F E A T U R E S
E L K E F L E C K E N S T E I N A N D H A N S G . D R E X L E R *
F r o m t h e G e r m a n C o l l e c t i o n o f M i c r o o r g a n i s m s a n d C e l l C u l t u r e sD e p a r t m e n t o f H u m a n a n d A n i m a l C e l l C u l t u r e s , B r a u n s c h w e i g , G e r m a n y* Corresponding author: Email: HDR@GBF_Braunschweig.de
Mycoplasma contamination remains a
These antibiotic treatments had a high efficiency of permanent cure: MRA 64%,
ciprofloxacin 77%, BM-Cyclin 84%. Resistance to mycoplasma eradication was observed
significant impediment to the culture of
in some cell cultures: BM-Cyclin 5%, ciprofloxacin 14%, MRA 22%. Nearly all resistantcontaminants that could be identified belonged to the species M. arginini and M. orale.eukaryotic cells. For certain cultures,
Detrimental effects of the antibiotics were seen in form of culture death caused by cyto-toxicity (in 9-13% of the cultures). Alterations of the cellular phenotypic features or selec-
attempts to eliminate the infection are
tive clonal outgrowth might represent further untoward side-effects of exposure to theseantibiotics.
feasible alternatives to the normally recom-
Overall, antibiotic decontamination of mycoplasmas is an efficient, inexpensive, reli-
able, and simple method: 269/366 (73%) chronically and heavily contaminated cultures
mended disposal of the contaminated culture.
were cured, while 97/366 (27%) cultures could not be cleansed and were either lost orremained infected. It is concluded that eukaryotic cell cultures containing mycoplasmas
Here three antibiotic regimens for mycoplas-
are amenable to antibiotic treatment and that a cure rate of about three-quarters is a reasonable expectation. mal decontamination were compared in a Introduction large panel of naturally infected cultures: (i) a
Mycoplasma contamination of cell culture systems continues to present major prob-
lems for basic research as well as for the manufacturing of bioproducts (1,2). Mycoplasmas
one-week treatment with the fluoroquinolone
affect virtually every parameter within the cell culture system (3). As mycoplasmal infec-tion of cell cultures might often persist for long periods of time without apparent cell dam-
Mycoplasma Removal Agent (MRA), (ii) a two-
age (4), it is important to use one or several efficient detection methods (1,3,5,6). Mycoplasma-positive cell cultures are themselves the major source of infection (7). Thus,
week treatment with the fluoroquinolone
it was generally recommended that positive cultures should be discarded and replaced inorder to prevent the spreading of the contaminant (2,3). If the culture is considered irre-
ciprofloxacin, and (iii) three rounds of a
placeable, it is possible to effectively eliminate the contaminant(s). Therefore, treatment ofmycoplasma-positive cell cultures has become a practicable option (4). sequential one-week treatment with BM-
A number of methods have been employed in recent years with mixed results.
Procedures for elimination have included use of antibiotics, complement, and heterologous
Cyclin, which contains a pleuromutilin and a
antisera; passage in nude mice; exposure to mouse macrophages; treatment with trypsin, S-bromouracil, and Hoechst 33258; culture in soft agar; and several other techniques
tetracycline derivative.
B I O C H E M I C A ■ N O . 1 [ 1 9 9 6 ]
F E A T U R E S
(2–4,8–16). However, few of these tech-
niques produced satisfactory and consistent
results. It became apparent that elimination
biotics. None of the cell lines were deliber-
(Boehringer Mannheim) using specific anti-
of mycoplasmas from infected cell cultures
represented chronically contaminated cul-
Mycoplasma elimination
unsuccessful exercise posing the risk of sec-
tures. Cultures were passaged according to
ondary infection to other cultures (4). Mycoplasma detection
the manufacturer’s instructions, using
tamination should be simple, have minimal
effect on cell growth, and not lead to loss of
mycoplasmas with standard tests (5,6).
BM-Cyclin 2 for four days; this alternating
Thus, the cultures were tested before and
cycle was performed three times. The final
simple technique appears to be antibiotic
rescence staining and the microbiological
treatment. Here, in particular, it is impor-
broth-agar colony assay. Most treated cul-
tetracycline derivative) were 10 g/ml and
tant to closely monitor effectiveness of the
5 g/ml, respectively. Ciprofloxacin was
used for 14 days at 10 g/ml. Mycoplasma
tion and eukaryotic cytotoxicity (2). It has
an ELISA with specific polyclonal antisera
(e.g., Mycoplasma Detection Kit, Boehringer
medium for 8 days at a final concentration
approach is to identify the contaminant by
species and determine the antibiotic sensi-
tivity of the infectant; then the mycoplasma-
antibiotic-free medium (also without peni-
positive eukaryotic cell culture is exposed
using a mix of outer and inner primers (e.g.,
to several consecutive treatments with an
antibiotic cocktail (17). However, for most
Mannheim, Germany). All assays were weeks prior to testing for residual
scientists, cell culturing is only the means to
previously described in detail (5,6,24).
patience, or interest required for cumber-some trials. Therefore, new products to be
marketed specifically for these purposes.
these studies examined only limited num-bers of treated cultures; furthermore, few
comparative data are available. We sum-marize here our experience with antibiotic
large number of positive cell cultures. Materials and Methods Cell culture
formed in cell cultures from cell lines that
Outcome of treatment of mycoplasma-positive cell cultures with either BM-Cyclin, ciprofloxacin, or MRA. According to the reagent manufacturers’ instructions, cells
were originally submitted to the Deutsche
were treated for 1 week with MRA, for 2 weeks with ciprofloxacin, or for 3 weeks with BM-Cyclin, and then cultured in antibiotic-free medium (also without penicillin or streptomycin) for at least another 2 weeks prior to testing for residual mycoplasma contamination. All cultures were tested with DAPI DNA fluorescence staining and a broth-agar colony assay; 80% of the cultures were also investigated with a
that were found to contain mycoplasmas. third method, either DNA/RNA hybridization (Mycoplasma Detection Kit), ELISA, monoclonal antibody CCM-2, or a polymerase chain reaction (Mycoplasma PCR ELISA). The results are shown as
Cells were cultured under standard condi-
percent of cultures that were either cured or that remained mycoplasma contaminated (due to resis- tance) or that were lost during the treatment period (due to cytotoxicity). The number of cultures ana- lyzed in each category is indicated (N).
B I O C H E M I C A ■ N O . 1 [ 1 9 9 6 ]
F E A T U R E S Results and Discussion
cell lines. For such low-level persistent
In this study we set out to determine (i)
infection, the introduction of the PCR tech-
suggested that it might be preferable to per-
form appropriate antibiotic sensitivity tests
lines could be efficiently cleansed using
the battery of available mycoplasma detec-
antibiotic treatment, and (ii) whether the
unnecessary on a routine basis as they are
plasmas over long-term culturing, (i.e.,
type of outcome of the antibiotic treatment
was loss of the culture, which occurred in
eradicated or only suppressed). The results
ment, is illustrated by the percentages of
successful outcomes: 64–84% of the cul-
effects of the reagents. Although previous
studies on mycoplasma-negative cell lines
Figure 1; mycoplasma infection was elimi-
did not provide any evidence of antibiotic
the literature shows several similar results
cytotoxicity on the eukaryotic cells (18), the
77%, and by BM-Cyclin in 84% of the situation is certainly different in chronically
cultures studied. Furthermore, the decon-
and heavily contaminated cultures, such as
With regard to the last point, the possi-
tamination was total and permanent, as 14
the ones treated here, because of the ble adverse effects of the treatment on the
days after treatment, no mycoplasmas were
cell culture, three unwanted developments
detected in cultures deemed to be cured.
reduced viability. Ciprofloxacin has been
must be considered: (i) cytotoxicity; (ii)
reported to have an effect on intracellularly
loss of special cellular characteristics; and
(iii) clonal selection of treated cells. A
cultures remained unequivocally negative.
however, in that study, ciprofloxacin was
cytotoxic to all 9 cell lines treated (23).
used at significantly higher concentrations
of the three different regimens are evalu-
(14–15 times the concentration used here)
plasma immediately at the end of the treat-
ated: (i) There was no selection on the (27). Other reports described inhibitory
ment period, all cultures were ultimately
cultures that were treated; attempts to elim-
effects of ciprofloxacin on hematopoietic
lost due to poor growth and extensive cell
cell growth (28–30). The long-term cocul-
death (23). These latter data stand in clear
positive cultures submitted to the cell bank
contrast to the 11% culture death seen in
from 1990–1995, using at least one of the
might lead to a sort of symbiosis whereby
our series (Figure 1). In another report, no
an abrupt termination might be detrimental
to the cells. Further studies are required to
Cyclin treatment of 11 cell lines (22).
ments in parallel (see below); (ii) All elaborate the reason(s) why some cell lines
cultures were treated under the same con-
are more susceptible to the cytotoxic effects
loss of cell culture in two series of 9 and 26
ditions, (e.g., incubation, concentration of
of the antibiotics than others treated at the
antibiotics, treatment protocol). Thus, our
lished on cytotoxic effects of MRA during
apoptosis might also play some as yet unde-
specific cellular characteristics and/or acci-
dental clonal selection have not yet been
floxacin or MRA were similar (Figure 1).
method should be simple, efficient, and not
studied systematically in cultures exposed
Although the species of contaminants were
have any adverse effects on the cell culture
not identified in all cases, our data demon-
(4). The simplicity of antibiotic eradication
analysis is, however, urgently needed since
strate clearly that M. arginini and M. orale
account for the vast majority of resistant
lines were cultured under the same condi-
tions during the treatment period as prior
cross-resistance to ciprofloxacin and MRA;
to decontamination, only the reagents were
of the consequences of the unsolicited rou-
these cell lines contained mostly M. arginini
added to the culture media. We noted that
tine application of anti-mycoplasma anti-
or M. orale. This cross-resistance is not sur-
it is advantageous to increase the FCS con-
biotics in the daily cell culture work: the
prising because ciprofloxacin and MRA are
centration and to incubate the cells at high-
emergence of resistant mycoplasma strains
both fluoroquinolones of similar structure
er densities. However, it must be pointed
can surely be expected, and alterations of
(25). It should be added that consideration
out that antibiotic mycoplasma decontami-
the eukaryotic phenotype in the long term
should be given to the possibility that a low
are quite possible as well. It is further
level infection could persist undetected by
suming: the duration of the treatment plus
standard methods. The possibility of recur-
detection methods (6) at regular intervals
in order to examine cleared cultures for
B I O C H E M I C A ■ N O . 1 [ 1 9 9 6 ]
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31995L0046 Directiva 95/46/CE del Parlamento Europeo y del Consejo, de 24 de octubre de 1995, relativa a la protección de las personas físicas en lo que respecta al tratamiento de datos personales y a la libre circulación de estos datos Diario Oficial n° L 281 de 23/11/1995 p. 0031 - 0050 DIRECTIVA 95/46/CE DEL PARLAMENTO EUROPEO Y DEL CONSEJOrelativa a la protección de las p
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