Richard J. St. John scite author profile

High hydrostatic pressures (1-2 kbar), combined with low, nondenaturing concentrations of guanidine hydrochloride (GdmHCl) foster disaggregation and refolding of denatured and aggregated human growth hormone and lysozyme, and ␤-lactamase inclusion bodies. One hundred percent recovery of properly folded protein can be obtained by applying pressures of 2 kbar to suspensions containing aggregates of recombinant human growth hormone (up to 8.7 mg͞ml) and 0.75 M GdmHCl. Covalently crosslinked, insoluble aggregates of lysozyme could be refolded to native, functional protein at a 70% yield, independent of protein concentration up to 2 mg͞ml. Inclusion bodies containing ␤-lactamase could be refolded at high yields of active protein, even without added GdmHCl.

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High Pressure Refolding of Recombinant Human Growth Hormone from Insoluble Aggregates

John¹,

Carpenter²,

Balny³

et al. 2001

Journal of Biological Chemistry

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Two different types of insoluble, non-native aggregates of recombinant human growth hormone were formed by agitation in buffer or buffer containing 0.75 M guanidine HCl (GdnHCl) and characterized by infrared and second derivative UV spectroscopies. The degree of secondary structural perturbation was greater in the aggregates formed in 0.75 M GdnHCl. Both aggregate types were dissolved and refolded using high hydrostatic pressures in combination with either elevated temperature or non-denaturing levels of guanidine HCl or urea. The effects of a range of temperature, pressure, and chaotrope concentrations were tested and led to optimal conditions that approached 100% yield of native protein. The aggregates formed in 0.75 M GdnHCl required higher concentrations of urea or GdnHCl, or higher temperature or pressure for a yield equivalent to that for aggregates formed in buffer alone. Investigation of the effects of pressure, temperature, and chaotrope on unfolding of rhGH documented that under conditions used for optimal high pressure disaggregation and refolding, the native state is greatly favored thermodynamically (e.g. 25 kJ/mol at 2000 bar and 0.75 M GdnHCl). Dissolution of aggregates under pressure is a kinetically limited process. Comparison of refolding yields in GdnHCl and urea solutions suggest that pressure effects on electrostatic interactions do not dominate pressure effects on disaggregation. We suggest that non-native hydrogen bonds between protein molecules within aggregates of recombinant human growth hormone are responsible for the rate-limiting kinetic barrier in pressure-induced disaggregation.

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High‐Pressure Refolding of Disulfide‐Cross‐Linked Lysozyme Aggregates: Thermodynamics and Optimization

John

Carpenter

Randolph

2002

Biotechnology Progress

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Previous exploratory work revealed that high pressure (200 MPa), in combination with oxido-shuffling agents such as glutathione, effectively refolds covalently cross-linked aggregates of lysozyme into catalytically active native molecules, at concentrations up to 2 mg/mL (1). To understand further and optimize this process, in the current study we varied the redox conditions and levels of guanidine hydrochloride (GdnHCl) in the refolding buffer. Maximum refolding yields of 80% were seen at 1 M GdnHCl; higher concentrations did not increase refolding yields further. A maximum in refolding yield was observed at redox conditions with a 1:1 ratio of oxidized to reduced glutathione (GSSG:GSH). Yields decreased dramatically at more oxidizing conditions ([GSSG] > [GSH]). Kinetics of dissolution and refolding of covalently cross-linked aggregates of lysozyme depended strongly on redox conditions. At GSSG:GSH ratios of 4:1, 1:1, and 1:16, lysozyme dissolved and refolded with time constants of 62, 20, and 8 h, respectively. Estimates of the free energy of unfolding of lysozyme in GdnHCl solutions at 200 MPa suggested that the native state of lysozyme is strongly favored (ca.18.6 kJ/mol) under the conditions used for dissolution and refolding.

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High‐pressure refolding of human vascular endothelial growth factor (VEGF) recombinantly expressed in bacterial inclusion bodies: Refolding optimization, and feasibility assessment

Cothran¹,

John²,

Schmelzer³

et al. 2011

Biotechnology Progress

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High-pressure has been established as an effective technique for refolding proteins at high concentrations. In this study, high hydrostatic pressure (1-3 kbar) was utilized to refold a homodimeric protein from inclusion bodies and the process was evaluated for large-scale manufacturing feasibility. This research focused on increasing protein concentration while maximizing yield and product quality. Refolding yields of 29-42% were achieved in the absence of urea at 2 kbar and at a protein concentration of 6 g/L. Optimization of the refolding buffer composition via multivariate design of experiments and other process parameters such as refolding pressure, gas sparging, and time under pressure are discussed. Although high-pressure refolding can be considered a viable technology for manufacturing if the gains are clearly identified, in this particular case, the benefits that the high-pressure technology offers do not compensate for the drawbacks of implementing new equipment in an existing facility, and unknown impact of scale-up for this molecule.

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Richard J. St. John

High pressure fosters protein refolding from aggregates at high concentrations

High Pressure Refolding of Recombinant Human Growth Hormone from Insoluble Aggregates

High‐Pressure Refolding of Disulfide‐Cross‐Linked Lysozyme Aggregates: Thermodynamics and Optimization

High‐pressure refolding of human vascular endothelial growth factor (VEGF) recombinantly expressed in bacterial inclusion bodies: Refolding optimization, and feasibility assessment

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