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Blood, Vol. 93 No. 11 (June 1), 1999:
pp. 3956-3963
Horizontal Transfer of DNA by the Uptake of Apoptotic Bodies
By
Lars Holmgren,
Anna Szeles,
Eva Rajnavölgyi,
Judah Folkman,
Georg Klein,
Ingemar Ernberg, and
Kerstin I. Falk
From the Center for Genomic Research and Microbiology and Tumor
Biology Center, Karolinska Institute, Stockholm, Sweden; the Department
of Immunology, L. Eötvös University, Göd, Hungary;
and the Department of Surgery, Children's Hospital, and Department of
Cell Biology, Harvard Medical School, Boston, MA.
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ABSTRACT |
In this study we have raised the question of whether DNA can be
transferred from one cell to another by phagocytosis of apoptotic bodies. We have used integrated copies of the Epstein-Barr virus (EBV)
as a marker to follow the fate and expression pattern of apoptotic DNA
in the phagocytotic host. Apoptosis was induced in EBV-carrying cell
lines by irradiation before cultivation with either human fibroblasts,
macrophages, or bovine aortic endothelial cells. Analysis of the
expression pattern of EBV-encoded genes was performed by
immunofluorescent staining as well as in situ hybridization.
Cocultivation of apoptotic bodies from lymphoid cell lines containing
integrated but not episomal copies of EBV resulted in expression of the
EBV-encoded genes EBER and EBNA1 in the recipient cells at a high
frequency. Fluorescence in situ hybridization analysis showed uptake of
human chromatin as well as integrated EBV-DNA into the nuclei of bovine
aortic endothelial cells. These data show that DNA may be rescued and
reused from apoptotic bodies by somatic cells. In addition, our
findings suggest that apoptotic bodies derived from EBV-carrying B
lymphocytes may serve as the source of viral transfer to cells that
lack receptors for the EBV virus in vivo.
© 1999 by The American Society of Hematology.
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INTRODUCTION |
THE CONTROL OF cell number in
multicellular organisms depends on the fine balance between cell
proliferation and cell death. Cell death by apoptosis plays a key role
in the elimination of cells during embryonic development as well as in
adults. It is, for example, involved in the negative selection of
neural cells, removing redundant cells during organ
formation.1 In adults, apoptosis plays an important role in
the maintenance of tissue homeostasis; in the human small intestine
alone, approximately 109 cells apoptose every hour and are
sloughed off into the lumen of the gut.2,3 Apoptosis is
also of importance in tumor development. It may serve as an anticancer
mechanism by restricting the expansion of cells with unleashed
proliferative potential. Tumors remain constant in size or dormant when
proliferation is balanced by an equal level of cell death.4
This state of dormancy may be controlled at the genetic level such as
induction of apoptosis by the p53 tumor-suppressor gene or by the
inability of the tumor cells to recruit vessels from the
microenvironment.5,6 Loss of p53 or the induction of
angiogenesis results in lowered incidence of apoptosis and escape from
dormancy. Thus, there exists stages during tumor development in which
there is a high turnover of genetic material that is fragmented during
apoptosis and subsequently taken up by neighboring cells.
The recognition of apoptotic bodies by macrophages or dendritic or
neighboring cells is mediated by several different pathways. Surface
receptors such as the vitronectin receptor ( v 3) and thrombospondin receptor (CD36) located on the macrophages may recognize
apoptotic cells via the binding of thrombospondin.7 Translocation of phosphatidylserine from the inner to outer side of the
cell membrane serves as a recognition signal for phagocytosis. Not only
macrophages are capable of phagocytosing apoptotic bodies. Injection of
apoptotic liver cells in the portal vein in the mouse liver results in
uptake of apoptotic bodies in the liver endothelial cells.8
In vitro, apoptotic macrophages are rapidly phagocytosed by human
fibroblast cells within 1 hour.9
Horizontal transfer of genes has been reported in bacteria and fungi
and plays an important role in the generation of resistance to
antibiotic drugs as well as adaptation to new environments (reviewed in
Porter10 and Mishra11). Transfer of DNA from bacteria to somatic cells may also occur, as shown by in vitro experiments that demonstrate efficient uptake of a -gal reporter plasmid from attenuated bacteria into the nuclei of the phagocytic cell.12 However, horizontal transfer of genetic information between somatic cells has not yet been described. In this study, we
raised the question of whether DNA from apoptotic cells can be salvaged
and reused after phagocytosis. We have followed the fate of DNA from
apoptotic bodies of Epstein-Barr virus (EBV)-carrying transformed
lymphoid cell lines after phagocytosis of normal adherent fibroblasts,
macrophages, and endothelial cells. Integrated, non-virus-producing copies of EBV-DNA were used as markers to track the incoming DNA after
ingestion as well as the expression of EBV-encoded genes by the
phagocytosing cell.
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MATERIALS AND METHODS |
Cocultivation experiments.
Human fetal lung fibroblasts, bovine aortic endothelial cells
(established in the laboratory of Dr Judah Folkman, Children's Hospital, Boston, MA), human monocytes (purified from normal human blood as previously described13), or human vascular smooth
muscle cells (kindly provided by Britt Dahlgren, Karolinska Hospital, Stockholm, Sweden) were trypsinized and transferred to 8-well Lab Tek
slides (Nalgene; Nunc, Copenhagen, Denmark) for
immunostaining (50,000 cells/well) or 10-cm Petri dishes for
fluorescence in situ hybridization (FISH) analysis. The following day,
EBV-carrying lymphoid cell lines were irradiated with 150 Gy and added
to the cultures at a ratio of 5:1. Alternatively, cells were treated with 16 µg/mL etoposide (Sigma, St Louis, MO) for 24 hours, washed three times in phosphate-buffered saline (PBS), and then
added to cultures of human fetal fibroblasts. The tissue culture medium was first changed after 48 hours and then changed every 3 days. Cell
lines negative for EBV were also included as negative controls. For
immunostaining, cells were washed once with PBS and then fixed in
 20°C methanol:acetone, 2:1 (vol:vol) for 5 minutes and
air-dried. Cells were rehydrated in balanced salt solution (BSS) and
then incubated with human serum antibodies against EBNA1-6 or with serum from an EBV-negative donor for 15 minutes at 37°C and washed in 3× BSS.14 EBNA1 was detected with human serum
preadsorbed with an EBNA1-negative, EBNA2-6-positive cell line
E95-A-BL28.14 Positive staining was visualized by
incubation sequentially with complement and fluorescein isothiocyanate
(FITC)-labeled anticomplement antibodies as previously
described.15 The mouse monoclonal antibody PE2 was also
used to detect EBNA2 expression by immunofluorescence.16 The presence of cells in viral lytic cycle was detected by
immunostaining against viral capsid antigen (VCA) or early antigen (EA)
using FITC-conjugated sera from Burkitt's lymphoma (EA) or
nasopharyngeal carcinoma (VCA) patients according to established
protocols.17,18 For detection of EBER1 and 2 nuclear RNAs, cells were fixed in 4% paraformaldehyde for 4 hours,
pretreated with 5 µg/mL proteinase K at 37°C for 30 minutes, and
hybridized according to the protocol of the manufacturer (DAKO,
Glostrup, Denmark).
Apoptosis assays.
For DNA fragmentation assays, 5 × 106 cells were
resuspended in 10 mmol/L EDTA, pH 8, 0.5% Triton X-100, and lysed with
10 strokes with a Dounce homogenizer. Cells were pelleted and the resulting supernatant was incubated with 100 µg/mL RNase A at 37°C for 1 hour. Sodium dodecyl sulfate (SDS) and proteinase K were
added to concentrations of 1% (wt/vol) and 200 µg/mL, respectively, and incubated at 50°C for 2 hours. The DNA was precipitated
overnight at 20°C by adding 1/10 of total volume 5 mol/L
NaCl and 2.5 vol of 99% EtOH. Precipitated DNA was collected by
centrifugation at 13,000 rpm at 4°C in a microcentrifuge.
Fragmentation was analyzed by electrophoresis in 1.5% agarose gels.
FISH.
Total human genomic DNA from a normal donor was labeled with
tetramethyl-rhodamine-dUTP using a nick translation kit (GIBCO-BRL, Grand Island, NY). The BamHI W fragment from the
EBV genome was labeled with biotin-11-dUTP with the same method. FISH
analysis was performed according to the protocol of Pinkel et
al.19 Slides were denatured for 5 minutes in 70%
formamide, 2× SSC at 75°C and subsequently dehydrated
sequentially in cold 70%, 95%, and 100% ethanol and air-dried.
Probes were denatured for 10 minutes at 80°C in the hybridization
mix (50% formamide, 2× SSC, and 10% dextran sulphate). Slides
were hybridized overnight at 37°C and then washed in 50%
formamide, 2× SSC for 4 × 3 minutes, and for 3 × 3 minutes in 2× SSC at 46°C. Positive
hybridization with the biotinylated BamHI W probe was detected
using avidin-conjugated to fluorescein (Vector, Burlingame,
CA). The tetra-methyl-rhodamine-dUTP-labeled human probe
was viewed directly by fluorescence microscopy without signal
amplification. Cells were counterstained with the DNA fluorochrome 4,6-diamidino-2-phenyl indole (DAPI) and mounted in antibleach medium.
Results were analyzed using a fluorescence microscope (Leitz-DMRB;
Leica, Heidelberg, Germany) equipped with a Hamamatsu 4800 CCD camera
(Hamamatsu, Herrsching, Germany). Digital images were processed in
Adobe Photoshop (Adobe, Mountain View, CA). For three-dimensional
imaging, pictures were sampled in the z-axis and deconvoluted using
digital confocal imaging (Openlab, Improvision, Coventry, UK). The
resulting images were processed using the 3-D rendering software (Openlab).
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RESULTS |
Expression of EBV-encoded genes in fibroblasts after uptake of
apoptotic bodies.
The EBV-negative Burkitt's lymphoma cell line BL41 and its
EBV-positive derivative BL41/95 was used for cocultivation with human
fetal fibroblasts (HF). The BL41/95 is an in vitro EBV-infected BL41
cell line that carries integrated copies of EBV that express the EBNA1
and 2 (as detected by immunofluorescence) but does not produce
virus20,21 (Barbro Ehlin-Eriksson, personal communication, December 1998). Apoptosis was reproducibly induced by irradiating cells
at 150 Gy. Radiation induced DNA ladder formation as analyzed by DNA
gel electrophoresis. Staining of nuclei with the DNA fluorochrome Hoechst 33258 showed nuclear condensation of DNA and fragmentation of
nuclei into apoptotic bodies (Fig 1A and
B). Irradiation resulted in 100% cell death after 4 days, as analyzed
by trypan blue exclusion (Fig 1C).
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| Fig 1.
Induction of apoptosis in BL41 and BL41/B95 cells. (A)
Analysis of DNA fragmentation 48 hours after irradiation with 150 Gy by
DNA gel electrophoresis. M, 123-bp DNA ladder (GIBCO). (B) Apoptotic
morphology was examined with Hoechst 33258 DNA staining. (C) Viability
of irradiated cells was analyzed by trypan blue exclusion.
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Apoptotic bodies cultivated with human fetal fibroblasts became
phagocytosed and internalized within 1 hour, as previously reported.9 To follow the fate of internalized DNA, the
BL-41 and BL41/95 were labeled with 2, 3 Bromo-deoxy-uridine (BrdU) for
48 hours before irradiation. The irradiated cells and HF cells were
cocultivated for 1 week, as previously described.22 The presence of BL41 and BL41/95 DNA in HF cells was detected by
immunostaining with antibodies against BrdU. In both cell lines,
apoptotic bodies were still detectable in a perinuclear location in the
cytoplasm of the HF cells after 1 week of cocultivation
(Fig 2a). Double staining with KF human
serum against the EBNA complex 1-6 showed that nuclei of HF cells
containing a BL41/95 apoptotic body stained positive for EBNA (Fig 2a).
The presence of EBNA1 in cocultures of HF cells was shown by staining
with human serum preadsorbed with an EBNA1-negative, EBNA2-6-positive
cell line E95-A-BL28. Control experiments in which fibroblasts were
cultivated with the original EBV-negative BL41 cell line were always
negative (Fig 2a). EBV did not infect HF cells, as shown by the lack of positive EBNA staining after incubation with B95-8 virus23
that could infect and transform B cells in parallel cultures
(Table 1).
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| Fig 2.
(a) Presence of apoptotic bodies in HF cells after 1 week
of cocultivation. The EBV-positive BL41/95 (A through C) and -negative
BL41 (D through F) were labeled for 48 hours with BrdU before
irradiation and cultivation with HF cells. DNA from the lymphomas was
detected with antibodies against BrdU (A and D). Cells were
double-stained with human serum against EBV nuclear antigens (EBNA; B
and E). (C) and (F) show Hoechst 33258, anti-EBNA, and anti-BrdU
stainings in the same picture. Size bar = 5 µm. (b) Fibroblasts
pulsed with BrdU before being cultivated with irradiated BL41/95 cells.
Nuclei of fibroblastic origin were detected with antibodies against
BrdU. Cells were double-stained with human serum against EBNAs. The
picture shows overlapping signals of EBNA, BrdU, and Hoechst 33258 staining in fibroblast nuclei. Size bar = 8 µm.
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Table 1.
Induction of EBNA1 and EBER Expression in HF Cells After
Coculture With Apoptotic Bodies From Lymphoid Cell Lines
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One explanation for our findings is that the EBNA1-positive nuclei were
derived from entire lymphoid nuclei taken up by the fibroblast cells.
To exclude this possibility, fibroblasts were pulsed with BrdU before
cocultivation with irradiated (unlabeled) BL41/95 cells.
Double-staining of cells with BrdU and EBNA1 antibodies showed EBNA1
staining in nuclei that also were positive for BrdU. Sporadic cells
could be detected containing more than one EBNA1-staining nuclei. These
nuclei were always of fibroblastic origin, as shown by positive BrdU
staining (Fig 2b).
Integrated EBV-DNA but not episomal induces expression of EBV-encoded
genes in fibroblasts.
We next investigated whether cocultivation of apoptotic bodies derived
from other EBV-carrying cell lines could induce EBNA expression to HF
cells. Apoptosis was elicited by irradiation in 9 EBV-carrying cell
lines and 3 EBV-negative cell lines. The resulting apoptotic bodies
were cultivated with HF cells for 3 weeks. Subsequently, the cells were
tested for the presence of the EBV-encoded RNAs, EBER1 and 2, by in
situ hybridization analysis and for EBNA1 expression by
immunofluorescence staining (Table 1 and
Fig 3G and H). The donor cell lines could
be divided into two groups: apoptotic bodies from 5 of the cell lines
(Table 1, upper part) induced EBNA1 and EBER expression in HF, whereas
the other 4 could not. The lines that could act as EBV donors induced EBNA1 and EBER expression in 1% to 5% HF cells. The other cell lines
induced little or no EBNA or EBER expression in the recipient cells
(<5 of 500,000 cells in 5 experiments). The cell lines that could
induce expression of EBV markers in HF cells carried integrated EBV
genomes,24-27 whereas the ineffective cell lines contained episomal EBV-DNA (Table 1).28
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| Fig 3.
Expression of EBV-specific genes, EBER1+2 and EBNA1-6,
in different cell types after 3 weeks of cultivation with apoptotic
bodies from EBV-carrying Namalwa line. (A) Phase contrast and (B)
immunofluorescence staining showing coexpression of macrophage-specific
marker CD68 (red) and EBNA (green) in the same cells. (C) shows the
location of macrophage nuclei by Hoechst 33258 DNA staining that
overlap with EBNA as shown in (D). Arrows mark the location of the
nuclei that are located in the periphery of the cytoplasm of the
macrophages. (E) Phase contrast and (F) fluorescence showing EBNA
expression in bovine aortic endothelial cells. (G) Phase contrast and
(H) bright field view of in situ hybridization analysis of EBER1 and 2 expression in HF cells. Arrows depict positive nuclei. Size bar = 20 µm.
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The induction of EBNA1 in HF cells was not restricted to
radiation-induced apoptosis, because a similar effect was observed with
cells treated with etoposide (Table 2).
Interestingly, cocultivation of HF cells with Namalwa cells exposed to
hypo-osmotic shock did not affect EBNA1 expression in HF cells. This
finding indicates that transfer of expression of EBV-encoded genes is
mediated by EBV-carrying apoptotic but not necrotic cells.
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Table 2.
Expression of EBNA1-6 in Human Fetal Fibroblasts After 3 Weeks of Coculture With Apoptotic/Necrotic Namalwa Cells
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Host-dependent expression of EBNA2.
We next investigated whether the expression pattern of EBV-encoded
genes depended on the phenotype of the donor or the host. Earlier
findings have shown that EBNA2 is only expressed in immunoblastic lines.29 EBNA2 was expressed in all donor lines studied,
with the exception of Rael, P3H3, and EHR-A-BL41.29-31 We
investigated whether the expression pattern of EBNA2 was downregulated
in EBNA1- and EBER-expressing HF cells. No detectable EBNA2 staining
could be observed with either the PE2 anti-EBNA2 monoclonal antibody or
adsorbed EBNA-2 specific human serum (Table 1). This finding is
consistent with the lack of EBNA2 expression in EBV-carrying non-B
cells, including somatic cell hybrids between B and non-B cells with a
dominating fibroblastic or epithelial phenotype.32
High efficiency transfer of expression EBV to macrophages and
endothelial cells.
We have also tested whether integrated EBV can be transferred with
similar efficiency to other cell types. Apoptotic bodies derived from
Namalwa cells were cultured with either bovine aortic endothelial (BAE)
cells, human monocytes, or vascular smooth muscle cells for 3 weeks.
Both monocytes and BAE cells showed a high percentage of
EBNA1-6-positive cells (20% to 50% positive EBNA1-6 staining after 3 weeks of cocultivation; Fig 3A through F and Table 3). Smooth muscle cells exhibit a
significantly lower frequency of uptake and expression of EBNA1-6
(<0.01%). The high efficiency with which monocytes and endothelial
cells are induced to express EBNA1 may relate to their normally high
phagocytotic activity.
Presence of DNA from apoptotic cells in the nuclei of recipient
cells.
The maintenance of high EBNA1 and EBER expression over more than 3 weeks, the integration dependent expression of these genes, and the
recipient cell type-related expression pattern (EBNA1+,
EBNA2 ) suggested that integrated EBV sequences were
transferred to the phagocytotic host during cocultivation. We therefore
examined whether DNA from apoptotic lymphoid cell lines was transferred to the nuclei of the recipient cells. FISH analysis was used to follow
the fate of EBV as well as genomic DNA after phagocytosis by bovine
endothelial cells. Coculture of cells from two different species
permitted us to distinguish between the DNA of the donor cells from
that of the recipient cells. Total human genomic DNA was labeled with
tetra-methyl-rhodamine-dUTP and used as a probe to identify DNA of
human origin. Hybridization of human DNA to Namalwa interphase nuclei
resulted in a uniform hybridization pattern with no detectable
cross-reactivity to bovine nuclei (Fig 4A).
The presence of EBV-DNA was assayed by FISH analysis using a
biotin-labeled BamHI W fragment as a probe (a 3-kb fragment that is repeated 6 to 10 times in the EBV genome).24,33 The BamHI W probe gave two distinct signals in Namalwa nuclei, as previously reported,24,33 whereas all BAE nuclei were
negative (Fig 4A).
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| Fig 4.
Samples were hybridized with the BamHI W fragment
of EBV, a sequence approximately 3-kb long that is repeated 6 to 10 times in the EBV genome. After hybridization, the biotinylated
BamHI W probe was detected using the fluorescein-conjugated
avidin-biotin amplification system (green signals). Human total genomic
DNA was directly labeled with tetra-methyl-rhodamine-dUTP (red signal).
The presence of yellow signals indicated overlap of the human and the
EBV probes. Nuclei were counterstained with the DNA fluorochrome, DAPI
(blue). Digital images were captured in gray scale and subsequently
pseudo-colored using computer imaging software. (A) Namalwa (left) and
BAE nuclei (right) hybridized simultaneously with the EBV BamHI
W probe (green) and human genomic DNA probe (red). The Namalwa nucleus
shows two distinct signals with the EBV probe and uniform hybridization
with the human probe, whereas the bovine nucleus was negative for both
probes. (B through E) These figures show four examples from the
two-color FISH analysis of the presence of human genomic DNA (red) and
EBV-DNA (green) in BAE cells cultured with irradiated Namalwa cells for
1 week. Yellow signals indicate overlap of the signals from the EBV
BamHI W and the human probes. (F) Simultaneous analysis of
presence of EBV-DNA and human DNA in a BAE nucleus after cultivation
with the EBV-negative cell line BL41 shows the presence of human DNA
but not of EBV DNA in the BAE nucleus. (G) BAE nucleus cultured with
irradiated Namalwa cells showing uptake of human DNA (red). A
positive signal was analyzed by digital confocal microscopy. Images
were sampled in the z-axis and subsequently processed with 3-D
rendering software (Openlab) to generate three-dimensional pictures.
The nuclei and incoming DNA could be viewed at different angles
(0°, 44°, 56°, and 72°) and depths that showed that the
positive signal was localized within the nuclear cage.
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The transfer of EBV and human DNA was then analyzed in bovine
endothelial cells cultured with apoptotic Namalwa cells. Using the
human DNA- and EBV-specific probes simultanously, it was shown that
approximately 17% of the bovine endothelial nuclei contained human DNA
and 15% of the bovine nuclei analyzed a positive signal with the
BamHI W (Fig 4 and Table 4).
Similar frequencies were also observed in nuclei from BAE cells
cultured with apoptotic IB4 cells (Table 4). In the bovine nuclei
showing positive hybridization with both probes, signals overlapped in
the same nuclear compartment (Fig 4B through D). Transfer of human DNA
was also detectable in 3% of the nuclei after coculture of BAE cells
and the EBV-negative BL41 line (Fig 4F). As expected, no positive
signal could be detected in these cells with the BamHI W probe.
To exclude the possibility that the positive signal was originating
from cytoplasmic apoptotic DNA, positive signals were also analyzed by
digital confocal microscopy. Images were sampled in the z-axis and
subsequently processed with 3-D rendering software to generate
three-dimensional pictures (Fig 4G). The nuclei and incoming DNA could
be viewed at different angles and depths that showed that the positive
signal was residing within the nuclear cage.
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DISCUSSION |
We have shown that cultivation of apoptotic bodies derived from
EBV-carrying cell lines with either fibroblasts, monocytes, or
endothelial cells resulted in the uptake of DNA (as shown in the BAE
cells) and expression of EBV-specific markers in the recipient cells.
Expression of EBNA1 as well as EBER1+2 could be detected up to 5 weeks
after the start of cocultivation experiments. The EBNA expression
pattern was host-dependent, because EBNA1 but not EBNA2 was detected in
fibroblast cells. This finding is consistent with previous findings
showing that EBNA2 is only expressed in cells of lymphoblastoid origin.
BrdU-labeled apoptotic bodies could still be detected in a perinuclear
location of the fibroblast recipient cells after 1 week of culture.
Fibroblast cells containing an apoptotic body from the EBV-carrying
cell line BL41/95 also expressed EBNA1, whereas fibroblasts cultivated
with EBV-negative cell lines did not. Labeling recipient cells with
BrdU before cocultivation showed that recipient cells only contained
nuclei of fibroblast origin. This argues against the possibility that
whole nuclei of the donor cell are phagocytosed to generate a
functional hybrid cell with the recipient cell. FISH analysis showed
that genomic as well as EBV-DNA from the apoptotic bodies was
transferred into the nuclear compartment of the phagocytosing cell. The
transferred DNA was stable over time, because similar frequencies could
be detected with human and EBV-specific probes after 1, 2, and 3 weeks
of cocultivation (data not shown).
Cultivation of lymphoid cell lines with either integrated or episomal
copies of EBV showed that integrated EBV-DNA is transferred to the
recipient cell, whereas episomal DNA is not. It is not clear why
integration of EBV-DNA seems to be a requirement for EBV-DNA transfer.
One explanation is that the episomal forms may be more prone to
degradation by nucleases activated during apoptosis than integrated
viral copies. FISH analysis showed that integrated EBV-DNA in Namalwa
is transferred at a relative high frequency to bovine endothelial
cells. The Namalwa cell line contains two integrated copies (172 kb) of
EBV on the human chromosome 1 and constitutes a minute fraction of the
total genome. It is therefore striking that the frequency of transfer
of EBV-DNA after cocultivation with apoptotic bodies induced in the
Namalwa line is at a level comparable to that of total Namalwa DNA. It
suggests that the transfer of different fragments from the apoptotic
chromatin and/or integrated EBV-DNA may be preferentially transferred
after phagocytosis.
EBV infects B lymphocytes after binding to the complement receptor 2 (CR2), which is only present on B cells and immature T cells. However,
EBV-DNA and/or its expression has been detected in several additional
cell types in vivo, such as fibroblasts from rheumatoid arthritis
patients, T-cell lymphomas, and a variety of carcinomas and
sarcomas.34-38 Our findings raise the question of whether
apoptotic bodies derived from EBV-carrying B lymphocytes may serve as
the source of viral transfer to cells that lack receptors for the EBV
virus in vivo. This could play an important role in the persistence of
the EBV virus in the human host. In addition, the extended expression
of viral genes in antigen presenting cells such as endothelial cells
and macrophages may play an important role in eliciting an immune
response to viral antigens. Finally, we speculate that similar
mechanisms of horizontal DNA transfer may be of importance in
conditions characterized by high levels of apoptosis, eg, in tumors
treated with irradiation or chemotherapy.
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FOOTNOTES |
Submitted September 11, 1998; accepted January 26, 1999.
Supported by grants from the Swedish Cancer Society and the Jeannska Foundation.
The publication costs of this
article were defrayed in part by
page charge payment. This article
must therefore be hereby marked
"advertisement"
in accordance with 18 U.S.C. section
1734 solely to indicate this fact.
Address reprint requests to Lars Holmgren, PhD, Microbiology and Tumor
Biology Center, PO Box 280, Karolinska Institute, S-171 77, Stockholm,
Sweden; e-mail: Lars.Holmgren{at}mtc.ki.se.
| |
REFERENCES |
1.
Jacobson MD, Weil M, Raff MC:
Programmed cell death in animal development.
Cell
88:347, 1997[Medline]
[Order article via Infotrieve]
2.
Wyllie AH:
Apoptosis and the regulation of cell numbers in normal and neoplastic tissues: An overview.
Cancer Metastasis Rev
11:95, 1992[Medline]
[Order article via Infotrieve]
3.
Potten CS:
The significance of spontaneous and induced apoptosis in the gastrointestinal tract of mice.
Cancer Metastasis Rev
11:179, 1992[Medline]
[Order article via Infotrieve]
4.
Holmgren L:
Angiogenesis-restricted tumor dormancy.
Cancer Metastasis Rev
15:241, 1996[Medline]
[Order article via Infotrieve]
5.
Symonds H, Krall L, Remington L, Aenz-Robles M, Lowe S, Jacks T, Van Dyke T:
p53-dependent apoptosis suppresses tumor growth and progression in vivo.
Cell
78:703, 1994[Medline]
[Order article via Infotrieve]
6.
Holmgren L, O'Reilly MS, Folkman J:
Dormancy of micrometastases: Balanced proliferation and apoptosis in the presence of angiogenesis suppression.
Nat Med
1:149, 1995[Medline]
[Order article via Infotrieve]
7.
Savill J, Fadok V, Henson P, Haslett C:
Phagocyte recognition of cells undergoing apoptosis.
Immunol Today
14:131, 1993[Medline]
[Order article via Infotrieve]
8.
Dini L, Lentini A, Diez Diez G, Rocha M, Falasca L, Serafino L, Vidal-Vanaclocha F:
Phagocytosis of apoptotic bodies by liver endothelial cells.
J Cell Sci
108:967, 1995[Abstract]
9.
Hall SE, Savill JS, Henson PM, Haslett C:
Apoptotic neutrophils are phagocytosed by fibroblasts with participation of the fibroblast vitronectin receptor and involvement of a mannose/fucose-specific lectin.
J Immunol
153:3218, 1994[Abstract]
10.
Porter RD:
Modes of gene transfer in bacteria, in
Kucherlapati R,
Smith GR
(eds):
Genetic Recombination. Washington, DC, ASM, 1988, p 1.
11.
Mishra NC:
Gene transfer in fungi.
Adv Genet
23:73, 1985[Medline]
[Order article via Infotrieve]
12.
Darji A, Guzmán CA, Gerstel B, Wachholz P, Timmis KN, Wehland J, Chakraborty T, Weiss S:
Oral somatic transgene vaccination using attenuated S. typhimurium.
Cell
91:765, 1997[Medline]
[Order article via Infotrieve]
13.
Freundlich B, Avdalovic N:
Use of gelatin/plasma coated flasks for isolating human peripheral blood monocytes.
J Immunol Methods
62:31, 1983[Medline]
[Order article via Infotrieve]
14.
Falk K, Ernberg I, Sakthivel R, Davis J, Christensson B, Luka J, Okano M, Grierson HL, Klein G, Purtilo DT:
Expression of Epstein-Barr virus-encoded proteins and B-cell markers in fatal infectious mononucleosis.
Int J Cancer
46:976, 1990[Medline]
[Order article via Infotrieve]
15.
Reedman B, Klein G:
Cellular localization of an Epstein-Barr-virus (EBV)-associated complement fixing antigen in producer and non-producer lymphoblastoid cell lines.
Int J Cancer
11:499, 1973[Medline]
[Order article via Infotrieve]
16.
Young L, Alfieri C, Hennessy K, Evans H, O'Hara C, Anderson KC, Ritz J, Shapiro RS, Rickinson A, Kieff E, Cohen JI:
Expression of Epstein-Barr virus transformation-associated genes in tissues of patients with EBV lymphoproliferative disease.
N Engl J Med
321:1080, 1989[Abstract]
17.
Klein G, Dombos L, Gothoskar B:
Sensitivity of Epstein-Barr virus (EBV) producer and non-producer human lymphoblastoid cell lines to superinfection with EBV-virus.
Int J Cancer
10:44, 1972[Medline]
[Order article via Infotrieve]
18.
Henle W, Henle GE, Horwitz CA:
Epstein-Barr virus specific diagnostic tests in mononucleosis.
Hum Pathol
5:551, 1974[Medline]
[Order article via Infotrieve]
19.
Pinkel D, Straume T, Gray JW:
Cytogenetic analysis using quantitative high-sensitivity fluorescence hybridization.
Proc Natl Acad Sci USA
83:2934, 1986[Abstract/Free Full Text]
20.
Cordier M, Calender A, Billoud M, Zimber U, Rousselet G, Pavlish O, Banchereau J, Tursz T, Bornkamm G, Lenoir GM:
Stable transfection of Epstein-Barr virus (EBV) nuclear antigen 2 in lymphoma cells containing the EBV P3H3R1 genome induces expression of B-cell activation molecules CD21 and CD23.
J Virol
64:1002, 1990[Abstract/Free Full Text]
21.
Nakagomi H, Pisa P, Pisa EK, Yamamoto Y, Halapi E, Backlin K, Juhlin C, Kiessling R:
Lack of interleukin-2 (IL-2) expression and selective expression of IL-10 mRNA in human renal cell carcinoma.
Int J Cancer
63:366, 1995[Medline]
[Order article via Infotrieve]
22.
Jones K, Rivera C, Sgadari C, Franklin J, Max EE, Bhatia K, Tosato G:
Infection of human endothelial cells with Epstein-Barr virus.
J Exp Med
182:1213, 1995[Abstract/Free Full Text]
23.
Miller G, Lipman M:
Release of infectious Epstein-Barr virus by transformed marmoset leukocytes.
Proc Natl Acad Sci USA
70:190, 1973[Abstract/Free Full Text]
24.
Lawrence JB, Villnave CA, Singer RH:
Sensitive, high resolution chromatin and chromosome mapping in situ: Presence and orientation of two closely integrated copies of EBV in a lymphoma line.
Cell
52:51, 1988[Medline]
[Order article via Infotrieve]
25.
Hurley EA, Klaman LD, Agger S, Lawrence JB, Thorley-Lawson DA:
The prototypical Epstein-Barr virus-transformed lymphoblastoid cell line IB-4 is an unusual variant containing integrated but no episomal viral DNA.
J Virol
65:3958, 1991[Abstract/Free Full Text]
26.
Henderson A, Ripley S, Heller M, Kieff E:
Chromosome site for the Epstein-Barr virus DNA in a Burkitt tumor cell line and lymphocytes growth transformed in vitro.
Proc Natl Acad Sci USA
80:1987, 1983[Abstract/Free Full Text]
27.
Hurley EA, Agger S, McNeil JA, Lawrence JB, Calendar A, Lenoir G, Thorley-Lawson DA:
When Epstein-Barr virus persistently infects B-cell lines, it frequently integrates.
J Virol
65:1245, 1991[Abstract/Free Full Text]
28.
Gulley ML, Raphael M, Lutz CT, Ross DW, Raab-Traub N:
Epstein-Barr virus integration in human lymphomas and lymphoid cell lines.
Cancer
70:185, 1992[Medline]
[Order article via Infotrieve]
29.
Ernberg I, Falk K, Minarovits J, Busson P, Tursz T, Masucci MG, Klein G:
The role of methylation in the phenotype-dependent modulation of Epstein-Barr nuclear antigen 2 and latent membrane protein genes in cells latently infected with Epstein-Barr virus.
J Gen Virol
70:2989, 1989[Abstract/Free Full Text]
30.
Ernberg I, Kallin B, Dillner J, Falk K, Ehlin-Eriksson B, Hammarskjöld M-L, Klein G:
Lymphoblastoid cell lines and Burkitts-lymphoma-derived cell lines differ in the expression of a second Epstein-Barr virus encoded nuclear antigen.
Int J Cancer
38:729, 1986[Medline]
[Order article via Infotrieve]
31.
Trivedi P, Cuomo L, de Campos-Lima PO, Imreh MP, Kvarnung K, Klein G, Masucci MG:
Integration of a short Epstein-Barr virus DNA fragment in a B95-8 virus converted Burkitt lymphoma line expressing Epstein-Barr nuclear antigens EBNA2 and EBNA5.
J Gen Virol
74:1393, 1993[Abstract/Free Full Text]
32.
Contreras-Brodin BA, Anvret M, Imreh S, Altiok E, Klein G, Masucci MG:
B cell phenotype-dependent expression of the Epstein-Barr virus nuclear antigens EBNA-2 to EBNA-6: Studies with somatic cell hybrids.
J Gen Virol
72:3025, 1991[Abstract/Free Full Text]
33.
Skare J, Strominger J:
Cloning and mapping of BamH1 endonuclease fragments of DNA from the transforming strain B95-8 strain of the Epstein-Barr virus.
Proc Natl Acad Sci USA
77:3860, 1980[Abstract/Free Full Text]
34.
Koide J, Takada K, Sugiura M, Sekine H, Ito T, Saito K, Mori S, Tekeuchi T, Echida S, Abe T:
Spontaneous establishment of an Epstein-Barr virus-infected fibroblast line from the synovial tissue of a rheumatoid arthritis patient.
J Virol
71:2478, 1997[Abstract]
35.
Harabuchi Y, Yamanaka N, Kataura A, Imai S, Kinoshita T, Mizuno F, Osato T:
Epstein-Barr virus in nasal T-cell lymphomas in patients with lethal midline granuloma.
Lancet
335:128, 1990[Medline]
[Order article via Infotrieve]
36.
Shibata D, Weiss LM:
Epstein-Barr virus-associated gastric adenocarcinoma.
Am J Pathol
139:469, 1992[Abstract]
37.
Fåhreus R, Fu HL, Ernberg I, Finke J, Rowe M, Klein G, Falk K, Nilsson E, Yadav M, Busson P, Tursz T, Kallin B:
Expression of Epstein-Barr virus-encoded proteins in nasopharyngeal carcinoma.
Int J Cancer
42:329, 1988[Medline]
[Order article via Infotrieve]
38.
Lee ES, Locker J, Nalesnik M, Reyes J, Jaffe R, Alashari M, Nour B, Tzakis A, Dickman PS:
The association of Epstein-Barr virus with smooth muscle tumors occurring after organ transplantation.
J Exp Med
332:19, 1995
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