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Molecular and Cellular Biology, December 1999, p. 7995-8002, Vol. 19, No. 12
American Registry of Pathology, Department of
Infectious and Parasitic Disease Pathology, Armed Forces Institute
of Pathology, Washington, D.C. 20306
Received 15 July 1999/Returned for modification 18 August
1999/Accepted 30 August 1999
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- Mycoplasmas are a heterogeneous
group of the smallest organisms capable of self-replication.
Mycoplasmas can cause a wide variety of diseases in animals
(28). Some mycoplasmas cause respiratory or urogenital
diseases in humans (18, 29), but others chronically colonize
our respiratory and urogenital tracts without apparent clinical
significance. In this respect, wall-free mycoplasmas are among the few
prokaryotes that can grow in close interaction with mammalian cells,
often silently for a long period of time. However, prolonged
interactions with mycoplasmas with seemingly low virulence could,
through a gradual and progressive course, significantly affect many
biological properties of mammalian cells.
Using a murine embryonic (C3H) cell system, we demonstrated that
chronic infection by mycoplasmas induced chromosomal instability as
well as malignant transformation of mammalian cells. This
mycoplasma-mediated oncogenic process had a long latency and
demonstrated distinct multistage progression (30).
Overexpression of H-ras and c-myc oncogenes was
found to be closely associated with both the initial reversible and the
subsequent irreversible states of the mycoplasma-mediated transformation in C3H cells (36). We have developed a new
paradigm for neoplastic processes based on our in vitro studies. We
hypothesize that chronic infection or colonization by certain
mycoplasmas may gradually induce malignant transformation and promote
tumorous growth of mammalian cells.
It is important to note that previous studies reported isolation of
mycoplasmas from human leukemic bone marrow (1, 7, 10, 14,
21). A majority of the mycoplasma population isolated was
identified as Mycoplasma fermentans. Furthermore,
experimental inoculation of M. fermentans induced leukemoid
disease with myeloproliferative changes in mice (20).
However, the mycoplasma oncogenesis hypothesis failed to advance
because although mycoplasma was isolated most frequently from patients
with leukemia, the same mycoplasma could also be found in nonleukemic
children or adults (19). Decades later, our understanding of
chronic infections, cancer latency, and cancer-associated microbes has
changed significantly (3, 4, 23). The previously described
evidence of latent mycoplasmal infection in bone marrow and our
findings that chronic infections by mycoplasmas could be associated
with a unique form of pathogenesis including cell transformation
(37) prompted us to reexamine the mycoplasmal effects on
malignant transformation of hematopoietic cells. Growth of murine
myeloid (32D) cells depends on the continuous induction of
interleukin-3 (IL-3) (12, 13). Differing from other
IL-3-dependent cells such as FD cells, 32D cells remain under strict
regulation by the growth signaling of IL-3 and rarely undergo
spontaneous transformation or become IL-3 independent. Withdrawal of
IL-3 supplement in culture rapidly induces the 32D cells to undergo
apoptosis, and more than 80% of the cells die within 4 to 5 days. The
growth of 32D cells is regulated closely by growth factor signaling,
which provides an ideal model system to study the transforming effects
of mycoplasmas.
Remarkably, we found that infections by several species of human
mycoplasmas, but not all species tested, would effectively prevent 32D
cells from undergoing apoptosis in culture without IL-3 supplement. The
mycoplasma-infected 32D cells continued to grow without the induction
of IL-3 growth signaling. Moreover, after a period of 4 to 5 weeks of
infection by M. fermentans or M. penetrans, 32D
cells gradually underwent malignant transformation and no longer
required the continued presence of mycoplasmas for growth in the
IL-3-free culture. These 32D cells grew autonomously and became highly
tumorigenic when injected into nude mice. This in vitro model system
allowed us to explore mycoplasma-mediated molecular mechanisms that
rescue cells from apoptosis and induce continuous cell growth. We also
studied the machinery that could lead to malignant transformation in
32D cells chronically infected by mycoplasmas.
Mycoplasmas and cell culture.
M. fermentans PG18 (ATCC
19989), incognitus (previously isolated from our laboratory
[17]), and A25 (isolated from a patient with AIDS and
to be reported separately), M. penetrans GTU-54 (previously
isolated from our laboratory [16]), M. salivarium ATCC 23064, M. genitalium ATCC 33530, M. pneumoniae ATCC 15531, M. orale ATCC 23714, and M. pirum (kindly provided by J. G. Tully, National
Institute of Allergy and Infectious Diseases, National Institutes of
Health) were grown aerobically in SP-4 broth medium. The 32D cell line
(kindly provided by Jaclyn H. Pierce, National Cancer Institute,
National Institutes of Health) is an IL-3-dependent, nontumorigenic
cell line that has an undifferentiated myeloid phenotype and a normal
diploid karyotype. The cell line was maintained in RPMI culture medium
containing 15% fetal calf serum and 5% WEHI-3B conditioned medium
(also provided by Jaclyn H. Pierce).
Infection of 32D cells with mycoplasmas.
32D cells were
transferred to culture medium free of IL-3 then inoculated with various
species of Mycoplasma at a ratio of 1,000 color change
units/cell. To determine the growth kinetics of 32D cells in cultures
infected with mycoplasmas, cell cultures were initiated at 2 × 105 cells/ml. Viable cells stained with trypan blue were
examined and counted every 2 to 3 days in a hemocytometer. Cell
densities of cultures were adjusted to 2 × 105
cells/ml when subcultured.
Heat inactivation of mycoplasmas.
Mycoplasmas were cultured
in SP-4 medium to log growth phase. After a culture sample was taken
for titration, mycoplasma cultures were incubated in a water bath at
70°C for 30 min. Heat-treated mycoplasmas were tested by culture to
ensure complete inactivation of the organisms and centrifuged in a
microcentrifuge at 12,000 rpm for 20 min. Mycoplasma pellets were then
suspended in RPMI 1640 medium at 1/10 of the original volume. These
suspensions of heat-killed mycoplasmas were kept frozen at Preparation of nuclear proteins.
Nuclear proteins were
prepared by the method of Schreiber et al. (27). Typically,
5 × 106 to 1 × 107 32D cells were
washed with 10 ml of Tris-buffered saline and pelleted. The pellet was
resuspended in 1 ml of Tris-buffered saline and pelleted again by
spinning for 15 s in a microcentrifuge. Tris-buffered saline was
removed, and the cell pellet was resuspended in 0.8 ml of cold buffer A
(10 mM HEPES [pH 7.9], 10 mM KCl, 0.1 mM EDTA, 0.1 mM EGTA, 1 mM
dithiothreitol [DTT], 0.5 mM phenylmethylsulfonyl fluoride, 10 mM
leupeptin, 1.5 mM pepstatin). The cells were incubated on ice for 15 min, after which 50 µl of a 10% solution of Nonidet NP-40 was added
and the tube vigorously vortexed for 10 s. The homogenate was
centrifuged for 30 s in a microcentrifuge, and the supernatant was
removed. The nuclear pellet was resuspended in 100 µl of ice-cold
buffer C (20 mM HEPES [pH 7.9], 0.4 M NaCl, 1 mM EDTA, 1 mM EGTA, 1 mM DTT, 1 mM phenylmethylsulfonyl fluoride, 10 mM leupeptin, and 1.5 mM
pepstatin), and the tube was vigorously rocked at 4°C for 15 min on a
shaking platform. The nuclear extract was centrifuged for 5 min in a
microcentrifuge at 4°C, and the supernatant was frozen in aliquots at
EMSA.
Electrophoretic mobility shift assay (EMSA) was
performed as described by Vincenti et al. (32). A
double-stranded oligonucleotide containing a mouse tumor necrosis
factor alpha Eradication of mycoplasmas in cell cultures.
To eradicate
mycoplasmas from the infected 32D cell cultures, the cultures were
treated with ciprofloxacin (10 µg/ml) for 3 to 4 weeks. Growth
responses of the infected cells to treatment were examined every 2 to 3 days by counting viable cell numbers in the cultures. The cell density
was adjusted to 2 × 105 cells/ml when subculture was
needed. To determine if mycoplasmas were successfully eradicated in the
cell cultures, samples of cell culture supernatants were cultured in
the SP-4 broth medium for isolating mycoplasmas (5).
Additionally, DNAs were isolated from the cell cultures and assayed for
the presence of mycoplasmal DNA by PCR using primers specific for
M. fermentans and M. penetrans (34) or
specific 16S rRNA genes (11).
Tumorigenicity in nude mice.
Normal, infected, and
transformed 32D cells were harvested from cultures and suspended in a
small volume (less than 1 ml) of phosphate-buffered saline (PBS). About
5 × 106 cells in 0.2 ml PBS were injected
subcutaneously into each nude mouse (6 to 8 weeks old; Harlan-Sprague
Dawley). The animals were carefully monitored for 1 year for tumor formation.
Karyotype analysis.
Actively growing 32D cell cultures were
incubated in the presence of colcemid (0.05 µg/ml) for 1 h to
accumulate metaphase cells. Cells were suspended in hypotonic solution
(0.075 M KCl) for 10 to 15 min; cell pellets were fixed in
methanol-acetic acid mixture (3:1 vol/vol) and then washed three times
in the fresh fixative. Chromosome preparations were stained with Giemsa
staining solution or by the trypsin-Giemsa banding method
(35).
Mycoplasmal infections induce continued growth of 32D cells in
IL-3-deprived culture.
Growth of 32D cells was strictly dependent
on IL-3. Removal of IL-3 from the culture caused immediate growth
arrest and apoptosis of 32D cells; about 75% of the cells died by day
4. Surprisingly, infections by mycoplasmas effectively prevent 32D
cells from undergoing apoptosis in the IL-3-deprived culture. As a
typical example, Fig. 1 shows that
infection by M. fermentans PG18 rescued 32D cells from
apoptosis and induced continued cell growth in the IL-3-free culture.
In this study, all mycoplasma-infected 32D cells that continued to
proliferate were maintained in culture without IL-3 supplement for more
than 3 months. We examined nine different strains and species of human
mycoplasmas for the ability to prevent apoptosis and induce continued
growth of 32D cells in the IL-3-deprived culture. In addition to
M. fermentans PG18, infections by M. fermentans
incognitus and A25, M. penetrans GTU-54, M. genitalium, M. orale, and M. pneumoniae were
all found to induce continued growth of 32D cells in cultures without
IL-3 supplement (Table 1). In contrast,
infections by M. salivarium or M. pirum failed to
rescue 32D cells from undergoing apoptosis in IL-3-free culture.
0270-7306/99/$04.00+0
Copyright © 1999, American Society for Microbiology. All rights reserved.
Mycoplasmal Infections Prevent Apoptosis and Induce Malignant
Transformation of Interleukin-3-Dependent 32D Hematopoietic
Cells
ABSTRACT
Top
Abstract
Introduction
Materials and Methods
Results
Discussion
References
B, 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-B 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.
INTRODUCTION
Top
Abstract
Introduction
Materials and Methods
Results
Discussion
References
MATERIALS AND METHODS
Top
Abstract
Introduction
Materials and Methods
Results
Discussion
References
70°C
until needed. The amount of heat-inactivated mycoplasmas added to the
cell cultures equaled to 1,000 color change units/ml.
70°C. Protein determination was performed by using a Bio-Rad DC
protein assay kit.
B enhancer located at 510 bp from the start of
transcription to the tumor necrosis factor alpha gene was used for the
binding assay. The sequences of the two strands of the oligonucleotide
with an NF-B binding site were 5'-CAA ACA GGG GGC TTT CCC TCC TC-3'
and 3'-GTT TGT CCC CCG AAA GGG AGG AG-5'; those of the oligonucleotide
with an AP-1 binding site were 5'-CGC TTG ATG ACT CAG CCG GAA-3' and
3'-GCG AAC TAC TGA GTC GGC CTT-5'. In the assay, a
32P-labeled oligonucleotide fragment (100,000 cpm) was
mixed with 2 µg of nuclear protein in a total volume of 20 µl of 25 mM HEPES (pH 7.9)-0.5 mM EDTA-0.5 mM DTT-0.1 M NaCl-10%
glycerol-1 µg of bovine serum albumin-2 µg of poly(dI-dC). After
30 min of incubation at room temperature, the reaction mixtures were
loaded onto 6% polyacrylamide gels in 0.5× Tris-borate-EDTA. The gels
were prerun for 1 h at 150 V prior to the actual run of 2.5 h
at the same voltage. After electrophoresis, the gels were dried and
exposed for autoradiography. Quantitation of protein-bound
oligonucleotide bands was done using Storm 860 scanner with ImageQuant
version 4.2 software (Molecular Dynamics).
RESULTS
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Abstract
Introduction
Materials and Methods
Results
Discussion
References
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FIG. 1.
M. fermentans PG18 infection induces
continued cell growth of 32D cells in culture deprived of IL-3. 32D
cells initiated at 5 × 104 cells/ml in culture medium
containing IL-3 or 2 × 105 cells/ml in culture medium
deprived of IL-3 were infected by M. fermentans PG18 at a
ratio of 1,000 color change units/cell. To avoid medium depletion and
ensure logarithmic growth, infected and noninfected 32D cells cultured
in IL-3-containing medium were subcultured with a 1:10 dilution on
every 4th day. Infected 32D cells cultured in IL-3-deprived medium were
subcultured on days 6, 12, 18, and 28 to maintain a cell density in the
range of 5 × 104 to 4 × 105
cells/ml. Viable cells were examined by trypan blue staining and
counted in a hemocytometer. Growth curves were plotted based on
cumulative cell numbers.
TABLE 1.
Activation of NF- B, continued cell growth in IL-3-free
cultures, and subsequent malignant transformation of 32D cells
following mycoplasmal infections
Mycoplasma-infected 32D cells do not produce IL-3. One possible explanation that infections by mycoplasmas could induce continued growth of 32D cells in culture without any supplement of IL-3 was that mycoplasma-infected 32D cells were themselves producing IL-3. The newly produced IL-3 would provide autocrine signaling and support growth of 32D cells. Thus, we examined expression of the IL-3 gene in mycoplasma-infected 32D cells. RNA from M. fermentans PG18-infected 32D cells that continued to grow in culture without IL-3 supplement was analyzed for the presence of IL-3 messenger by reverse transcriptase PCR (6). However, after 30 cycles of amplification using an IL-3-specific primer set (sense, 5'-ATG GTT CTT GCC AGC TCT ACC ACC A-3'; antisense, 5'-GAT AAG ACA TTT GAT GGC ATA AAG GA-3'), we could not detect any IL-3 messenger in mycoplasma-infected 32D cells that continued to grow in IL-3-free culture (data not shown). Mycoplasmal infections evidently triggered a replicating machinery that bypassed the IL-3-mediated signal-transducing pathway in rescuing 32D cells from undergoing apoptosis and inducing continued cell growth.
Mycoplasmas induce NF-B and enhance AP-1 nuclear binding
activities in 32D cells.
Recently, various membrane preparations
from mycoplasmas were found to be potent activators for NF-B and
AP-1 transcription factors in murine macrophages (8, 9, 25,
26). Since NF-B was known to have marked antiapoptosis
functions (2, 31, 33) we examined by EMSA the NF-B
activities in 32D cells before and after mycoplasmal infections.
Nuclear extracts of 32D cells grown in culture media supplemented with
IL-3 showed little NF-B activity. Infections by M. fermentans PG18, incognitus, and A25 for 24 h, however,
markedly induced NF-B binding activity in the nuclear extract of 32D
cells cultured in medium with or without IL-3 supplement (Fig.
2A). In this study, we also found that
infection by M. penetrans, M. pneumoniae,
M. genitalium, and M. orale could support
continued growth of 32D cells in IL-3 free culture by rapidly inducing
NF-B binding activity in the nuclear extract of 32D cells (Table 1).
In comparison, infection by M. salivarium or M. pirum, which failed to support continued growth of 32D cells in
IL-3-free culture, could not elicit the same nuclear factor response
(Fig. 2A and Table 1).
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Interference with induction of NF-B binding activity in
mycoplasma-infected 32D cells results in cell death.
Although
infections by mycoplasmas could rapidly activate both NF-B and AP-1
transcription factors in 32D cells, activation of NF-B appeared to
be more closely correlated with IL-3-independent mycoplasma-induced
cell growth. To further explore the role that NF-B might play in
preventing apoptosis and in induction of continued cell growth in the
absence of IL-3 signaling, we treated 32D cells with pyrrolidine
dithiocarbamate (PDTC; Sigma), a potent and specific inhibitor of
NF-B activation. While pretreatment with 100 nM PDTC had little
effect, pretreatment with 1,000 nM completely blocked the activation of
NF-B in 32D cells induced by M. fermentans PG18 infection
(Fig. 3). PDTC at the concentration of
100 nM had no effect on growth of 32D cells induced by the mycoplasma.
On the other hand, consistent with the lack of NF-B activation, mycoplasma-infected 32D cells treated with 1,000 nM PDTC failed to grow
and quickly died. In a separate study, treatment of M. fermentans incognitus-infected 32D cells with 500 and 1,000 nM PDTC blocked more than 70 and 85% of NF-B activation, respectively (Fig. 3). Growth of 32D cells induced by infections of the mycoplasma for 2 days was inhibited about 30% by 500 nM and 70% by 1,000 nM PDTC
(Fig. 3). PDTC by itself at the concentration of 1,000 nM did not seem
toxic or affect the growth of 32D cells supported by IL-3.
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Heat-inactivated mycoplasmas and mycoplasmal lipid-associated membrane proteins (LAMPs) can induce IL-3 independent growth of 32D cells. To examine whether infections by live mycoplasmas were required to induce the IL-3-independent growth of 32D cells, we first heat inactivated the mycoplasmas and then examined their ability to induce continued growth of 32D cells in IL-3-free culture. Figure 4A shows that introduction of heat-inactivated M. fermentans incognitus or A25 effectively prevented cell death and induced growth of 32D cells in IL-3-deprived culture. If heat-inactivated mycoplasmas were added whenever the cultures were replenished with fresh medium, 32D cells would continue to proliferate in IL-3 free culture. In this study, the cultures supported by heat-inactivated mycoplasmas were maintained for over 2 months before being terminated. However, transferring these 32D cells into culture with fresh medium without adding the heat-inactivated mycoplasmas quickly resulted in apoptosis and cell death. Continual presence of the heat-inactivated mycoplasmas was evidently required for the continued survival of 32D cells in culture without IL-3 supplements.
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B and AP-1 in murine macrophages (8,
25), we examined if the Triton X-114 preparation of LAMPs could
support the IL-3-independent growth of 32D cells. Figure 4B shows that LAMPs prepared from M. fermentans incognitus and M. penetrans rescued 32D cells from apoptosis and induced continued
cell growth in culture free of IL-3. Consistent with the earlier
finding, heat-killed M. fermentans, M. penetrans,
and their LAMPs rapidly induced NF-B activation in 32D cells (data
not shown).
Infection by live mycoplasmas induces transformation of 32D cells. If continued presence of heat-inactivated mycoplasmas in the IL-3-free culture was required for the continued growth of 32D cells, we wanted to know whether the continued presence of live mycoplasmas was also required for the continued growth of 32D cells in IL-3-free culture. We began to treat a subset of mycoplasma-infected cultures with ciprofloxacin to eradicate the mycoplasmas after 4 to 5 weeks of IL-3-independent mycoplasma-induced cell growth. Figure 5 shows the growth response to ciprofloxacin treatment of 32D cells that had been infected by M. fermentans PG18 for 4 to 5 weeks. Although after 5 days of ciprofloxacin treatment, no viable mycoplasmas could be isolated from the culture, 32D cells continued to grow rapidly for 2 to 3 weeks. As expected, PCR analysis showed that nonviable mycoplasmal organisms were detectable in culture and likely continued to support cell growth during this period. The nonviable organisms, however, were serially diluted to low concentration and were no longer detectable in culture after several subsequent fresh medium replenishments. The increase of cell number in the culture appeared to slow down significantly after 3 weeks. Examination of the culture revealed that many 32D cells were apparently dying while many others continued to grow. After 7 weeks, rapid cell growth resumed in the culture free of IL-3. PCR analyses confirmed the absence of M. fermentans in the continuously growing 32D cell culture without IL-3 supplement. In addition to M. fermentans PG18, we observed similar transformation of strictly IL-3-dependent 32D cells into autonomously growing cells after 4 to 5 weeks of infections by the M. fermentans A25 and incognitus as well as M. penetrans (Table 1). All of these mycoplasmal agents were eradicated from the 32D cell cultures by 3 weeks of antibiotic treatment.
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Mycoplasma-transformed 32D cells do not have the active nuclear
factors of NF-B and AP-1.
Our earlier study showed rapid
activation of NF-B by mycoplasmas appeared to be essential in
preventing 32D cells from undergoing apoptosis in IL-3-free culture. If
the continued presence of live mycoplasmas was no longer required for
the continued survival of transformed 32D cells in IL-3-free culture,
had 32D cells constitutively activated NF-B or AP-1 following
transformation? When we examined NF-B and AP-1 binding activities by
EMSA in nuclear extracts of these mycoplasma-transformed 32D cells that
were growing autonomously, we found no positive binding activity of
NF-B or AP-1 (Table 1). Infections by live mycoplasmas for a few
weeks apparently activated a new growth-stimulating pathway, different
from those of IL-3 signaling or NF-B activation, in these
autonomously growing cells.
Mycoplasma-transformed 32D cells have abnormal karyotypes.
In
C3H murine embryonic cells, an irreversible form of malignant
transformation induced by chronic infection of M. fermentans or M. penetrans was found to be associated with development
of chromosomal changes (30). We examined alteration of
chromosomes in 32D cells following mycoplasma infections and
particularly in 32D cells that were transformed and grew autonomously
in culture free of growth-stimulating mycoplasmas and IL-3
supplement. Karyotypic analysis showed that a great majority of
the control IL-3-dependent 32D cells had a total of 34 chromosomes with
7 abnormal chromosomes (Table 2) instead
of the normal mouse diploid complement of 40 chromosomes. Five of the
seven abnormal chromosomes, M1 [rob(2;17)], M2 [rob(3;10)], M3
[rob(4;12)], M4 [rob(12;16)], and M5 [rob(13;19)], were
Robertsonian translocation chromosomes; the other two abnormal chromosomes, M6 and M7, appeared to be derivative chromosomes of
complex translocation. The M6 chromosome was derived from translocation between chromosomes 9 and 14 [t(9;14)]; the M7 chromosome was chromosome 10 with a very small piece of additional chromosomal material on its centromere. The additional chromosomal material appeared to be a portion of chromosome 14 that is also involved in the
translocation with chromosome 9. The representative karyotype of 32D
cells is presented in Fig. 6. Infections
by various strains of M. fermentans or M. penetrans for 4 to 5 weeks in culture supplemented with IL-3
caused few chromosomal changes in 32D cells. In contrast, 32D cells
infected by these mycoplasmas for 4 to 5 weeks in culture without
supplemental IL-3 showed significant chromosomal alteration (Table 2).
Nearly 50% (23 of 51) of 32D cells infected by M. fermentans PG18 gained an additional chromosome. Interestingly, half (12 of 23) of the cells that gained an additional chromosome had
trisomy 19; the other half had an extra copy of various chromosomes. About 6% (3 of 52) of the 32D cells infected by M. fermentans incognitus for 4 weeks also gained an additional
chromosome 19. Most strikingly, more than 95% (52 of 54) of the 32D
cells infected by M. penetrans GTU-54 for 3 to 4 weeks in
culture free of IL-3 had trisomy 19 (Table 2).
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/PG18 culture) either had 34 chromosomes with 8 abnormal chromosomes or 35 chromosomes with an
additional copy of chromosome 19. Those cells with 34 chromosomes, in
addition to the original 7 abnormal chromosomes, had a new abnormal
rob(19;19) chromosome. Thus, both populations of
32D/IL-3/PG18 cells actually had trisomy
19. All 32D cells transformed by a period of M. fermentans
incognitus infection (4 weeks) and maintained in IL-3-free culture
following treatment with ciprofloxacin
(32D/IL-3/Mi culture) had 34 chromosomes.
In addition to the original 7 abnormal chromosomes, all of the
transformed cells had a new abnormal rob(19;19) chromosome. Thus, they
all were trisomy 19. Since more than 95% of 32D cells infected by
M. penetrans for 4 to 5 weeks
(32D/IL-3/Mpe+ culture) already had 35 chromosomes with an extra chromosome 19, treatment with ciprofloxacin
to eradicate M. penetrans in culture free of IL-3 did not
alter the cell karyotype. All of the transformed cells that rapidly
prevailed after ciprofloxacin treatment to eradicate mycoplasmas
(32D/IL-3/Mpe culture) had trisomy 19 (Table 2).
Mycoplasma-transformed 32D cells are highly tumorigenic.
We
examined whether the transformed 32D cells induced by mycoplasma
infections had become tumorigenic when injected into animals. In this
study, 2 × 106 mycoplasma-infected cells,
mycoplasma-free transformed cells, or noninfected control cells were
inoculated subcutaneously into each of three nude mice. Similar to the
IL-3-dependent 32D control cells, cells infected by various strains of
M. fermentans for 4 to 5 weeks in culture with or without
IL-3 supplement did not form tumors when injected into the animals. As
described above, treatment with ciprofloxacin to eradicate M. fermentans from the IL-3-free culture selected populations of
truly transformed cells. All cells in the
32D/IL-3/PG18 and
32D/IL-3/Mi cultures had trisomy 19 (Table
2) and formed tumors rapidly in nude mice. Noninfected control cells
treated in parallel with ciprofloxacin for 3 weeks did not form tumors
when injected into the animals. More than 95% of the cells in the
32D/IL-3/Mpe+ culture already had trisomy 19 (Table 2), they formed tumors in two out of three nude mice inoculated.
At necropsy, tumors formed by the mycoplasma-infected 32D cells in
animals were cultured and PCR tested for M. penetrans. No
evidence of M. penetrans infection was identified in these
tumors. After ciprofloxacin treatment to eradicate M. penetrans, the cells that grew autonomously in the
32D/IL-3/Mpe culture rapidly formed tumors
in all three animals inoculated. The tumors formed in the animals by
the mycoplasma-transformed 32D cells could be regrown easily in cell
culture system without IL-3 supplement and could also be passed easily
to other animals.
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DISCUSSION |
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Top
Abstract
Introduction
Materials and Methods
Results
Discussion
References
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IL-3-dependent 32D cells transfected with various oncogenes have
served as a model system to study oncogenesis (15). The inherent drawback of this model system is that the cells are
transformed artificially by introducing potent transforming genes apart
from what naturally transpires. In contrast, our model system using 32D
cells examines the transforming effects of infectious agents (mycoplasmas) that are naturally encountered. In this study, we showed
that infections by several human mycoplasmas prevented apoptosis and
induced continued proliferation of 32D cells in culture without IL-3
supplement. We believe this is the first reported finding that
infection by a prokaryote agent replaces the action of a growth factor
to which the targeted cells normally respond. Interaction with a
mycoplasmal membrane component(s) on the cell surface transmitted a
signal(s) that had potent antiapoptotic effects and rescued 32D cells
from cell cycle arrest. This mycoplasma-mediated growth-signaling
pathway was apparently different from that of IL-3 in supporting
continued growth of 32D cells. Activation of previously inactive
NF-B in 32D cells by the mycoplasmas appeared to be closely
associated with their ability to rescue these cells from apoptosis in
culture deprived of IL-3. Infections by mycoplasmas that markedly
enhanced AP-1 activity but did not activate NF-B failed to support
growth of 32D cells in IL-3-free culture. Moreover, blocking activation
of NF-B by an inhibitor led to prominent cell death of 32D cells
that were otherwise induced to grow by mycoplasmas. This finding is
consistent with recent reports from several laboratories showing that
NF-B appears to mediate survival signals that protect cells from
dying of apoptosis (2, 31, 33).
It became clear that rapid activation of NF-B and induction of
continued cell growth in 32D cells did not require infections by live
mycoplasmas. Heat-killed mycoplasmas or mycoplasmal membrane preparation LAMPs could effectively activate NF-B and induce continued growth of 32D cells in IL-3 free culture. The active component that triggered the signaling of NF-B activation is most
likely the lipid moiety of mycoplasmal membrane lipopeptides (8,
9, 25, 26). By continually supplying heat-killed mycoplasmas, we
could maintain 32D cells in culture without IL-3 supplement for at
least 2 months. Growth of these 32D cells remained dependent on the
presence of a mycoplasma-mediated growth signaling(s) for survival.
They quickly began to die of apoptosis when transferred to culture
without supplement of IL-3 or heat-killed mycoplasmas.
In comparison, infections by live mycoplasmas not only rescued 32D cells from cell cycle arrest and supported continued cell growth in IL-3-free culture but also induced malignant transformation of 32D cells. However, similar to our earlier finding for C3H cells (30), the mycoplasma-mediated cell transformation process would take time and involve a period of latency. In this study, it took more than 4 to 5 weeks of chronic infection by M. fermentans or M. penetrans before some of the 32D cells with autonomous growth ability began to emerge. Initially, the 32D cells that had acquired the unregulated growth property and no longer required the support from IL-3 or mycoplasmas constituted apparently only a small population. Further prolonged infection by the live mycoplasmas in culture could produce more cells with the malignant ability of autonomous growth. Antibiotic eradication of mycoplasmas from these IL-3-free cultures infected by the mycoplasmas effectively selected for a population(s) or clones of transformed cells that were capable of continued growth without the support of growth signaling from either IL-3 or mycoplasmas (Fig. 6). These transformed 32D cells were highly tumorigenic when injected into animals. It is not known whether infections by all mycoplasmas capable of supporting continued growth of 32D cells in IL-3-free culture could subsequently transform 32D cells.
Interestingly, the transformed 32D cells that obtained the malignant
property of unregulated growth induced by chronic mycoplasmal infection
showed no evidence of NF-B activation found in the early stage of
mycoplasmal infection (Table 1). Infection by the mycoplasmas for 4 to
5 weeks apparently had irreversibly activated an oncogenic process, not
involving NF-B, that was constantly signaling growth to the 32D
cells. Previous studies by others and by us showed chronic mycoplasmal
infections produced chromosomal instability in mammalian cells
(24, 30). Karyotypic analysis revealed development of
unregulated cell growth ability and tumorigenic properties of 32D cells
following infection by either M. fermentans or M. penetrans was associated with chromosomal changes and trisomy 19. Infection by M. penetrans appeared to be particularly
effective in causing trisomy 19 and hence malignant transformation of
32D cells in IL-3-free culture. A great majority (95%) of cells were found to have trisomy 19 after 4 to 5 weeks of M. penetrans
infection, without clonal selection by ciprofloxacin treatment (Table
2). Growth of these cells had apparently become unregulated, since they
formed tumors in two of three injected nude mice.
Extensive cell cycle studies in recent years helped the development of important concepts of checkpoints and rate-limiting steps in the cell cycle (22). Because cancer is largely a somatic genetic disease, loss of the ability to effectively coordinate the progression of cell cycle events when damage prejudicial to cell division has occurred often leads to development of malignancy. Although the molecular mechanism of mycoplasma-mediated oncogenesis is still not clear, our present study showed infections by M. fermentans and M. penetrans caused infidelity of genomic transmission in cell division. There were apparent aberrations in the machinery of chromosomal segregation as well as cell cycle checkpoint controls in mycoplasma-infected 32D cells. Following a few weeks of infections by either of the mycoplasmas, 32D cells with chromosomal changes and trisomy 19 began to appear and gradually accumulated in culture. It is not known how obtaining additional chromosome 19 was associated with better autonomous growth ability of 32D cells in culture without IL-3 support. Study of overexpression or constitutive activation of various oncogenes in the mycoplasma-transformed 32D cells is in progress.
In a previous study using monolayer culture of murine C3H embryonic cells, we showed that mycoplasmas induced malignant transformation of mammalian cells through chronic persistent infection. The process appeared to be a gradual progression with multiple distinct stages characterized by reversibility or irreversibility of transformation (30). In the present model system, using suspension culture of murine hematopoietic cells, we elucidated two separable avenues of mycoplasmal effects on mammalian cells. The first avenue rapidly activated an antiapoptotic cascade of events exerted through membrane component(s), rescued cells from cell cycle arrest, and induced continued cell growth. The mitogenic effect of mycoplasma-mediated signaling was reversible. The second avenue of effect required infection by live organisms with a latent period, later causing infidelity of genomic transmission in cell division resulting in malignant cell transformation. The effect of the first avenue to induce continued proliferation of cells that would otherwise undergo apoptosis was a prerequisite for subsequent induction of irreversible cell transformation associated with chromosomal changes. Since the mycoplasma-mediated transformation did not require mycoplasmal DNA integration into the host cells (37) or continued presence of the microbes once the genetic changes that lead to unregulated cell growth occurred, it presented a unique form of "hit and run" process.
Finding that human mycoplasmas can render growth factor independence and induce malignant transformation of IL-3-dependent hematopoietic cells in vitro has not only significance in general biology but also great direct clinical implications. In addition to further understanding the molecular mechanisms of mycoplasma-mediated pathway(s) for growth factor independence and oncogenesis, some important questions need to be answered. Can mycoplasmal infections also induce malignant transformation of human blood cells in culture? Is it possible to develop an animal model for mycoplasma-induced malignancies? These important studies will prove to be highly challenging due to the chronic nature of mycoplasma infections and the long latency in oncogenesis in vivo. However, resolving these pieces of the puzzle could fundamentally change the way in which we view many human malignancies.
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ACKNOWLEDGMENTS |
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We thank Douglas J. Wear for critical reading of the manuscript. We also thank Mark Tsai for assistance with Storm860 scanner and Susan Ditty for help with preparation of the manuscript.
This work was supported in part by the American Registry of Pathology.
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FOOTNOTES |
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* Corresponding author. Mailing address: Department of Infectious and Parasitic Disease Pathology, Armed Forces Institute of Pathology, Building 54, Room 4091, 14th St. and Alaska Ave., NW, Washington, DC 20306-6000. Phone: (202) 782-1870. Fax: (202) 782-7477. E-mail: los{at}afip.osd.mil.
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REFERENCES |
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Top
Abstract
Introduction
Materials and Methods
Results
Discussion
References
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