Mycoplasmal infection of insect cell cultures

Routine Maintenance and Storage of Lepidopteran Insect Cell Lines and Baculoviruses

The various methods for maintaining (i.e., subculturing, splitting, or passaging) established lepidopteran cell lines are described. Three procedures are presented that are appropriate for different cell lines dependent upon the growth characteristics (in particular, cell attachment properties) of the cells of interest. In addition to the routine maintenance of cells in active culture, methods are also described for both short-term (low temperature) and long-term (frozen in liquid nitrogen) storage of cell lines, as well as quality control procedures for the cultures. Methods for storing baculoviruses for use in cell cultures and issues of concern when using cell cultures for their production and study are also described.

Safety aspects of insect cell culture

CONCLUSIONS

The hazards posed to the environment by the accidental release of baculovirus expression vectors can be put into perspective by the results obtained from experiments in which AcNPV was released deliberately into the field (Bishop et al., 1992). Polyhedrin positive viruses will persist in soil and on leaf surfaces for periods comprising weeks and months. However, polyhedrin negative viruses (similar to those used as expression vectors) do not survive in similar situations. In consequence, accidental release of baculovirus expression vectors poses negligible hazard. The risk of such a release will largely depend on the skill of the operators. This does not take into account the hazard posed by the recombinant product which is being made by the virus-infected insect cell. Synthesis of a mammalian-specific toxin, of course, would require particularly careful manipulation of the virus-infected cell culture.The fact that insect cell lines represent an undefined risk, in terms of carriage of adventitious agents means that their containment should be maintained at a minimum of the European containment level 2. Where the tissue of origin has a high risk of infection with human pathogens or where cells may have been used in a virus culture laboratory then appropriate testing is advisable. Careful risk assessment respecting the scale of work and whole procedures (in addition to individual assessment of agents and reagents) will ensure safe working conditions for laboratory staff. If applied properly safety procedures will also succeed in encouraging clean, efficient and well documented work procedures which are synonymous with the economical use of time and resources and good science.

Biological enrichment of Mycoplasma agents by cocultivation with permissive cell cultures

In this study, we describe our results on the evaluation of the ability of different permissive mammalian cell lines to support the biological enrichment of mycoplasma species known to be bacterial contaminants of cell substrates. The study showed that this approach is able to significantly improve the efficiency of mycoplasma detection based on nucleic acid testing or biochemical technologies (e.g., MycoAlert mycoplasma detection). Of 10 different cell lines (Vero, MDBK, HEK-293, Hep-G2, CV-1, EBTr, WI-38, R9ab, MDCK, and High Five) used in the study, only MDCK cell culture was found to support the efficient growth of all the tested mycoplasmas (Mycoplasma arginini, M. bovis, M. fermentans, M. gallinaceum, M. gallisepticum, M. synoviae, M. hominis, M. hyorhinis, M. orale, M. salivarium, and Acholeplasma laidlawii) known to be most frequently associated with contamination of cell substrates and cell lines in research laboratories or manufacturing facilities. The infection of MDCK cells with serial dilutions of each mycoplasma species demonstrated that these common cell line contaminants can be detected reliably after 7-day enrichment in MDCK cell culture at contamination levels of 0.05 to 0.25 CFU/ml. The High Five insect cell line was also found to be able to support the efficient growth of most mycoplasma species tested, except for M. hyorhinis strain DBS1050. However, mycoplasma growth in insect cell culture was demonstrated to be temperature dependent, and the most efficient growth was observed when the incubation temperature was increased from 28 degrees C to between 35 and 37 degrees C. We believe that this type of mycoplasma enrichment is one of the most promising approaches for improving the purity and safety testing of cell substrates and other cell-derived biologics and pharmaceuticals.

Routine maintenance and storage of lepidopteran insect cell lines and baculoviruses

The various methods for maintaining (a.k.a., subculturing, splitting, or passaging) established lepidopteran cell lines are described. Three procedures are presented that are appropriate for different cell lines dependent upon the growth characteristics (in particular, cell attachment properties) of the cells of interest. In addition to the routine maintenance of cells in active culture, methods are also described for both short (low temperature) and long-term (frozen in liquid nitrogen) storage of cell lines, as well as quality control procedures for the cultures. Methods for storing baculoviruses for use in cell cultures and issues of concern when using cell cultures for their production and study are also described.

Insect cell cultures in the study of attachment and pathogenicity of spiroplasmas and mycoplasmas

The insect cell lines Dm-1 (Drosophila melanogaster), AS-2 (Aceratagallia sanguinolenta) and AC-20 (Agallia constricta) were infected with spiroplasmas, mycoplasmas and Acholeplasma laidlawii. In Dm-1 cultures maintained at 25 degrees C in M1A medium, all strains multiplied except M. hyorhinis and the uncultivable sex-ratio organism. Spiroplasma citri R8A2, S. floricola BNR-1 and OBMG, S. apis PPS-1 and the strains BC-3, corn stunt spiroplasma (CSS) and 277F produced cytopathogenic effects (CPE), whereas S. mirum SMCA, M. orale, M. arginini and A. laidlawii did not. Cytadsorption was found with the cultivable spiroplasmas and A. laidlawii. At 30 degrees C SMCA, M. orale, M. arginini and A. laidlawii killed the Dm-1 cultures. M. hyorhinis grew without any CPE. In AS-2 and AC-20 cultures grown at 28 degrees C in LB medium, R8A2, B88, 277F, BNR-1 and PPS-1 multiplied and reached titres of 2 X 10(8) to 4 X 10(9) CFU/ml. They produced CPE leading to culture death. CSS did not grow. R8A2 reached higher titres in AS-2 cultures than in fresh LB medium. This stimulating factor was studied by means of conditioned medium. All 6 spiroplasmas cytadsorbed to AS-2 and AC-20 cells. B88 and 277F adsorbed heavily, while the other 4 strains adsorbed only slightly. Fluorescent DNA staining with "Hoechst 33258" revealed the presence of non-helical forms inside the cells.