bio-active compounds from rinds of garcinia indica using aqueous two-phase system: Process evaluation and optimization. Sep Purif Technol 253: 117520.

[24] NASCIMENTO TP, SALES AE, PORTO CS, BRANDÃO RMP, TAKAKI GMC, TEIXEIRA JAC, PORTO TS & PORTO ALF. 2015. Production and Characterization of New Fibrinolytic Protease from Mucor subtillissimus UCP 1262 in Solid-State Fermentation. Adv Enzyme in Res 3: 81-91.

[25] ODA K, KAKIZONO D, YAMADA O, IEFUJI H, AKITA O & IWASHITA K. 2006. Proteomic Analysis of Extracellular Proteins from. Appl Enviromen Microbiol 72: 3448-3457.

[26] OLIVEIRA VM, CARNEIRO DA CUNHA MN, ASSIS CRD, BATISTA JMS, NASCIMENTO TP, SANTOS JF, LIMA CDA, VIANA-MARQUES DA, BEZERRA RSP & PORTO ALF. 2020. Separation and partial purification of collagenolytic protease from peacock bass (Cichla ocellaris) using different protocol: Precipitation and partitioning approaches. Biocatal Agric Biotechnol 24: 105509.

[27] OLIVEIRA VM, NERI RCA, MONTE FTD, ROBERTO NA, COSTA HMS, ASSIS CRD, SANTOS JF, BEZERRA RS & PORTO ALF. 2019. Crosslink-free collagen from Cichla ocellaris: Structural characterization by FT-IR spectroscopy and densitometric evaluation. J Molecule Struct 1176: 751-758.

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VARIABLE		LEVEL
VARIABLE	Low (-1)	Central (0)	High (+1)
M_PEG (g/mol) ^a C_PEG (% w/w) ^b C_SALT % (w/w) ^c	200 17.5 15.0	550 20.0 17.5	1000 22.5 20.0

Runs	M_PEG	C_PEG (%)	C_SALT (%)	CA_PEG (U/mL)	CA_SALT (U/mL)	K	Y (%)	PF	MB
1	200	17.5	15	12.0	4.13	2.903	175.14	1.106	106.432
2	1000	17.5	15	1.3	4.53	3.000	194.11	1.323	91.938
3	200	22	15	13.3	4.43	0.287	123.00	0.818	99.032
4	1000	22	15	10.9	4.33	2.515	147.3	1.415	90.978
5	200	17.5	20	14.0	4.67	3.000	174.05	2.174	135.365
6	1000	17.5	20	8.4	4.57	3.000	198.65	2.389	104.727
7	200	22	20	14.7	4.90	1.839	81.73	1.333	127.697
8	1000	22	20	13.7	4.83	2.834	162.92	1.441	101.601
9_cp	500	20	17.5	13.4	7.00	1.914	159.35	1.544	92.171
10_cp	500	20	17.5	13.2	6.97	1.895	156.97	1.508	112.664
11_cp	500	20	17.5	8.8	6.77	1.300	109.41	1.280	89.708
12_cp	500	20	17.5	11.0	6.93	1.587	124.86	1.551	85.405

Runs	M_PEG	C_PEG (%)	C_SALT (%)	CA_PEG (U/mL)	CA_SALT (U/mL)	K	Y (%)	PF	MB
1	200	17,5	15	27.6	16.6	1.66	125.64	0.557	96.49
2	1000	17,5	15	32.4	25.8	1.25	116.06	0.406	139.77
3	200	22	15	65.2	18.9	3.45	291.94	1.925	83.84
4	1000	22	15	34.8	25.7	1.35	96.09	3.495	103.10
5	200	17,5	20	37.5	25.2	1.48	123.13	1.409	92.06
6	1000	17,5	20	29.6	16.6	1.78	97.19	0.500	96.16
7	200	22	20	25.1	16.9	1.48	93.66	0.775	80.38
8	1000	22	20	29.1	16.2	1.79	69.49	1.516	86.57
9_cp	500	20	17,5	40.3	25.1	1.60	132.33	1.860	85.65
10_cp	500	20	17,5	50.1	26.2	1.91	134.60	2.348	110.61
11_cp	500	20	17,5	47.5	26.7	1.77	127.61	2.176	103.24
12_cp	500	20	17,5	40.0	25.5	1.56	131.34	1.779	90.45

Variable or Interaction	Submerged fermentation			Solid-state fermentation
Variable or Interaction	K^a	Y^b _PEG	PF^c	K^a	Y^b _PEG	PF^c
M_PEG ^d	-5.3833*	-4.8668*	3.1270*	4.2018*	10.8222	6.4074*
C_PEG ^e	4.0375*	3.7435*	-5.4592*	4.2002*	-31.0174*	1.6564
C_SALT ^f	3.8022*	1.2756	7.3568*	-2.5914	-29.8910*	-2.8905
*M_PEGC_PEG**	2.3936	2.4877	0.7508	-3.7063*	-22.3946*	4.4636*
*M_PEGC_SALT**	2.1583	1.1759	-1.3504	6.8878*	-24.7008*	-5.3958*
*C_PEGC_SALT**	-1.6176	-0.6944	-4.3811*	4.1546*	18.8527*	-2.8905
*M_PEGC_PEGC_SALT*	-1.3822	-0.8565	-1.3394	3.7775*	22.8242	-0.0940

Brasil

Brasil

A novel collagenolytic protease from Mucor subtilissimus UCP 1262: Comparative analysis of production and extraction in submerged and stated-solid fermentation

Abstract

INTRODUCTION

MATERIALS AND METHODS

Microorganism

Means of maintenance and sporulation

Preparation of inoculums for submerged and solid-state fermentations

Production of collagenolytic protease by submerged fermentation (SF)

Production of collagenolytic protease by solid-state fermentation (SSF)

Preparation of aqueous two-phase systems and extraction of collagenolytic protease

Sodium dodecyl sulfate-polyacrylamide gel electrophoresis (SDS-PAGE)

Analytical determinations

Protein determination

Protease activity

Azocoll assay for collagenolytic enzyme activity determination

Determination of partition coefficient (K), activity yield (Y), purification factor (PF), Mass balances (MB) for ATPS

Statistical analysis

RESULTS AND DISCUSSION

Collagenolytic protease production by Mucor subtilissimus UCP1262 in Submerged Fermentation (SF) and Solid-State Fermentation (SSF)

Comparative extraction of collagenolytic protease from submerged fermentation (SF) and solid-state fermentation (SSF) using aqueous two-phase system

CONCLUSIONS

ACKNOWLEDGMENTS

REFERENCES

Publication Dates

History