Title
Irreversible aggregation of recombinant bovine granulocyte-colony stimulating factor (bG-CSF) and implications for predicting protein shelf life
Author
Christopher J. Roberts, Richard T. Darrington, Maureen B. Whitley
Year
2003
Journal
Journal of Pharmaceutical Sciences
Abstract
The kinetics of irreversible aggregation of bovine Granulocyte-Colony Stimulating Factor (bG-CSF) in solution were investigated as a function of temperature (T), concentration, and pH, and analyzed in terms of an Extended Lumry-Eyring model of protein aggregation proceeding via a non-native conformational state. In the spirit of classic Lumry-Eyring models, the observed kinetics are separated into contributions from thermodynamic or conformational stability of unaggregated native and non-native states, and the intrinsic aggregation kinetics of non-native molecules. It is found that a detailed treatment of the intrinsic kinetics coupled with a two-state approximation of the reversible unfolding transition is sufficient to allow quantitative prediction of low-T stability from high-T data despite highly non-Arrhenius kinetics. Accounting for shifts in conformational equilibrium quantitatively captures the non-Arrhenius T dependence, without requiring the assumption of a change in the rate-determining step with T. From a more general perspective, the observed aggregation behavior of bG-CSF is consistent with the rate-determining step being aggregation at T below a crossover temperature Tx that is inversely related to initial protein concentration. Above Tx, irreversible unfolding is presumably the rate-determining step. The results illustrate that protein aggregation kinetics can, in principle, be predicted quantitatively from so-called accelerated data provided the thermodynamic and kinetic components can be separately extrapolated to longer term storage conditions.
Instrument
J-810
Keywords
Circular dichroism, Secondary structure, Chemical stability, Thermal stability, Thermodynamics, Biochemistry, Pharmaceutical