Abstract
This work focuses on the adsorption of Bromelain in expanded bed conditions, such as the adsorption kinetics parameters. The adsorption kinetics parameters showed that after 40 minutes equilibrium was achieved and maximum adsorption capacity was 6.11 U per resin mL. However, the maximum adsorption capacity was only determined by measuring the adsorption isotherm. Only by the Langmuir model the maximum adsorption capacity, Qm, and dissociation constant, kd, values could be estimated as 9.18 U/mL and 0.591, respectively, at 25 ºC and 0.1 mol/L phosphate buffer pH 7.5. A column made of glass with an inner diameter of 1 cm was used for the expanded bed adsorption (EBA). The residence time was reduced 10 fold by increasing the expansion degree 2.5 times; nonetheless, the plate number (N) value was reduced only 2 fold. After adsorption, the bromelain was eluted in packed bed mode, with a downward flow. The purification factor was about 13 fold and the total protein was reduced 4 fold. EBA showed to be feasible for purification of bromelain.
Adsorption; Enzyme Activity; Purification; Axial Dispersion; Expanded Bed Adsorption; Bromelain
THERMODYNAMICS AND SEPARATION PROCESSES
Expanded bed adsorption of bromelain (E.C. 3.4.22.33) from Ananas comosus crude extract
E. SilveiraI; M. E. Souza-JrII; J. C. C. SantanaI; A. C. ChavesII; A. L. F. PortoIII; E. B TambourgiI,* * To whom correspondence should be addressed
ISchool of Chemical Engineering, State University of Campinas, UNICAMP, P. O. Box 6066, 13083-970, Campinas-SP, Brazil. E-mail: eliastam@feq.unicamp.br
IILaboratório de Biotecnologia, FFPNM/UPE
IIIDepartamento de Morfologia e Fisiologia Animal, UFRPE; Fax: +(55) (19) 3521-3910
ABSTRACT
This work focuses on the adsorption of Bromelain in expanded bed conditions, such as the adsorption kinetics parameters. The adsorption kinetics parameters showed that after 40 minutes equilibrium was achieved and maximum adsorption capacity was 6.11 U per resin mL. However, the maximum adsorption capacity was only determined by measuring the adsorption isotherm. Only by the Langmuir model the maximum adsorption capacity, Qm, and dissociation constant, kd, values could be estimated as 9.18 U/mL and 0.591, respectively, at 25 ºC and 0.1 mol/L phosphate buffer pH 7.5. A column made of glass with an inner diameter of 1 cm was used for the expanded bed adsorption (EBA). The residence time was reduced 10 fold by increasing the expansion degree 2.5 times; nonetheless, the plate number (N) value was reduced only 2 fold. After adsorption, the bromelain was eluted in packed bed mode, with a downward flow. The purification factor was about 13 fold and the total protein was reduced 4 fold. EBA showed to be feasible for purification of bromelain.
Keywords: Adsorption; Enzyme Activity; Purification; Axial Dispersion; Expanded Bed Adsorption; Bromelain.
INTRODUCTION
The pineapple (Ananas comosus L.) is cultivated extensively in Hawaii, Philippines, Caribe, Malaysia, Australia, Mexico, South Africa and Brazil. Brazil is the pineapple's second worldwide producer with 45,000 planted hectares. The main planted areas are the rain forest and northeast, although it is cultivated all around the country (Silveira, 2007).
The stem and fruit bromelains (formerly E.C. 3.4.22.4 and E.C. 3.4.22.5, respectively) are extracted from the A. comosus. Considered by many to be a whole fruit, it is in fact an infrutescence. Many independent fruits are bonded together in one body around a fibrous stem. The stem bromelain (E.C. 3.4.22.32) is the most abundant endopeptidase cystein in the pineapple's stem. It exhibits a broad specificity for protein cleavage, having a strong preference for Z-Arg-Arg-|-NHMec amongst the small molecule substrates (Hatano, et al., 1998; Harrach et al., 1998; Hatano et al., 2002; Haq et al., 2002; Rasheedi, 2003; Khan et al., 2003; Gaspani et al., 2002). The fruit bromelain (E.C. 3.4.22.33) is extracted from the pineapple infrutescence. It hydrolyzes proteins with a broad specificity for peptide bonds. Bz-Phe-Val-Arg-|-NHMec is a good synthetic substrate, but there is no action on Z-Arg-Arg-|-NHMec (Maurer, 2001).
Expanded Bed Adsorption (EBA) is a chromatographic technique for separation and purification of biological products directly from crude feedstock, without centrifugation, microfiltration and other prior clarification steps (Chase, 1994; Hjorth; 1997; Thömmes, 1997; Anspach et al., 1999; Trinh et al., 2006; Camprubi et al., 2006; Tan et al., 2006). This technique permits crude feeding into the chromatographic column without initial treatment and, as the bed expands, it increases adsorbent surface contact, making interaction with the target molecule more effective (Roy et al., 1999; Fernandez-Lahore et al., 2001).
Several works on expanded bed adsorption have contributed to a better understanding of the effects of adsorption, emphasizing studies of adsorbent type and size (Yamamoto et al., 2001; Dainiak et al., 2002), bed height, linear velocity (Mullick and Flickinger, 1999), fluidization and elution solution effects on residence time distribution (Fernandez-Lahore et al., 2001; Santos et al., 2000; Santos et al., 2002) for application in the recovery of important biomolecules.
The axial dispersion in EBA is a parameter of greater importance, as it reveals the flow performance, the adsorption and mass transfer mechanisms of biomolecules and the particular adsorption behaviors along the bed. Non-uniform axial distribution of particle size and local bed voidage are always established within the bed, due to broad size and/or particle density, which results in the variation of the axial dispersion with the bed height (Bruce and Chase, 2001; Yun et al., 2004a; Yun et al., 2004b).
In the present work, bromelain from a crude extract of Ananas comosus was purified by expanded bed adsorption with Amberlite IRA 410 ion-exchange resin on a glass column (1 cm i.d.). The effect of expansion degree of resin bed on bromelain purification was studied and also a residence time distribution study was performed.
MATERIAL AND METHODS
Reagents
Amberlite IRA 410 ion-exchange resin was purchased from VETEC (São Paulo, Brazil). Pineapple, Ananas comosus cv. Smooth cayenne, was purchased at a local market. All others reagents were of analytical grade.
EBA Column
A glass column of 1 cm inner diameter and 40 cm height with an adjustable piston on the top, feed inlet at the bottom and an outlet at the top was used. A sixty mesh plate at the feed inlet was used to avoid loss of adsorbent particles. A ruler was placed along the column to measure the bed height.
Enzyme Extract
The enzyme extract was obtained from the pineapple's (A. comosus) infrutescence. The pineapple's stem and fruit were processed in a blender and then filtered in a sixty mesh filter to remove the plant tissue fibres.
Enzyme Assay
The bromelain proteolytic activity was estimated by the method described by Kunitz (1973) and modified by Walter (1984), using casein 2 % (w/v) as substrate and tyrosine as standard. One enzymatic unit was defined as the bromelain amount necessary to produce 1µmol/mL of tyrosine in 1 minute at 37ºC.
Protein Determination
The total protein concentration was determined by the method described by Deutscher (1990) using albumin as standard. The protein concentration was measured by absorbance at 280 nm.
Adsorption Equilibrium and Kinetics
In kinetic experiments, 2 mL of drained resin was mixed up with 20 mL of buffered bromelain solutions (0.1 mol/L phosphate buffer pH 7.5). The adsorption was carried out in a shaking incubator at 25ºC. At different time intervals, supernatant samples of 0.5 mL were analysed for bromelain activity. Using this procedure, the time course of bromelain activity decrease was determined.
In adsorption equilibrium experiments, 5 mL of drained resin was added to 25 mL of bromelain extract solutions of different concentrations. The aqueous solution was 0.1 mol/L phosphate buffer (pH 7.5). Adsorption experiments were conducted at 25ºC for 2 h in a shaking incubator (100 rpm). At the end of adsorption, the solid phase was separated and the supernatant was analyzed for bromelain activity. The activity of adsorbed bromelain was calculated by mass balance.
Determination of Bed Voidage ( ε )
Bed voidage was obtained by substitution of data for specific mass (ρp) and mass of the adsorbent particles (mP), cross sectional area of the column (AT) and bed height (H) into the following equation (Santos et al., 2000; Fernandez-Lahore et al., 2001; Yamamoto et al., 2001):
where VP is the particle volume and VB is the bed volume.
Residence Time Distribution (RTD) Study
Phosphate buffer at 0.1 mol/L concentration and at pH 7.5 was used as fluidizer; the bed was fluidized until the bed height achieved the pre-determined height (1.5, 2.0 and 2.5 times the initial bed height). All experiments were carried out at standard conditions of temperature and pressure (25ºC and 1 atm). An acetone solution (2.5 % v/v) was used as tracer. The acetone solution was fed into the column until a maximum UV signal was observed at the outlet and then, the feed solution was switched to buffer and samples collected at the column outlet at time intervals varying with the flow velocity.
The RTD curves were obtained by the negative pulse method. Figure 1 shows how RTD curves were determined experimentally. The mean residence time (t) and the standard deviation (σ) were substituted into equation (2) to obtain the number of theoretical plates (N).
Axial dispersion (Daxial) was calculated as described in equation (3)
where U is the flow velocity.
Bromelain Purification
Expanded bed adsorption was carried out at 25ºC, 1 atm and pH 7.5. The adsorbent bed was pre-equilibrated at the desired height, with 0.1 mol/L phosphate buffer at pH 7.5. A 4.0 cm bed height was expanded to 6.0, 8.0, and 10 cm; these bed heights correspond to 1.5, 2.0 and 2.5-fold expansion degrees, respectively. 25 mL of enzyme solution, 1.02 U/mL of enzyme and 2.7 mg/mL of protein, in phosphate buffer at pH 7.5, were loaded onto the column bottom for adsorption of bromelain on Amberlite IRA 410 ion-exchange resin. After adsorption, the column was washed until the protein concentration at the outlet reached the baseline. The elution was performed with a continuous 0.1 - 0.5 mol/L NaCl gradient at 0.95 mL/min in downward flow. The bromelain activity and protein concentration were measured from time to time during adsorption, washing and elution periods.
SDS-PAGE
SDS-PAGE was performed according to the method described by Hochstrasser et al. (1998a; 1998b) for silver staining. The molar mass range was from 24 kDa to 66 kDa, and the markers were Trypsinogen (24 kDa); Carbonic Anhydrase (29 kDa); Glyceraldehyde-3-phosphate dehydrogenase (36 kDa); Ovoalbumin (45 kDa); Glutamic dehydrogenase (55 kDa); and Albumin (66 kDa).
RESULTS AND DISCUSSION
Characterization of Amberlite IRA 410
Figure 2 shows the adsorption isotherms of bromelain on Amberlite IRA 410 ion-exchange adsorbent. The adsorption isotherm was well expressed by the Langmuir equation:
The adsorption of bromelain was near 6.11 U/mL of resin at 25 ºC and 0.1 mol/L phosphate buffer pH 7.5, although the maximum adsorption capacity (Qm) was nearly 9.2 U/mL of resin. The dissociation constant (kd) was 0.591 U/mL. The main difficulty in obtaining kinetic constants from bromelain adsorption was the limited amount of enzyme per cm3 of vegetative tissue. In addition, the Ananas comosus stem is very fibrous, requiring the addition of distilled water during the extraction of the enzyme, diluting the extract.
Lali et al. (1989) claimed that the wall effect on the bed expansion behaviour is negligible as long as the ratio of column to particle diameter is larger than 20. Because the value of this ratio in this work was larger than 20, the bed expansion experiments should be influenced by the wall effect. The bed expansion degrees for the resin are shown in Figure 3, and the expansion degrees for Streamline are also shown for comparison.
Amberlite IRA 410 has a specific mass (ρp) of 1.12 g/mL and a particle diameter of 4 x 10-4 m. Although the specific mass is smaller than streamline material (Amersham Pharmacia, 1997), the particle diameter is greater, resulting in lower expansion degrees with higher flow velocities, as shown in Figure 3.
Residence Time Distribution Study
Figure 4 shows RTD curves for acetone (2.5 % w/v) tracer as it passed through the column bed. Analyzing the RTD obtained after a perfect ion-tracer pulse (axial dispersion, plug-flow exchange of mass with stagnant zones) gave a quantitative description of the underlying hydrodynamic situation during the EBA process (Fernandez-Lahore et al., 2001).
Table 1 shows the RTD results after substitution of data into equations (1) to (3), according to the methodology used by several authors (Santos et al., 2000; Fernandez-Lahore et al., 2001; Yamamoto et al., 2001; Toledo et al., 2006).
As detailed in Table 1, the liquid axial dispersion increased with bed height and hence with expansion degree. There was a 12-fold increase in axial dispersion when the expansion degree was raised 1.5 fold and a 51-fold increase as its expansion degree increased 2.5 fold. This increase in axial dispersion facilitates the flow of particles and biological material into the bed and increases the interaction of target molecule and adsorbent particles, facilitating the feed of crude extract directly to the bed, avoiding fouling and reducing costs, as the number of pre-treatment and pre-purification steps may be reduced, which are the main chromatographic problems (Wheelwright, 1994; Amersham Pharmacia, 1997; Fernandez-Lahore et al., 2001).
Expanded Bed Adsorption of Bromelain
Table 2 shows the results for Bromelain by expanded bed adsorption on Amberlite IRA 410. The recovery yield increased as the expansion degree increased, which should occur because there are more adsorbent-target molecule interactions in expanded beds than in fixed beds, by the increase of the influence of bed voidage. This effect was also reported by Chang et al. (1994), and Santos (2000) working with G6PDH and lysozyme, respectively.
As the expanded bed lengthened, there was also an increase in the specific activity. This shows that bromelain purification is somehow proportional to the expansion degree or flow velocities under the conditions studied here. Similar results were found by Toledo et al. (2006) working with α-amylase. It also agrees with the RTD study, because the bed height increases the contact between enzymes and the ion-exchange resin, Amberlite IRA 410.
The purification factor also rose as the expanded bed height increased. The purification factor of the expanded bed at 2.5-fold expansion degree increased more than 12-fold, which is higher than in reverse micellar systems (Hebbar et al., 2008) or aqueous two-phase systems (Rabelo et al., 2004). This purification factor was close to those reported in ion-exchange chromatography for several enzymes (Kim et al., 2000; Wang et al., 2008). However, the use of DEAE-cellulose and DEAE-sephacel resins increased the cost of purification of biomolecules. With the use of Amberlite IRA 410 ion-exchange resin and the expanded bed condition, it was possible to obtain pure biological products, such as bromelain, with lower operational cost, thus, decreasing overall process cost (Fernandez-Lahore et al., 2001).
The protein and bromelain activity history is presented in Figure 5. It shows that bromelain was eluted in a single peak, although there was an overlap of the first and second peak. This might have occurred due to variations in buffer composition at the column outlet; the stepwise gradient provides at least three different buffer compositions travelling through the column at the same time. This might have caused the overlap to appear in the chromatogram, which showed more than one protein peak, although it is related to a difference in the mobile-phase composition, not to the heterogeneity of the product (Wheelwright, 1994) as seen in the SDS-PAGE of the collected extract (Figure 6).
The SDS-PAGE analysis shows that the eluted peaks containing bromelain activity were electrophoretically pure. The estimated molecular weight of bromelain was around 32.2 kDa; similar results were found by Silverstein and Kezdy (1975), 35 kDa; and Murachi (1976), 33 kDa. However, Ota et al. (1972), Takahashi et al. (1973), Wharton (1974), and Suh et al. (1992) have found different molecular weights for bromelain, 28 kDa, 28 kDa, 28.4 kDa, and 37 kDa, respectively.
CONCLUSIONS
This work showed that the purification of bromelain by expanded bed adsorption is feasible by using Amberlite IRA 410 as adsorbent, showing good activity for the recovered extract and a good purification factor for the purification process as well. It was also shown that, by increasing flow velocity, other variables also increase such as bed expansion, bed voidage, HEPT and axial dispersion, which lead to a high purification factor and an electrophoretically pure product.
ACKNOWLEDGEMENT
The authors acknowledge the aid of Monique Ferraz and Igor Teixera with the SDS-PAGE technique. The authors are also thankful to Capes and CNPq for financial support.
(Submitted: August 14, 2007 ; Revised: May 8, 2008 ; Accepted: May 16, 2008)
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Publication Dates
-
Publication in this collection
10 Mar 2009 -
Date of issue
Mar 2009
History
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Accepted
16 May 2008 -
Reviewed
08 May 2008 -
Received
14 Aug 2007