Your search keyword '"Valentine Wanga"' showing total 1 results

1. Improving the large scale purification of the HIV microbicide, griffithsin

Author

Kenneth E. Palmer, Joshua L Fuqua, and Valentine Wanga

Subjects

Anti-HIV Agents, Magnesium Chloride, Human immunodeficiency virus (HIV), Microbicide, medicine.disease_cause, 03 medical and health sciences, Tobacco, Protein purification, medicine, Purification methods, 030304 developmental biology, Active ingredient, Griffithsin, 0303 health sciences, Manufacturing technology, Chromatography, biology, 030306 microbiology, business.industry, N. benthamiana, Industrial scale, HIV, Recombinant Proteins, Biotechnology, Bentonite, biology.protein, Tobacco mosaic virus, Plant Lectins, business, Research Article

Abstract

Background Griffithsin is a broad spectrum antiviral lectin that inhibits viral entry and maturation processes through binding clusters of oligomannose glycans on viral envelope glycoproteins. An efficient, scaleable manufacturing process for griffithsin active pharmaceutical ingredient (API) is essential for particularly cost-sensitive products such as griffithsin -based topical microbicides for HIV-1 prevention in resource poor settings. Our previously published purification method used ceramic filtration followed by two chromatography steps, resulting in a protein recovery of 30%. Our objective was to develop a scalable purification method for griffithsin expressed in Nicotiana benthamiana plants that would increase yield, reduce production costs, and simplify manufacturing techniques. Considering the future need to transfer griffithsin manufacturing technology to resource poor areas, we chose to focus modifying the purification process, paying particular attention to introducing simple, low-cost, and scalable procedures such as use of temperature, pH, ion concentration, and filtration to enhance product recovery. Results We achieved >99% pure griffithsin API by generating the initial green juice extract in pH 4 buffer, heating the extract to 55°C, incubating overnight with a bentonite MgCl2 mixture, and final purification with Capto™ multimodal chromatography. Griffithsin extracted with this protocol maintains activity comparable to griffithsin purified by the previously published method and we are able to recover a substantially higher yield: 88 ± 5% of griffithsin from the initial extract. The method was scaled to produce gram quantities of griffithsin with high yields, low endotoxin levels, and low purification costs maintained. Conclusions The methodology developed to purify griffithsin introduces and develops multiple tools for purification of recombinant proteins from plants at an industrial scale. These tools allow for robust cost-effective production and purification of griffithsin. The methodology can be readily scaled to the bench top or industry and process components can be used for purification of additional proteins based on biophysical characteristics.