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Purification of recombinant aprotinin produced in transgenic corn seed: separation from CTI utilizing ion-exchange chromatography

Abstract

Protein expression in transgenic plants is considered one of the most promising approaches for producing pharmaceutical proteins. As has happened with other recombinant protein production schemes, the downstream processing (dsp) of these proteins produced in plants is key to the technical and economic success of large-scale applications. Since dsp of proteins produced transgenically in plants has not been extensively studied, it is necessary to broaden the investigation in this field in order to more precisely evaluate the commercial feasibility of this route of expression. In this work, we studied the substitution of an IMAC chromatographic step, described in previous work (Azzoni et al., 2002), with ion-exchange chromatography on SP Sepharose Fast Flow resin as the second step in the purification of recombinant aprotinin from transgenic maize seed. The main goal of this second purification step is to separate the recombinant aprotinin from the native corn trypsin inhibitor. Analysis of the adsorption isotherms determined at 25°C under different conditions allowed selection of 0.020 M Tris pH 8.5 as the adsorption buffer. The cation-exchange chromatographic process produced a high-purity aprotinin that was more than ten times more concentrated than that generated using an IMAC step.

Recombinant aprotinin; Transgenic corn; Protease inhibitor purification; Downstream processing; Ion-exchange chromatography


BIOTECHNOLOGY

Purification of recombinant aprotinin produced in transgenic corn seed: separation from CTI utilizing ion-exchange chromatography

A. R. AzzoniI; K. TakahashiI; S. L. WoodardII, III; E. A. MirandaI, * * To whom correspondence should be addressed ; Z. L. NikolovII, III

ILEBp: Laboratório de Engenharia de Bioprocessos, Departamento de Processos Biotecnológicos, Phone: +(55) (19) 3788-3918, FEQ, UNICAMP, CP 6066, CEP 13083-970, Campinas - SP, Brazil. E-mail: everson@feq.unicamp.br

IIProdiGene, College Station, TX 77845, USA

IIIBiological and Agricultural Engineering, Texas A&M University, College Station, Texas 77843-2117, USA

ABSTRACT

Protein expression in transgenic plants is considered one of the most promising approaches for producing pharmaceutical proteins. As has happened with other recombinant protein production schemes, the downstream processing (dsp) of these proteins produced in plants is key to the technical and economic success of large-scale applications. Since dsp of proteins produced transgenically in plants has not been extensively studied, it is necessary to broaden the investigation in this field in order to more precisely evaluate the commercial feasibility of this route of expression. In this work, we studied the substitution of an IMAC chromatographic step, described in previous work (Azzoni et al., 2002), with ion-exchange chromatography on SP Sepharose Fast Flow resin as the second step in the purification of recombinant aprotinin from transgenic maize seed. The main goal of this second purification step is to separate the recombinant aprotinin from the native corn trypsin inhibitor. Analysis of the adsorption isotherms determined at 25°C under different conditions allowed selection of 0.020 M Tris pH 8.5 as the adsorption buffer. The cation-exchange chromatographic process produced a high-purity aprotinin that was more than ten times more concentrated than that generated using an IMAC step.

Keywords: Recombinant aprotinin; Transgenic corn; Protease inhibitor purification; Downstream processing; Ion-exchange chromatography.

INTRODUCTION

Aprotinin, also known as bovine pancreatic trypsin inhibitor, is an inhibitor of serine proteases including kallikrein, trypsin, and chymotrypsin. First isolated from bovine sources by Kunitz and Northrop (1936), it is a single-chain polypeptide made up of 58 amino acid residues with a molecular mass of 6.5 kDa. Aprotinin has applications as a protease inhibitor in tissue cultures and is also an expensive drug used during cardiac surgery (Beath et al., 2000). Bovine lung has been the commercial source of pharmaceutical-grade aprotinin. The bovine source of pharmaceutical proteins poses concerns about possible product contamination with bovine spongiform encephalopathy (BSE). Consequently, alternative systems of aprotinin production have been pursued. Recombinant aprotinin has been expressed in Escherichia coli (Auerswald et al., 1987), Pichia pastoris (Vedvick et al., 1991), Sacharomyces cerevisiae (Norris et al., 1990), and Hansenula polymorpha (Zurek et al., 1996).

Taking into account the important advantages of plants over other expression systems, such as low production and scale-up costs, the natural storage stability of the recombinant proteins in tubers or seeds, and the fact that transgenic plants do not propagate human or animal pathogens (Cramer et al., 2000; Hood and Howard, 1999; Kusnadi et al., 1997), the expression of aprotinin in maize seeds was studied by Zhong et al. (1999). Now, recombinant aprotinin produced in maize seeds is commercially available under the name of AproliZeanTM (Prodigene, 2004).

Recently, Azzoni et al. (2002) reported the extraction and purification of recombinant aprotinin produced in maize seeds utilizing a two-step chromatographic process. After aqueous extraction of transgenic seed flour, aprotinin was adsorbed from the liquid phase in an immobilized trypsin affinity column together with the native corn trypsin inhibitor CTI. Then, immobilized metal ion chromatography (IMAC) used in a negative mode, removed CTI from the recombinant aprotinin. Although the two-step process produced aprotinin of high purity and yield, this purification method had two disadvantages: possible contamination of the final product with metal ions that could be difficult and/or expensive to remove and excessive dilution of the recombinant aprotinin during the negative-mode IMAC step. Therefore, the objective of this work was to evaluate the possibility of substituting a cation-exchange chromatographic step for the IMAC step to separate CTI from aprotinin, since ion exchange does not have metal leakage and major dilution problems. The rationale for selecting a cation-exchange step includes the following considerations: 1) the significant difference in pI between aprotinin (10.5) and CTI isoforms (5.1-7.3) (Hojima et al., 1980), 2) the low cost of resin, and 3) ion-exchange scalability and robustness.

MATERIALS AND METHODS

Materials

The transgenic corn seed containing the recombinant aprotinin used in this work was the same as that used by Zhong et al. (1999). The HiTrap column loaded with SP Sepharose Fast Flow resin (cation-exchange resin) was purchased from Amersham-Pharmacia, USA. N-a-benzoyl-DL-arginine-p-nitroanilide (BApNA), bovine trypsin (Type I), and aprotinin were purchased from Sigma, USA. CTI was purified from nontransgenic corn seed according to Swartz et al. (1977). The Coomassie Plus Protein Reagent was from Pierce, USA. All other chemicals used in this work were of at least reagent grade.

Methods

• Transgenic Corn Seed Grinding

Seeds were ground to a particle size smaller than 0.85 mm using an Intermediate Model laboratory-scale mill from Thomas-Wiley, USA.

• Analytical Assays

Total protein concentration was determined by using the Pierce Coomassie Plus Protein Assay (Pierce, USA). Trypsin inhibition assay was carried out according to the Sigma Enzymatic Assay of Aprotinin per Kassel (1970). One trypsin unit was defined as the amount of enzyme that hydrolyzes 1.0 mmol of BApNA per minute at pH 7.8 and 25°C. One trypsin inhibition unit was defined as the amount of inhibitor that decreases the activity of two trypsin units by 50%. Aprotinin was quantified by ELISA according to Zhong et al. (1999). All assays were done in triplicate, and the final aprotinin concentration of each sample was expressed as the mean of the three replicates. Electrophoresis was carried out under denaturing conditions (SDS-PAGE) as described by Zhong et al. (1999).

• Determination of Adsorption Isotherms

The adsorption isotherms of aprotinin and CTI on the cation-exchange resin (SP Sepharose Fast Flow) were generated at 25°C using 1.5 mL Eppendorf tubes. Six different adsorption buffers were used: 0.020 M Tris and 0.030 M sodium phosphate buffers at pH values of 7.5 and 8.5 and 0.020 M Tris pH 8.5 containing 0.100 and 0.200 M NaCl, respectively. Five milligrams of drained resin previously equilibrated with a specific adsorption buffer was added to 1.0 mL of the desired protein solution prepared in the same buffer. The adsorption isotherm experiments were conducted as described by Azzoni and Miranda (1999). A nonlinear regression fit of the experimental data was done using the Langmuir adsorption model (Langmuir, 1916).

• Aprotinin Extraction and Affinity Chromatography on Trypsin-Agarose Resin

Aqueous extraction of the recombinant aprotinin and its recovery utilizing affinity chromatography on immobilized trypsin was carried out according to Azzoni et al. (2002). Typically, two hundred grams of aprotinin corn meal were mixed with 1.0 L of water for 30 min at pH 3.0 (pH controlled by addition of 1.0 M HCl). Filtered liquid phase was adjusted to pH 7.8 using a 1.0 M NaOH solution. The affinity chromatography was carried out with a 16 x 100 mm XK16 column (Pharmacia, Sweden) with 10 mL of trypsin-agarose resin. The column was equilibrated using 50 mM NaPi buffer pH 7.8 with 0.25 M NaCl. After loading the sample (775 mL at 2.0 mL/min), the column was washed with 50 mM NaPi buffer pH 7.8 containing 0.6 M NaCl. The elution step was done with 50 mM KCl-HCl pH 2.0 and 3.0 mL/min. The eluted fractions (4.0 mL) were immediately diluted 1:1 with 0.04 M Tris buffer pH 8.5 (final Tris concentration of 0.020 M), combined, and then adjusted to pH 8.5 with 1.0 M NaOH.

• Ion-Exchange Chromatography

Ion-exchange chromatography was carried out using SP Sepharose Fast Flow packed in a 1.0 mL HiTrap column. The column was equilibrated with 0.020 M Tris pH 8.5 (buffer A). The eluted peak from the affinity chromatography containing the high aprotinin concentrations were combined as a pool and fed into the SP-Sepharose column (only the first two fractions of this peak with a high protein concentration - mainly corn trypsin inhibitor - but a low aprotinin concentration were discarded, as previously described by Azzoni et al. (2002)). The column was then washed with 5 mL of buffer A. Elution was accomplished with a linear gradient of 0 to 1.5 M NaCl in buffer A using 20 column volumes (20 mL). All chromatographic steps were performed at a flow rate of 1.0 mL/min. The flow-throughs of the feeding and washing steps were collected as two separate pools and analyzed for aprotinin, total soluble protein, and trypsin inhibition along with the 1.5 mL fractions from the elution step.

RESULTS AND DISCUSSION

Determination of Adsorption Isotherms

The goal of the adsorption isotherm experiments was to identify conditions that allowed for maximum binding of aprotinin while minimizing the amount of CTI binding to the cation-exchange resin. Conditions examined included type of ion, pH, and the effect of NaCl in the adsorption buffer. Kinetic experiments were first carried out to determine the time needed to guarantee that equilibrium was achieved in the adsorption of aprotinin. This experiment was conducted using a 0.020 M Tris pH 7.5 buffer at 25°C. Since aprotinin liquid phase concentration stabilized after an adsorption time of just over 1 h (Figure 1), the adsorption time for isotherm experiments was set to 2 h.


Next, the effect of Tris and phosphate buffer ions on the adsorption of aprotinin and CTI was compared. Figure 2 shows the adsorption isotherms obtained at 25°C for aprotinin and CTI binding to the cation-exchange resin with the Tris buffer at either pH 7.5 or pH 8.5. Figure 3 shows the results of the same experiment performed in phosphate buffer. The shape of aprotinin isotherms is of the Langmuirian type, indicating specific interaction of aprotinin in both buffers and pHs. CTI isotherms were linear in both buffers and suggest nonspecific, weak interactions with the resin. The significant difference in adsorption at equilibrium between aprotinin and CTI under all conditions studied (Figures 2 and 3) indicates the possibility of cation-exchange chromatographic separation of aprotinin and CTI. The equilibrium binding parameters of aprotinin, calculated by a nonlinear regression fit of the experimental data in Figures 2 and 3, are shown in Table 1. Adsorption capacities for aprotinin were at least five to eighteen times higher than those for CTI. The lower adsorption pH allowed a higher adsorption capacity for aprotinin (qm) and stronger interaction between aprotinin and the resin adsorption sites (indicated by a lower Kd). Because the greatest difference in adsorption between the two proteins was measured in Tris pH 8.5, all subsequent experiments were performed in this buffer.



The effect of salt (ionic strength) on adsorption of aprotinin was also checked at two different NaCl concentrations. The data presented for adsorption of aprotinin in 0.020 M Tris pH 8.5 were plotted together with data for adsorption in this same buffer with 0.1 or 0.2 M NaCl (Figure 4). The results indicated that NaCl drastically reduces the adsorption of aprotinin onto the resin and aprotinin could be desorbed in a step change using a NaCl concentration higher than 0.2 M.


Recombinant Aprotinin Purification Using Cation-Exchange Chromatography

Having determined the condition of high adsorption of aprotinin onto the SP Sepharose Fast Flow resin, a pool of fractions eluted from a trypsin-agarose chromatographic column containing aprotinin was chromatographed on this cation-exchange resin. The fractions were analyzed for protein and aprotinin contents and trypsin activity inhibition. The profiles obtained are presented in Figure 5. Mass and activity balances for the whole process (extraction, affinity, and ion-exchange chromatographies) are presented in Table 2.


Just one protein peak containing aprotinin was detected. Despite the error in the ELISA method that overestimated the amount of aprotinin eluted (equivalent to 125% of the aprotinin fed into the ion-exchange column), we can interpret that this polypeptide was successfully adsorbed and eluted from the column. The ion-exchange chromatographic step and overall purification factors (9.5 and 465, respectively) were higher than those reported by Azzoni et al. (2002) (4.5 and 280, respectively). The overall yield found (37%) was lower than that previously described (49%), mainly due to a column overload during the affinity chromatographic step. SDS-PAGE of the samples of the ion-exchange chromatography confirmed the high level of purification of the recombinant aprotinin (Figure 6). The pool of fractions in which the purified recombinant aprotinin was expected to elute showed just one band in SDS-PAGE (lane 5), indicating the high purity of this preparation. The pool of eluted fractions from the affinity column (feed for the ion-exchange column, lane 3) contains three bands. The band with intermediate molecular mass is composed in part of aprotinin and is found there at low concentration. This can be realized by analyzing the flow-through of the ion-exchange column. It contains just 3% of the aprotinin fed onto the resin (lane 2) and the rest is CTI. Under reducing conditions for SDS-PAGE, the two-chain CTI (14 kDa) can be seen on the gel as two polypeptides of approximately 8.0 and 5.0 kDa each resulting from the cleavage of the molecule by the immobilized trypsin in the affinity column (Lei and Reeck, 1986). The flow through fraction (lane 4) contained the CTI. For comparison, aprotinin purified by the method described by Azzoni et al. (2002) was loaded in lane 6.


CONCLUSIONS

In this work adsorption isotherms were obtained for the binding of aprotinin and CTI to a cation-exchange resin and binding parameters were determined for the different conditions examined. We further demonstrated that substitution of a cation-exchange chromatographic step for the IMAC chromatographic step of the purification process developed by Azzoni et al. (2002) is feasible. This ion-exchange purification step developed here had a significantly high recovery and a purification factor 2.1 times higher than that of the IMAC step. More striking was the concentration of purified aprotinin: the ion-exchange chromatography produced a recombinant aprotinin solution over ten times more concentrated than the IMAC product.

ACKNOWLEDGMENTS

Authors (A.R. Azzoni and E.A. Miranda) gratefully acknowledge the financial support of the Coordenação de Aperfeiçoamento de Pessoal de Ensino Superior (CAPES), Brazil and the Fundação de Amparo a Pesquisa do Estado de São Paulo (FAPESP), Brazil. A. Azzoni thanks Iowa State University for sponsoring his research program in the United States. We also thank Dra. Sonia Maria Alves Bueno (Universidade Estadual de Campinas, Brazil) for the fruitful discussions and assistance during this work.

Received: July 30, 2004

Accepted: February 23, 2005

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  • *
    To whom correspondence should be addressed
  • Publication Dates

    • Publication in this collection
      28 Sept 2005
    • Date of issue
      Sept 2005

    History

    • Accepted
      23 Feb 2005
    • Received
      30 June 2004
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