Production and purification of two recombinant proteins from transgenic corn.

This study reports the production, purification, and characterization of recombinant Escherichia coli beta-glucuronidase (GUS) and chicken egg-white avidin from transgenic corn seed. The avidin and gus genes were stably integrated in the genome and expressed over seven generations. The accumulation levels of avidin and GUS in corn kernel were 5.7% and 0.7% of extractable protein, respectively. Within the kernel, avidin and GUS accumulation was mainly localized to the germ, indicating possible tissue preference of the ubiquitin promoter. The storage-stability studies demonstrated that processed transgenic seed containing GUS or avidin can be stored at 10 degrees C for at least 3 months and at 25 degrees C for up to 2 weeks without a significant loss of activity. The heat-stability experiments indicated that GUS and avidin in the whole kernels were stable at 50 degrees C for up to 1 week. The buffer composition also had an affect on the aqueous extraction of avidin and GUS from ground kernels. Avidin was purified in one step by using 2-iminobiotin agarose, whereas GUS was purified in four steps consisting of adsorption, ion-exchange, hydrophobic interaction, and size-exclusion chromatography. Biochemical properties of purified avidin and GUS were similar to those of the respective native proteins.

Processing of transgenic corn seed and its effect on the recovery of recombinant beta-glucuronidase.

The tools of plant biotechnology that have been developed to improve agronomic traits are now being applied to generate recombinant protein products for the food, feed, and pharmaceutical industry. This study addresses several processing and protein recovery issues that are relevant to utilizing transgenic corn as a protein production system. The gus gene coding for beta-glucuronidase (rGUS) was stably integrated and expressed over four generations. The accumulation level of rGUS reached 0.4% of total extractable protein. Within the kernel, rGUS was preferentially accumulated in the germ even though a constitutive ubiquitin promoter was used to direct gus expression. Fourth-generation transgenic seed was used to investigate the effect of seed processing on the activity and the recovery of rGUS. Transgenic seed containing rGUS could be stored at an ambient temperature for up to two weeks and for at least three months at 10 degrees C without a significant loss of enzyme activity. rGUS exposed to dry heat was more stable in ground than in whole kernels. The enzyme stability was correlated with the moisture loss of the samples during the heating. Transgenic seed was dry-milled, fractionated, and hexane extracted to produce full-fat and defatted germ fractions. The results of the aqueous extraction of rGUS from ground kernels, full-fat germ, and defatted-germ samples revealed that approximately 10 times more rGUS per gram of solids could be extracted from the ground full-fat germ and defatted-germ than from the kernel samples. The extraction of corn oil from ground germ with hot hexane (60 degrees C) did not affect the extractable rGUS activity. rGUS was purified from ground kernels and full-fat germ extracts by ion exchange, hydrophobic interaction, and size exclusion chromatography. Similar purity and yield of rGUS were obtained from both extracts. Biochemical properties of rGUS purified from transgenic corn seed were similar to those of E. coli GUS.

Production of recombinant proteins in transgenic plants: Practical considerations.

This review is based on our recent experience in producing the first commercial recombinant proteins in transgenic plants. We bring forward the issues that have to be considered in the process of selecting and developing a winning transgenic plant production system. From the production point of view, transcription, posttranscription, translation, and posttranslation are important events that can affect the quality and quantity of the final product. Understanding the rules of gene expression is required to develop sound strategies for optimization of recombinant protein production in plants. The level of recombinant protein accumulation is critical, but other factors such as crop selection, handling and processing of transgenic plant material, and downstream processing are equally important when considering commercial production. In some instances, the cost of downstream processing alone may determine the economic viability of a particular plant system. Some of the potential advantages of a plant production system such as the high levels of accumulation of recombinant proteins, glycosylation, compartmentalization within the cell, and natural storage stability in certain organs are incentives for aggressively pursuing recombinant protein production in plants. (c) 1997 John Wiley & Sons, Inc. Biotechnol Bioeng 56: 473-484, 1997.

Starch-binding domain of Aspergillus glucoamylase-I. Interaction with beta-cyclodextrin and maltoheptaose.

The characterization is reported of two peptide fragments (SBD106 and SBD122) containing the starch-binding domain (SBD) of Aspergillus sp. glucoamylase I. The starch-binding peptides were produced in Escherichia coli as fusion proteins of the maltose-binding protein (MBP). SBD106 (11.9 kDa) and SBD122 (13.8 kDa) were purified from the factor Xa digest of MBP fusion proteins. The amino acid compositions were similar to those deduced from their amino acid sequences. The interactions of beta-cyclodextrin and maltoheptaose with purified SBD peptides were investigated by UV difference spectroscopy. SBD106 and SBD122 bound specifically beta-cyclodextrin with a dissociation constant (Kd) of 34 microM and 23.5 microM, respectively. Maltoheptaose binding to SBD106 and SBD122 was weaker than that of beta-cyclodextrin; dissociation constants were 0.57 and 0.50 mM, respectively. The results indicate that the intramolecular disulfide bonding is not required for the domain functioning and that O-glycosylation is not critical for the functioning of the starch-binding domain, but may affect its conformation and dynamics.

Functional starch-binding domain of Aspergillus glucoamylase I in Escherichia coli.

We have fused three starch-binding domains (SBD) encoding gene fragments (residues 511-616, 495-616 and 481-616) of glucoamylase I (GAI) to the 3' end of the Escherichia coli malE gene encoding maltose-binding protein (MBP). The fusion proteins were produced in E. coli and were purified by chromatography on cross-linked amylose. Factor Xa digestion of the fusion proteins resulted in the release of functional SBD fragments which were separated from MBP on the basis of their differential binding to cross-linked amylose. The amino acid (aa) composition of the purified SBD fragments agreed with the respective amino acid compositions of GAI. The sizes of the SBD fragments were 11.9, 13.8 and 15.6 kDa, respectively.