Effect of conditioned medium factors on productivity and cell physiology in Trichoplusia ni insect cell cultures.

The influence of conditioned medium (CM) on cell physiology and recombinant protein production in Trichoplusia ni insect cells (T. ni, BTI-Tn-5B1-4) has been investigated. Cell cycle analysis showed that a high proportion of the cell population (80-90%) was in G1 during the whole culture, indicating that the S and G2/M phases are short relative to the G1 phase. Directly after inoculation, a rapid decrease of the S-phase population occurred, which could be observed as a lag-phase. The following increase in the number of cells in S occurred after 7 h of culture for cells in fresh medium, whereas for cells with the addition of CM it occurred at an earlier time point (5 h) and these cells had therefore a shorter lag-phase. The initial changes in the S-phase population were also affected by the inoculum cell density, as higher seeding cell densities resulted in a more rapid increase in the S-phase population after inoculation. These changes in cell cycle distribution were reflected in the cell size, and the CM-cells were smaller than the cells in fresh medium. Recombinant protein production in T. ni cells was improved by the addition of CM. The specific productivity was increased by 30% compared to cells in fresh medium. This beneficial effect was seen between 20 and 72 h of culture. In contrast, the highest specific productivity was obtained already at 7 h for the cells in fresh medium and then decreased rapidly. The total product concentration was around 30% higher in the culture with CM compared to the culture in fresh medium, and the maximum product concentration was obtained on day 2 compared to day 3 for the cells in fresh medium. Our results indicate that the positive effect on productivity by CM is related to its growth-promoting effect, suggesting that the proliferation potential of the culture determines the productivity.

Effects of conditioned medium factors and passage number on Sf9 cell physiology and productivity.

The effects of conditioned medium (CM) and passage number on Spodoptera frugiperda Sf9 cell physiology and productivity have been studied. Low passage (LP) cells at passages 20-45 were compared to high passage (HP) cells at passages >100. Addition of 20% CM or 10 kDa filtrated CM to LP cells promoted growth. LP cells passed a switch in growth kinetics, characterized by a shorter lag phase and a higher growth rate, after 30-40 passages. After this point, CM lost its stimulating effect on proliferation. HP cells displayed a still shorter lag phase and reached the maximum cell density 24-48 earlier than LP cells. HP cells also exhibited higher specific productivity of recombinant protein compared to LP cells, when infected with baculovirus during the initial 48 h of culture. The specific productivity of LP cells was decreased by 30-50% by addition of 20% CM or 10 kDa filtrated CM, whereas addition of CM to cells having passed the switch in growth kinetics had no negative effect on productivity. Cell cycle analysis showed that a large proportion of HP cells, >60%, was transiently arrested in G2/M after inoculation. In LP cultures this proportion was lower, 40-45%, and addition of CM decreased the arrested population further. This correlated to the cell size, the HP cells being the largest: HP cells > LP > LP + 20% CM > LP + 20% 10 kDa filtrated CM. Since the degree of synchronization in G2/M correlated to the productivity, yeastolate limitation was used to achieve 85% G2/M synchronized cells. In this culture the specific productivity was maintained during a prolonged production phase and a 69% higher volumetric yield was obtained. The results suggest that a decreasing degree of synchronization during the course of culture partly explains the cell-density-dependent drop in productivity in Sf9 cells.

Antimicrobial activity of conditioned medium fractions from Spodoptera frugiperda Sf9 and Trichoplusia ni Hi5 insect cells.

Concentrated conditioned medium (CM) fractions from Spodoptera frugiperda Sf9 and Trichoplusia ni cells, eluting from a gel filtration column at around 10 kDa, were found to exhibit strong antibacterial activity against Bacillus megaterium and Escherichia coli. The B. megaterium cells incubated in the CM fraction from Sf9 cells rapidly lost viability: after 8 min the viability had decreased to 0.7%, as compared with the control. Addition of the CM fraction to E. coli cells resulted in a less drastic drop in viability: 65% viability was lost after 60 min of incubation. Further, exposure to the CM fraction caused a substantial leakage of intracellular proteins, as demonstrated by SDS-PAGE analysis. Cell lysis was confirmed by optical density measurements, microscopic investigations and flow cytometry. B. megaterium exposed to a CM fraction from T. ni cells lost 97% of their viability in about 40 min. Ubiquitin, thioredoxin and cyclophilin were identified in the antibacterial fraction from Sf9 cells by mass spectrometry and N-terminal amino acid sequencing. Other proteins in the fraction gave no matches in a database search. Since ubiquitin was shown not to cause the antimicrobial effect and thioredoxin and cyclophilin were likely not involved, the responsible agent may be an unknown protein, not yet registered in databases. The antimicrobial effect of the CM fraction from T. ni cells most probably comes from a lysozyme precursor protein.

The three-dimensional structures of antagonistic and agonistic forms of the glucocorticoid receptor ligand-binding domain: RU-486 induces a transconformation that leads to active antagonism.

Here we describe the three-dimensional crystal structures of human glucocorticoid receptor ligand-binding domain (GR-LBD) in complex with the antagonist RU-486 at 2.3 A resolution and with the agonist dexamethasone ligand together with a coactivator peptide at 2.8 A. The RU-486 structure was solved in several different crystal forms, two with helix 12 intact (GR1 and GR3) and one with a protease-digested C terminus (GR2). In GR1, part of helix 12 is in a position that covers the co-activator pocket, whereas in the GR3, domain swapping is seen between the crystallographically identical subunits in the GR dimer. An arm consisting of the end of helix 11 and beyond stretches out from one molecule, and helix 12 binds to the other LBD, partly blocking the coactivator pocket of that molecule. This type of GR-LBD dimer has not been described before but might be an artifact from crystallization. Furthermore, the subunits of the GR3 dimers are covalently connected via a disulfide bond between the Cys-736 residues in the two molecules. All three RU-486 GR-LBD structures show that GR has a very flexible region between the end of helix 11 and the end of helix 12.