Protein precipitation by polyethylene glycol: a generalized model based on hydrodynamic radius.

PEGs for protein precipitation are usually classified by molecular weight. The higher molecular weight precipitants are more efficient but result in higher viscosity. Following empirical evidence that the precipitation efficiency is more comprehensively characterized by PEG hydrodynamic radius (r(h,PEG)) than molecular weight, this paper proposes a model to explicate the significance of r(h,PEG). A general expression was formulated to characterize the PEG effect exclusively by r(h,PEG). The coefficients of a linearized form were then fitted using empirical solubility data. The result is a simple numerical relation that models the efficiency of general-shaped PEG precipitants as a function of r(h,PEG) and protein hydrodynamic radius (r(h,prot)). This equation also explains the effects of environmental conditions and PEG branching. While predictions by the proposed correlation agree reasonably well with independent solubility data, its simplicity gives rise to potential quantitative deviations when involving small proteins, large proteins and protein mixtures. Nonetheless, the model offers a new insight into the precipitation mechanism by clarifying the significance of r(h,PEG). This in turn helps to refine the selection criterion for PEG precipitants.

Branched polyethylene glycol for protein precipitation.

The use of linear PEGs for protein precipitation raises the issues of high viscosity and limited selectivity. This paper explores PEG branching as a way to alleviate the first problem, by using 3-arm star as the model branched structure. 3-arm star PEGs of 4,000 to 9,000 Da were synthesized and characterized. The effects of PEG branching were then elucidated by comparing the branched PEG precipitants to linear versions of equivalent molecular weights, in terms of IgG recovery from CHO cell culture supernatant, precipitation selectivity, solubility of different purified proteins, and precipitation kinetics. Two distinct effects were observed: PEG branching reduced dynamic viscosity; secondly, the branched PEGs precipitated less proteins and did so more slowly. Precipitation selectivity was largely unaffected. When the branched PEGs were used at concentrations higher than their linear counterparts to give similar precipitation yields, the dynamic viscosity of the branched PEGs were noticeably lower. Interestingly, the precipitation outcome was found to be a strong function of PEG hydrodynamic radius, regardless of PEG shape and molecular weight. These observations are consistent with steric mechanisms such as volume exclusion and attractive depletion.

Zinc as an insulin replacement in hybridoma cultures.

There are many advantages to the use of protein-free media for biologics production, including a reduced risk of viral contamination from animal-derived proteins and simplification of downstream purification. In the course of developing protein-free media for hybridoma and myeloma cells, zinc was found to be an effective replacement for insulin, with no negative impact on viable cell density and antibody production. Transcript profiling using DNA microarrays indicated no major change in the global expression profile between the insulin and zinc-supplemented cultures, which is consistent with their similar growth and metabolic characteristics. Both DNA microarray and quantitative RT-PCR analysis showed increase in insulin receptor substrate 1 (Irs1) expression in zinc-supplemented cultures, while several key genes downstream of Irs1 in the insulin-signaling pathway, such as protein kinase B (PKB/Akt) and 3-phosphoinositide dependent protein kinase 1 (Pdpk1) did not show significant differences at the transcript level. Comparison of transcript profiles from cultures with low versus optimal zinc supplementation implicated the involvement of the insulin-related genes Pax6 and Phas1. Subtle differences were also observed between insulin and zinc in the serine-473 phosphorylation of Akt. Zinc increased serine-473 phosphorylation of Akt, but to a lesser extent than insulin. The phosphoinositide 3-kinase (PI3K) inhibitor, wortmannin, totally blocked the effect of both zinc and insulin on Akt activation, indicating the involvement of PI3K in the activation of Akt by zinc, rather than zinc acting on Akt directly. Our results highlight the impact of trace metal supplementation as protein-free media formulations move towards greater chemical definition.