Hybanthus enneaspermus

2.5. Scale up of H. enneaspermus View in CoL cell suspension culture using a rocking motion bioreactor

Rocking motion bioreactors utilizing single-use culture bags provide a convenient and modern approach for scaling up cyclotide production under controlled conditions, without the risks of cross contamination. Given the sustained and relatively high levels of cyO2 accumulation in H. enneaspermus compared to O. affinis in our smaller scale cultures, H. enneaspermus suspension cells were chosen to assess their ability to produce cyO 2 in a rocking motion bioreactor at 5 L final culture volume. A fed batch strategy was employed with 200 mL high density H. enneaspermus culture grown in shake flasks used to first inoculate 800 mL of fresh media in a disposable reactor bag. After 360 h this 1 L culture reached a density of 50% packed cell volume (PCV), at which point a further 4 L of fresh medium was added to achieve the final culture volume of 5 L. Culture conditions (dissolved oxygen %, pH, rocking speed and angle were monitored ( Fig. S4 View Fig ). In total 22 g DW of cells were produced at the end of the 480-h culture, which yielded 10.3 mg of pure cyO2 (0.46 mg /g DW). Purified cyO2 from suspension cells was shown via NMR to be identical to plant leaf derived cyO2 ( Fig. 6A View Fig ) and was demonstrated to be seven-fold more cytotoxic to insect Sf9 cells than chemosynthetically produced kB1 with a cytotoxic concentration (CC) of 0.27 ± 0.02 μM compared to 1.91 ± 0.02 μM respectively ( Fig. 6B View Fig ). Together, the establishment and scale up of H. enneaspermus suspension cells shows the feasibility of producing cyO 2 in a bioreactor, a bracelet-type cyclotide that is recalcitrant to production by chemosynthetic methods.