Efficiency of Plasmocin™ on various mammalian cell lines infected by mollicutes in comparison with commonly used antibiotics in cell culture: a local experience

Mycoplasma contamination is a deleterious event for cell culture laboratories. Plasmocin™ is used to prevent and eradicate mycoplasma infections from cell. In this study, 80 different mammalian cell lines from various sources; human, monkey, mice, hamster and rat were used to study and evaluate plasmocin™ efficiency and compare it to commonly used antibiotics such as BM-cyclin, ciprofloxacin and mycoplasma removal agent (MRA). It was shown that mycoplasma infections were eradicated by plasmocin™, BM-cyclin, ciprofloxacin and MRA in 65%, 66.25%, 20%, and 31.25%, respectively, of infected cell cultures. However, re-infection with mycoplasmas after the period of 4 months occurred in 10–80% of the studied cell lines. Cell cytotoxicity and culture death was observed in 25, 17.5 and 10% of the treated cells, for plasmocin™, BM-cyclin and MRA, respectively. In this study, Plasmocin™ showed strong ability to eradicate mollicutes from our cell lines with minimal percentage of regrowth. However, due to its high cell cytotoxicity it should be used with caution especially when dealing with expensive or hard-to-obtain cell lines. Amongst the antibiotics tested, BM-cyclin was shown to remove mycoplasma with the highest efficiency.     

Elimination of mycoplasmas from cell cultures utilizing hyperimmune sera

Eighteen cell lines contaminated with various mycoplasmas have been treated with hyperimmune sera and mycoplasmas have been eradicated from all. After treatment the cell lines have been observed for a least one year and they are still free from mycoplasma contamination as ascertained by four independent mycoplasma detection assays. The hyperimmune sera used were of high titer, type-specific and growth-inhibiting. These sera were produced by immunization of rabbits with purified membranes from Mycoplasma orale, M. arginini, M. hominis, M. fermentans, M. hyorhinis and Acholeplasma laidlawii. In addition to elimination of mycoplasmas from cell cultures we have successfully used these sera for detection and typing of mycoplasma contamination in cell cultures.     

Induction of interleukins by mycoplasma in culture of human mononuclear leukocytes

Mycoplasma shows a variety of effects on immune system, including the activation of macrophage, the increase in T cell cytotoxicity, and the enhancement of the proliferation and maturation of B cells, etc. As it is well known that many cytokines regulate the immune system, it is interesting to examine whether or not human peripheral blood mononuclear cells (PBMC) produce interleukin (IL) in response to mycoplasmas. In the present study, human PMBC were incubated with 7 species of mycoplasmas for 48 hours, and IL-1 beta, IL-2 and IL-6 activities in the supernatants were determined by ELISA. All the species of mycoplasmas were able to induce IL-1 beta and IL-6, although IL-2 was induced only by M. pneumoniae. These results suggest that the influence of mycoplasma infection on immune system may be partly due to the interleukins induced by mycoplasmas.     

Effects of mycoplasma contamination on phenotypic expression of mitochondrial mutants in human cells.

HeLa cells sensitive to the mitochondrial protein synthesis inhibitors erythromycin (ERY) and chloramphenicol (CAP) and HeLa variants resistant to the effects of these drugs were purposefully infected with drug-sensitive and -resistant mycoplasma strains. Mycoplasma hyorhinis and the ERY-resistant strain of Mycoplasma orale, MO-ERYr, did not influence the growth of HeLa and ERY-resistant ERY2301 cells in the presence or absence of ERY. M. hyorhinis also did not affect the growth of HeLa and CAP-resistant Cap-2 cells in the presence or absence of CAP. However, both HeLa and Cap-2 cells infected with the CAP-resistant strain of M. hyorhinis, MH-CAPr, were more sensitive to the cytotoxic effect of CAP. This may be due to the glucose dependence of the cells, which was compromised by the increased utilization of glucose by MH-CAPr in these infected cell cultures. In vitro protein synthesis by isolated mitochondria was significantly altered by mycoplasma infection of the various cell lines. A substantial number of mycoplasmas copurified with the mitochondria, resulting in up to a sevenfold increase in the incorporation of [3H]leucine into the trichloroacetic acid-insoluble material. More importantly, the apparent drug sensitivity or resistance of mitochondrial preparations from mycoplasma-infected cells reflected the drug sensitivity or resistance of the contaminating mycoplasmas. These results illustrate the hazards in interpreting mitochondrial protein synthesis data derived from mycoplasma-infected cell lines, particularly putative mitochondrially encoded mutants resistant to inhibitors of mitochondrial protein synthesis.     

Evidence that mycoplasmas, gram-negative bacteria, and certain gram-positive bacteria share a similar protein antigen.

It was demonstrated that mycoplasmas, gram-negative bacteria, and certain gram-positive bacteria share a similar protein antigen with a molecular weight ranging from 42,000 to 48,000. Western blotting (immunoblotting) with an antibody specific to a 43-kDa membrane protein of Mycoplasma fermentans showed the existence of this protein antigen in all Mycoplasma spp. tested (14 species), Acholeplasma laidlawii (1 strain), and gram-negative bacteria (8 species) but only in Staphylococcus aureus of four gram-positive species tested. Neither Ureaplasma urealyticum nor mammalian cell cultures showed any cross-reactions with this antibody. These proteins were found in both cytoplasmic and membrane fractions of mycoplasma cells but were not exposed on the surface of mycoplasmal or bacterial cells.     

Adenosine triphosphatase activity of mycoplasma membranes

Rottem, Shlomo (Hebrew University, Jerusalem, Israel), and Shmuel Razin. Adenosine triphosphatase activity of mycoplasma membranes. J. Bacteriol. 92:714-722. 1966.-Adenosine triphosphatase activity of Mycoplasma laidlawii, M. gallisepticum, and Mycoplasma sp. strain 14 was confined to the cell membrane. The enzymatic activity was dependent on magnesium, but was not activated by sodium and potassium. Ouabain did not inhibit the adenosine triphosphatase activity of the mycoplasmas, and did not interfere with the active accumulation of potassium by M. laidlawii cells. Sulfhydryl-blocking reagents and fluoride inhibited the enzymatic activity, whereas 2,4-dinitrophenol was without any effect. Membranes of M. laidlawii hydrolyzed other nucleotide triphosphates and adenosine diphosphate (ADP), but at a lower rate than adenosine triphosphate (ATP). Nucleoside-2'-(3')-phosphates, ribose-5-phosphate, glucose-6-phosphate, and pyrophosphate were not hydrolyzed by the membrane preparations. It seems that the enzyme(s) involved in ATP hydrolysis by M. laidlawii membranes is strongly bound to the membrane subunits, which would account for the failure to purify the enzyme by protein fractionation techniques. The adenosine triphosphatase activity of mycoplasma membranes resembles in its properties that of similar enzymes studied in bacteria. The mycoplasma enzyme(s) seems to differ from the adenosine triphosphatase associated with ion transport in mammalian cell membranes and from mitochondrial adenosine triphosphatase.     

Detection and identification of Mycoplasma infections by DNA hybridization

Infection of cell cultures by mycoplasmas can be detected by hybridization of the DNA of suspected cell cultures with recombinant plasmids containing fragments of the mycoplasma DNA. The test is very sensitive and allows detection of as little as 1 ng of mycoplasmal DNA, roughly equivalent to the DNA amount of 10(6) mycoplasmas. This approach turns out to be effective for detection and identification of mycoplasmas in clinical material, plant and insect tissues. A set of DNA probes for detection of mycoplasmas infecting cell cultures by dot hybridization has been constructed. This set consists of specific DNA probes and universal DNA probe. Recombinant plasmids, pAl32, pMa13, pMh9, containing specific DNA fragments of Acholeplasma-laidlawii, Mycoplasma arginini, Mycoplasma hominis (the prevalent mycoplasma contaminants of home cell cultures) are species-specific DNA probes. Recombinant plasmid pMg16 containing rRNA genes of Mycoplasma gallisepticum is the universal DNA probe for detection of any mycoplasma (or any prokaryote) contaminations. These two classes of DNA probes may be considered as complementing each other. These 32P labeled probes do not hybridize with eukaryotic DNA. The set of DNA probes allows not only to detect infection of cell cultures by mycoplasmas but also to identify the species of mycoplasmas and to evaluate the multiplicity of mycoplasma infection.     

In situ detection of mycoplasma contamination in cell cultures by fluorescent Hoechst 33258 stain

A simple, fast, and easily reproducible routine laboratory technique for detecting mycoplasma contamination in cell cultures is reported. Cells grown on a coverslip are fixed directly with Carnoy's, air-dried, stained with DNA-specific fluorescent Hoechst 33258, and examined microscopically. All cultures that were infected with mycoplasmas had readily discernible, small, morphologically uniform, bright fluorescent bodies in the extranuclear and intercellular space in contrast to the non-contaminated control cultures in which the extra-nuclear background appeared uniformly dark. To probe the degree of sensitivity to detect mycoplasmas, control cultures were infected with aliquots from serially diluted cells or media collected from Mycoplasma hyorhinus infected cultures. The lowest infection rate (0.40% by sampling 1 000 cells in average per culture 4–24 h after infection) scored presently, however, can easily be lowered by increasing sample size since a cell infected with even one mycoplasma can be discerned. These mycoplasmas resisted centrifugation at 2 500 rpm for 30 min and easily filtered through 0.22 μm pore-size filter membrane. Amazingly infection rate of 0.63% scored from 24 h post-infection incubation attained 100% contamination with several hundreds of mycoplasmas per host cell within 120 h.     

Detection of mycoplasmas infecting cell cultures by DNA hybridization

Infection of cell cultures by mycoplasmas can be detected and the mycoplasma identified by Southern blot hybridization of the Eco RI-digested DNA of the suspected cell cultures with a nick-translated probe consisting of cloned ribosomal RNA genes of Mycoplasma capricolum. The probe does not hybridize with eukaryotic DNA. The hybridization pattern with mycoplasmal DNA is species specific, enabling the identification of the four most prevalent mycoplasma contaminants, Mycoplasma orale, Mycoplasma hyorhinis, Mycoplasma arginini, and Acholeplasma laidlawii. The test is also very sensitive and can detect as little as 1 ng of mycoplasmal DNA, roughly equivalent to the DNA content of 10(5) mycoplasmas.     

Mycoplasma—virus contacts,budding and scars remaining in the membranes ofAcholeplasma laidlawii and its virus

Various stages of virus and mycoplasma budding indicated that both virus and, most probably some mycoplasma progeny developed by budding. Besides this alternative, binary fission was the mode of mycoplasma reproduction. Mycoplasma—virus and mycoplasma—mycoplasma connections by stems were observed. Circular scars, 40–80 nm in diameter, often in groups, were left in the membrane of mycoplasmas by the budding bodies. Cytoplasmic structures seen in cross-fracture are presented. A relatively small number of globular virus-like bodies, not identical with MV-Lg-L 172, were observed budding from mycoplasma cells in the non-infected host culture.     

Entry and intracellular location of Mycoplasma hominis in Trichomonas vaginalis

The parasite Trichomonas vaginalis causes one of the most common non-viral sexually transmitted infections in humans. The coexistence of different sexually transmitted diseases in the same individual is very common, such as vaginal infections by T. vaginalis in association with Mycoplasma fermentans or Mycoplasma hominis. However, the consequences and behavior of mycoplasma during trichomonad infections are virtually unknown. This study was undertaken to elucidate whether mycoplasmas enter and leave trichomonad cells and if so how. M. hominis was analyzed in different trichomonad isolates and the process of internalization and the pathway within the parasite was studied. Parasites naturally and experimentally infected with mycoplasmas were used and transmission electron microscopy, cytochemistry and PCR analyses were performed. The results show that: (1) M. hominis enters T. vaginalis cells by endocytosis; (2) some mycoplasmas use a terminal polar tip as anchor to the trichomonad plasma membrane; (3) some trichomonad isolates are able to digest mycoplasmas, mainly when the trichomonads are experimentally infected; (4) some fresh virulent isolates are able to maintain mycoplasmas as cohabitants in the cell’s interior; (5) some mycoplasmas are able to escape from the vacuole to the trichomonad cytosol, and trichomonad plasma membrane budding suggested that mycoplasmas could leave the parasite cell.     

Metal-induced extracellular protein excretion in Arthrobacter aurescens

Abstract Mycoplasma contamination of cell cultures is a menace to diagnostic and research procedures. Rapid and reliable detection methods are, therefore, sorely needed. After comparing 16S rRNA sequences from those mycoplasmas that contaminate cell cultures, three different oligonucleotide probes were constructed. Two of these probes were designed to be group-specific and one to be species-specific. The three oligonucleotide probes were designed to cover all mycoplasmas commonly isolated from cell cultures. Contaminated cell lines could easily be detected by a direct filter hybridization assay in which the probes were incubated jointly. The assay proved to be rapid and sensitive with the possibility to perform and evaluate the mycoplasma testing within one working day.     

Mycoplasmal infections prevent apoptosis and induce malignant transformation of interleukin-3-dependent 32D hematopoietic cells

32D cells, a murine myeloid cell line, rapidly undergo apoptosis upon withdrawal of interleukin-3 (IL-3) supplement in culture. We found that 32D cells, if infected by several species of human mycoplasmas that rapidly activated NF-kappaB, would live and continue to grow in IL-3-depleted culture. Mycoplasma-infected cells showed no evidence of autocrine production of IL-3. Pyrrolidine dithiocarbamate (PDTC) blocked activation of NF-kappaB and led to prominent cell death. Heat-killed mycoplasmas or mycoplasmal membrane preparations alone could support continued growth of 32D cells in culture without IL-3 supplement for a substantial period of time. However, upon removal of heat-inactivated mycoplasmas, 32D cells quickly became apoptotic. In comparison, live Mycoplasma fermentans or M. penetrans infection for 4 to 5 weeks induced malignant transformation of 32D cells. Transformed 32D cells grew autonomously and no longer required support of growth-stimulating factors including IL-3 and mycoplasmas. The transformed 32D cells quickly formed tumors when injected into nude mice. Karyotyping showed that development of chromosomal changes and trisomy 19 was often associated with malignant transformation and tumorigenicity of 32D cells. Mycoplasmal infections apparently affected the fidelity of genomic transmission in cell division as well as checkpoints coordinating the progression of cell cycle events.     

Elimination of mycoplasmas from cell cultures and establishment of mycoplasma-free cell lines

Several antibiotics were examined for their potential to eliminate mycoplasmas from contaminated cell cultures. Acholeplasma laidlawii, Mycoplasma arginini, Mycoplasma hyorhinis and Mycoplasma orale were effectively eliminated from experimentally contaminated mouse fibroblasts and mink epithelial cells by the use of the antibiotics minocycline and tiamutin. An elimination procedure was established, which involved the consecutive treatment of the cultures over a period of 3 weeks, followed by cell cloning. This procedure was effective when applied to cell lines which had been contaminated with unidentified and partially non-cultivable strains of mycoplasmas.     

Mycoplasma hyorhinis and Mycoplasma fermentans induce cell apoptosis and changes in gene expression profiles of 32D cells

Infection of mycoplasmas has been linked to various human diseases including arthritis, pneumonia, infertility and cancer. While Mycoplasma hyorhinis and Mycoplasma fermentans have been detected in gastric adenocarcinomas, the mechanisms underlyine the pathogenesis are unknown. In this study, cell growth kinetics, Hoechst 33258 staining, DNA ladder assays, Western blotting analysis and cDNA microarray assays were performed to investigate the roles of M. hyorhinis and M. fermentans during infection of mammalian cells. Our data demonstrated that these mycoplasmas inhibid the growth of immortalised cell lines (32D and COS-7) ane tumor cell lines (HeLa and AGS). In addition, the infection of the 32D cell line with M. hyorhinis and M. fermentans induced compression of the nucleus, degradation of the cell genome and dysregulation of the expression of genes related to proliferation, apoptosis, tumorigenesis, signaling pathway and metabolism. Apoptosis related proteins Bcl-2, Bid and p53 were down-regulated, Fas was up-regulated and Bax was dysregulated in mycoplasma-infected 32D cells. Together, our data demonstrated that infection of mycoplasmas inhibitd cele growts through modification of gene expression profiles and post-translation modification of proliferation and apoptosis related proteins.     

Common sulfoglycolipid receptor for mycoplasmas involved in animal and human infertility

Sulfoglycolipids are ubiquitous components of the male germ cell membrane. Sulfogalactoglycerolipid (SGG) is restricted to mammalian cells and has recently been implicated in sperm/egg interactions. Mycoplasma infections have been implicated in infertility in a variety of species, including humans. Four such species-specific mycoplasmas, Ureaplasma urealyticum and Mycoplasma hominis (humans), Mycoplasma pulmonis (rodents), and Ureaplasma diversum (cattle) are not shown to specifically recognize SGG and the sphingolipid counterpart, sulfogalactosyl ceramide. This glycolipid receptor binding may relate to the reproductive pathogenesis of these organisms.     

Relationship of Mycoplasma pneumoniae to other human Mycoplasma species studied by gel diffusion

Taylor-Robinson, David (National Institute of Allergy and Infectious Diseases, Bethesda, Md.), Otakar Sobeslavsky, and Robert M. Chanock. Relationship of Mycoplasma pneumoniae to other human Mycoplasma species studied by gel diffusion. J. Bacteriol. 90:1432-1437. 1965.-Conditions are presented for the production of four lines of precipitate between Mycoplasma pneumoniae antigen and homologous hyperimmune rabbit serum in double diffusion in agar. The specificity of the reaction was shown by the fact that M. pneumoniae antigen did not react with antisera to the other human mycoplasma species, nor did M. pneumoniae antiserum produce lines with antigens prepared from the other human mycoplasmas. In addition, there was no reduction in the number or intensity of precipitation lines after absorption of M. pneumoniae antiserum with heterotypic mycoplasma antigens, or after absorption of heterotypic mycoplasma antisera with M. pneumoniae antigen. These findings indicate that, of the human mycoplasma species so far studied, M. pneumoniae is antigenically the most distinct.     

Permanent mycoplasma removal from tissue culture cells: A genetic approach

Mycoplasma contamination of tissue culture cells easily evades detection and, thus, represents a continous threat to cell biologists. In cases where infected cell can not simply be replaced, attempts have to be made to eradicate mycoplasma from the tissue culture cells. A variety of anti-microbial agents have been shown to be toxic to mycoplasma strains; however, cell associated mycoplasmas are often protected from antibiotics at concentrations shown to be effectivein vitro. Antibiotic concentrations high enough to be lethal to cell asso|ciated mycoplasmas frequently are also detrimental to the host cells, while moderately increased antibiotic levels tolerated by the host cells often lead to only temporary growth suppression and/or to the emergence of mycoplasma strains resistant even to high concentrations of the antibiotic applied. Here, a genetic approach for the elimination of mycoplasma from tissue culture cells that overcomes these limitations is described. By expression of a selection marker conferring resistance to an otherwise toxic agent,Acholeplasma laidlawii infected BHK-21 cells used as the model system were enabled to temporarily tolerate antibiotic concentrations high enough to be lethal to cell associated mycoplasma while leaving the host cells unharmed. Upon successful mycoplasma eradication, cultivation of the cured host cells in the absence of the selective agent yielded revertant cell clones that had regained susceptibility to the toxic agent. Cessation of the selection marker expression was shown to result from the loss of the selection marker DNA, which is a consequence of the fact that the stable and permanent integration of foreign DNA in eucaryotic cell chromosomes is highly inefficient. Thus, the cells were cured from mycoplasma yet remained biochemically unaltered.     

Treatment of mycoplasma contamination in a large panel of cell cultures

Summary Mycoplasmal contamination remains a significant impediment to the culture of eukaryotic cells. For certain cultures, attempts to eliminate the infection are feasible alternatives to the normally recommended disposal of the contaminated culture. Here, three antibiotic regimens for mycoplasmal decontamination were compared in a large panel of naturally infected cultures: a 1-wk treatment with the fluoroquinolone mycoplasma removal agent (MRA), a 2-wk treatment with the fluoroquinolone ciprofloxacin, and three rounds of a sequential 1-wk treatment with BM-Cyclin containing tiamulin and minocyclin. These antibiotic treatments had a high efficiency of permanent cure: MRA 69%, ciprofloxacin 75%, BM-Cyclin 87%. Resistance to mycoplasma eradication was observed in some cell cultures: BM-Cyclin 0%, MRA 20%, ciprofloxacin 20%. Nearly all resistant contaminants that could be identified belonged to the speciesMycoplasma arginini andM. orale. Detrimental effects of the antibiotics were seen in the form of culture death caused by cytotoxicity (in 5 to 13% of the cultures). Alterations of the cellular phenotypic features or selective clonal outgrowth might represent further untoward side effects of exposure to these antibiotics. Overall, antibiotic decontamination of mycoplasmas is an efficient, inexpensive, reliable, and simple method: 150/200 (75%) chronically and heavily contaminated cultures were cured and 50/200 (25%) cultures could not be cleansed and were either lost or remained infected. It is concluded that eukaryotic cell cultures containing mycoplasmas are amenable to antibiotic treatment and that a cure rate of three-quarters is a reasonable expectation.     

Detection of Mycoplasma hominis and Mycoplasma orale in cell cultures by immunofluorescence.

Mycoplasma contaminants of animal and human cell cultures were rapidly detected and identified by an indirect immunofluorescent technique. Cells suspected of being contaminated by mycoplasmas were grown as monolayers on chamber slides in a culture medium selected to promote mycoplasmal growth. Before fixation by acetone, the monolayers were subjected to a hypotonic treatment to cause swelling of the mycoplasmas. Detection and identification were then performed by indirect immunofluorescence using rabbit antisera to various mycoplasma species. The correlation between results obtained by the standard isolation procedure and those obtained by this method was very close.