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HEMOSTASIS, THROMBOSIS, AND VASCULAR BIOLOGY
From the Divisions of Infectious Disease, Experimental
Medicine, and Hematology/Oncology, Department of Medicine, Beth Israel
Deaconess Medical Center and Harvard Medical School, Boston, MA.
Kaposi sarcoma-associated herpesvirus (KSHV)/human herpesvirus-8
(HHV-8) is causally associated with Kaposi sarcoma (KS). The absence of
a cell culture system that effectively reproduces the composite
mechanisms governing initiation and maintenance of HHV-8 infection
(lytic and latent) in KS endothelial cells, however, has left important
questions unanswered. Here, we report a culture system in which the
earliest events that accompany HHV-8 infection could be surveyed in
primary endothelial cells. Binding of HHV-8 to microvascular dermal
endothelial cells (MVDECs) was directly compared with other primary
target cells implicated in HHV-8-associated diseases. Virus
attachment, fusion, internalization and transport within MVDECs was
monitored by electron microscopy. Studies of genome configuration
revealed that rapid circularization of the viral DNA occurred on entry,
though by 72 hours after infection linear DNAs accumulated and early as
well as late lytic RNAs (T1.1, K8.1) could be detected. The latency
transcripts (LT1/LT2) were first detected on day 8, demonstrating that
both lytic and latent infection were initiated. Although most lytic
transcripts accrued until passage, open-reading frame-74 RNAs
fluctuated with a fixed periodicity, suggesting that early replication
after infection of MVDECs was synchronous.
(Blood. 2002;100:888-896) Kaposi sarcoma-associated herpesvirus (KSHV)/human
herpesvirus-8 (HHV-8) is the first human Many HHV-8-encoded proteins, which contribute to the pathogenesis of
KS, PEL, and MCD, are homologs of cellular genes involved in
inflammation, cell cycle regulation, and angiogenesis.7 Two such proteins are those encoded by open-reading frame (ORF)-74 and
ORF72. The respective proteins are expressed in distinct phases of the
virus life cycle.7 ORF74 encodes a lytic viral G
protein-coupled receptor (vGPCR), which is homologous to human
interleukin-8 receptors.7,8 When injected into mice,
vGPCR-transfected rodent fibroblasts cause spindle cell tumors with
prominent vasculature.7,9 ORF72 encodes a latent viral
cyclin that can activate kinases that inactivate retinoblastoma protein
(pRB), a checkpoint protein that inhibits entry into S
phase.7,10
In the complex lesions of KS, viral gene products are expressed in
endothelial cells, in spindle cells of probable endothelial origin, in
monocytes, and possibly in some infiltrating lymphocytes. The
endothelial cells primarily harbor virus as circular episomes and
synthesize latency-associated gene products, whereas the smaller monocyte subpopulation is productively infected.11,12
Normal primary endothelial cells can be infected with HHV-8 in vitro.
However, the efficiency and outcome of infections have been variable
despite diverse efforts to optimize in vitro culture.13-17 In contrast, herpesvirus infection of relevant primary cells, whether
productive or causing immortalization, is usually robust. Thus, the
recent studies of endothelial cell infection raise several questions
concerning whether a more physiologic target cell remains to be
identified, whether variable transmission in vitro is caused by
technical difficulties, whether in vitro infection is blocked at a
particular phase of the virus life cycle, or whether indeed HHV-8
infection is inefficient when compared with infection by other members
of the human herpesvirus family. To gain a better understanding of the
viral and cellular events that occur upon initiation of infection,
early in vitro transmission of HHV-8 to primary vascular endothelial
cell populations was investigated.
Cells
Virus preparation and labeling
Virus infection Endothelial cells were seeded at 2 × 105 per 100 mm2 tissue-culture dish (Falcon, Franklin Lakes, NJ) and cultured until 40% to 50% confluent. The cells were washed once with phosphate-buffered saline (PBS), overlaid with 2 mL virus suspension that was diluted 1:1 with endothelial cell tissue-culture media, and incubated for 3 hours at 37°C. At the end of the incubation, the cells were washed 2 or 3 times with PBS and reincubated as described above. Cells were harvested at specified time points and processed for preparation of total RNA, DNA, or protein as described below. Cells were split 1:2 or 1:3 on day 10.Antibodies and reagents for immunofluorescence Phycoerythrin (PE)-conjugated monoclonal antibodies (mAbs) used for direct staining and cytometric analysis were as follows: Anti-CD19, anti-CD-3, anti-CD14, and anti-MOPC-21 (control) were from Sigma. Anti-CD16 was from Becton Dickinson (San Jose, CA). Streptavidin-fluorescein conjugate, designated FITC-avidin and used as a control for FITC-HHV-8 staining, was purchased from Biosource (Camarillo, CA). The 2L10, a murine mAb directed to gp350/220, was a gift of Dr Gary Pearson. UPC10, an isotype-matched irrelevant control mAb (immunoglobulin G2a [IgG2a]), was purchased from ICN/Cappel (Aurora, OH). FITC-labeled goat F(ab')2 antimouse IgG was purchased from Biosource.Fluorescence cytometry HHV-8. Purified PBMCs were washed 3 times in RPMI, 2% hi FCS, and 0.1% sodium azide and were incubated with either FITC-HHV-8 or FITC-avidin for 30 minutes on ice. To remove unbound ligand, 2 washes in ice-cold medium containing 2% hi FCS were performed. The cells were reincubated under identical conditions with one of the respective PE-conjugated mAbs: anti-CD3 directed to T cells, anti-CD19 directed to B cells, anti-CD14 directed to monocyte/macrophages, anti-CD16 directed primarily to natural killer (NK) cells, or with a PE-conjugated control antibody (MOPC-21) that has no known specificity for human cells. Following the second incubation, cells were washed in media 3 additional times, fixed with 2% paraformaldehyde in media, and analyzed by cytometry on a FACScan (Becton Dickinson) (FITC, FL1 channel; and PE, FL2 channel). Cytometric analyses of the purified PBMCs with the respective PE-conjugated antibodies and the PE-conjugated control were performed prior to definitive experiments to optimize the setting of gates. Adherent cells (fMVDECs, HUVECs, and 293 cells) were removed from tissue-culture dishes by incubation in media containing 2 mM EDTA at 37°C for 10 minutes. The cells were pipetted gently 3 times to assure complete detachment and then washed 3 times in media containing 2% hi FCS and 0.1% sodium azide prior to staining with FITC-HHV-8 or FITC-avidin as described above. EBV. Suspended cells (fMVDECs, HUVECs, 293 cells, and JY-B-cell line) were incubated with purified EBV for 30 minutes on ice, washed twice, and reincubated with either mAb 2L10 directed to EBV membrane glycoprotein 350 or mAb UPC10 (control IgG2a antibody) for another 30 minutes on ice. They were then rewashed twice and reincubated with FITC-goat F(ab')2 anti-mouse IgG for 30 minutes on ice, washed 2 additional times, fixed, and analyzed as described above. Electron microscopy The fMVDECs were infected with HHV-8 or were mock-infected for 1 hour at 37°C. The supernatant was discarded, and the cells were rinsed 3 times in PBS to remove unbound virus. The cell monolayer was covered with 2% glutaraldehyde in 0.1 M cacodylate buffer and stored at 4°C. The monolayer was subsequently imbedded in situ in Epon resin, postfixed in 1% osmium tetroxide, dehydrated in a graded series of solutions of ethanol and propylene oxide, cut into thin sections, and reimbedded in Epon resin. The thin sections were stained with uranyl acetate and lead citrate and were examined on a JEOL 100cx transmission electron microscope (JEOL USA, Peabody, MA).Polymerase chain reaction-based in situ lysis hybridization BCBL-1 cells (uninduced or induced with 3 mM sodium butyrate for 72 hours) and fMVDECs (uninfected or infected with HHV-8 for various times) were harvested, lysed in wells, and electrophoresed through in situ lysis gels as described.25 A grid was created and gel slices were prepared. DNA was extracted from the individual slices, resuspended, and aliquoted as described.26 DNA polymerase chain reaction (PCR) was performed with upstream and downstream oligonucleotide primers (described below) that amplified a 394-base pair (bp) fragment from the genomic region encoding T1.1.27,28 The conditions were 94°C for 3 minutes, 35 cycles of 94°C for 1 minute, 62°C for 1 minute, 72°C for 1 minute, and a final extension step at 72°C for 7 minutes. The entire amplified product from each of the slices was electrophoresed through a 1% agarose gel (left to right on the agarose gel correlated with top to bottom slices of the in situ lysis gel), transferred to nitrocellulose, and probed with a 32P-labeled T1.1 complementary DNA (cDNA) (described below) generously provided by Dr Don Ganem (University of California-San Francisco, CA).28 The relative positions of migration of covalently closed circular versus linear HHV-8 genomes derived from BCBL-1 were determined in all experiments as a positive control. Uninfected fMVDECs were included in all experiments as a negative control.Probes and RNA blot hybridization Probes used for detection of total RNA or DNA by blot hybridization were as follows: for detection of T1.1, also known as polyadenylated nuclear RNA (PAN) or nut-1, ORFK7, a 1.1-kilobase (kb) cDNA EcoRI-XhoI fragment excised from pBS-T1.1 generously provided by Don Ganem was used. For detection of glyceraldehyde-3-phosphate dehydrogenase (GAPDH), a cDNA clone, pHcGAP,29 was obtained from the ATCC. To detect K8.1 (gp35/37), a 750-bp cDNA fragment isolated by reverse-transcription PCR (RT-PCR), as described below, was used. For detection of latent transcript 1 (LT1) and LT2,30 a 795-bp cDNA fragment encoding ORF72, the viral cyclin (vCYC) was synthesized by RT-PCR as described below. A 1045-bp cDNA probe was synthesized for detection of ORF74, the vGPCR, as described below. The BCBL-1 cell line was used as the source for total RNA in these syntheses. All probes were random prime-labeled as described previously.31 Total RNA was isolated, and RNA blot hybridization was performed as previously described.31RT-PCR analysis Total RNA (0.5 µg), isolated at various times from relevant primary cells and cell lines, was first treated with RQ1 DNAse (Promega, Madison, WI) as recommended by the manufacturer. The RNA was then reverse transcribed and sequentially amplified by means of the GeneAmp RNA PCR kit (Perkin-Elmer, Foster City, CA) according to directions provided by the manufacturer. Standard amplification conditions were 94°C for 3 minutes, 35 cycles of 94°C for 1 minute, annealing temperature for 1 minute, and 72°C for 1 minute, followed by 7 minutes' final extension at 72°C. Primers for KS330,1 ORF29,32 K8.1,33 and GAPDH34 are described in the respective references cited here. The remaining primers were as follows. ORF72 (vCYC): sense, 5'-GGAATTCCTATATGGCAACTGCCAAT-3'; antisense, 5'TCACAAGCTTAATAGCTGTCCAGAAT-3'. ORF74 (GPCR): sense, 5'-CCCAAGCTTATGGCGGCCGAGGATTTCCTA-3'; antisense, 5'-GGAATTCCTACGTGGTGGCGCCGGACAT-3'. T1.1 (PAN, nut1, ORFK7): sense, 5'-TTGGCTGCCGCTTCACCTAT-3'; antisense, 5'-CACCAGTGGGCGCTGCTTTC-3'.Amplified cDNAs were separated on a 1% agarose gel, transferred to nitrocellulose membranes by means of a Turboblotter downward transfer system (Schleicher and Schuell, Keene, NH), and detected with 32P-labeled probes made by the random priming method.31
Differential attachment of HHV-8 to primary microvascular endothelial cells, PBMCs, and the 293 epithelial cell line To explore the relationship of cellular attachment to HHV-8 entry, filtered and concentrated virus from the supernatant of the BCBL-1 cell line was labeled with FITC and was column purified. Binding of FITC-HHV-8 to primary PBMCs, fMVDECs, and the 293 cell line was assessed by flow cytometry. PE-conjugated mAbs were used to gate on PBMC subpopulations, permitting independent identification of B-cell (anti-CD19), T-cell (anti-CD3), monocyte (anti-CD14), and NK-cell (anti-CD16) subpopulations in identical assays. As shown in Figure 1, FITC-HHV-8 bound to the majority of peripheral blood B cells and monocytes, demonstrated by the relative number of virus-bearing cells (block) located to the right and outside of the negative control (FITC-avidin) curve (line). Comparative attachment of FITC-virus to T cells and NK cells was significantly less. Of note, FITC-HHV-8 bound to virtually all fMVDECs, exceeding virus attachment to either B cells or monocytes (Figure 1). In addition, the change in peak fluorescence of fMVDECs bearing FITC-virus compared with FITC-avidin (autofluorescence control) was greater than the corresponding change in peak fluorescence of the other cell populations studied. These results not only indicated that a greater number of fMVDECs bound virus, but also showed that fMVDECs contained a larger number of virus attachment sites per cell. Although the related -herpesvirus EBV readily bound to the surface of B-lymphoblastoid
cells, EBV did not bind to fMVDECs (Figure 1, bottom). Binding of HHV-8
and EBV to HUVECs was similar to binding to fMVDECs (not shown). The
293 cells are susceptible to HHV-8 infection; however, in a
representative experiment (Figure 1, bottom left), attachment of
FITC-virus to these cells was comparatively low. Virus attachment to
293L cells (a clonal derivative of 293 epithelial cells reported to be
more susceptible to HHV-8 infection than the parent
line21) was similar. Unlabeled virus blocked binding of
FITC-HHV-8 to all cell populations in a concentration-dependent manner, indicating that attachment based on competition-binding assay
was specific (not shown).
Electron-microscopic analyses of attachment and internalization of HHV-8 To visually confirm the attachment of HHV-8 to fMVDECs and to delineate the cellular events associated with virus entry, fMVDECs were incubated with HHV-8 at 37°C for 1 hour. Although precise knowledge of herpesvirus entry is limited, it is believed that herpesviruses enter cells by fusion of the viral envelope with the plasma membrane, resulting in the release of tegument proteins and the nucleocapsid into the cytoplasm, or alternatively by endocytosis followed by nucleocapsid release through the endosomal membrane.35-37 Of note, in the case of herpes simplex virus-1 (HSV-1), it has been suggested that entry by endocytosis may not result in productive infection.37 It was predicted that at the 1-hour time point, diverse events related to virus entry and uncoating might be concurrently observed,38 documenting that transport within fMVDECs followed attachment. Figure 2 confirms that virions at various stages of intracellular transport within distinct fMVDECs could be readily observed by EM at 1 hour after infection. Figure 2A depicts a single cell harboring multiple virions at different stages along the entry pathway. The large micrograph in Figure 2A and the right inset show surface attachment of electron-dense virions measuring, on average, approximately 110 nm, in agreement with the reported size range of enveloped herpesvirions (~80-250 nM).39-44 Size bars are indicated, as the fine structure of these virions cannot be appreciated. The virus particles, in nearly linear array, are bound to the exposed surface of the fMVDECs, but not to the cell surface that is attached to the culture plate. A single virion (inset) as well as clusters of virions could be observed, whereas no similar structures were detected in uninfected cells (not shown). Virions enclosed within a thin-walled cytoplasmic vacuole could be seen between the plasma membrane and nucleus in Figure 2A, left inset. A structure suggestive of a disintegrating nucleocapsid at the nuclear-cytoplasmic border was also visible (Figure 2A, arrow, right inset).37,41 In Figure 2B, a virion appears to be fusing with a cellular membrane, probably the plasma membrane,35,37,42 as invagination from the cell surface could be observed in a larger micrograph (not shown). Figure 2C and 2D each show a de-enveloped nucleocapsid that has penetrated into the cytosol. Decondensation of the tightly packaged genome, a typical feature that distinguishes virions entering the cell from newly synthesized exiting virions, was observed.37,42 Figure 2D further demonstrates the nucleocapsid in close proximity to microtubular systems, the likely transport mechanism, as has been observed for other herpesviruses.37,38 Although free nucleocapsids were present in the cytosol, some virions were clearly contained within cytoplasmic vesicles, probably endosomes, as shown in Figure 2A, left inset, and in Figure 2E. Disintegrating nucleocapsids and empty capsids could also be identified at the nuclear membrane at 1 hour (not shown).41,43,44
The state of the viral genome during initial infection of fMVDECs In cells latently infected with HHV-8, viral DNA persists in the form of covalently closed circular episomes (CCCs), whereas in productively infected cells, linear DNA accumulates as virus replicates by a rolling circle mechanism. The configuration of the virus genome in infected cells can be distinguished by electrophoresis of extrachromosomal DNA through in situ lysis gels and can be verified by DNA blot hybridization. Application of PCR technology to DNA extracted from consecutive gel slices has enhanced the sensitivity of this procedure.26To examine the genome configuration of HHV-8 after infection of
fMVDECs, cell lysates were prepared before and at various times after
virus infection, electrophoresed through in situ lysis gels, and
analyzed by DNA PCR of sequential slices. A nonrepetitive genomic
subfragment of 394 bp from T1.1 was amplified in these experiments
("Materials and methods"). The relative migration of circular
versus linear HHV-8 genomes was analyzed by comparing lysates from
latently infected BCBL-1 cells with BCBL-1 cells induced to produce
HHV-8. During latency, nearly all genomes were present as CCCs (Figure
3A, left, top) whereas, following
induction of lytic replication, linear DNAs accumulated (Figure 3A,
left, bottom). Because only a subset of BCBL-1 cells were sensitive to
induction,45 both circular and linear forms of HHV-8
persisted after treatment with butyrate (Figure 3A, left, bottom). When fMVDEC lysates were analyzed prior to HHV-8 infection, no PCR product
could be detected (Figure 3A, right, top panel), demonstrating that the
cells were free of endogenous virus and that the PCR reaction was
specific. PCR-based in situ lysis gel analysis of infected fMVDECs
performed 24 hours later (ie, for 21 hours after a 3-hour virus
incubation) revealed HHV-8 genomes almost exclusively in the form of
CCCs (Figure 3A, right, middle panel). In fact, circular genomes were
readily detected as early as 8 hours after entry (Figure 3B), as shown
in a separate experiment. These results demonstrated that linear virion
DNAs introduced at the time of entry into fMVDECs rapidly circularized.
However, by 72 hours after infection, the genome configuration of HHV-8
in infected fMVDECs had clearly shifted. A mixed pattern consisting of
both circular and linear genomes, similar to that observed after BCBL-1 induction, was observed (Figure 3A, right, bottom). This rapid evolution of the configuration of genomic DNAs following transmission of HHV-8 to fMVDECs demonstrated that primary infection was complex and
dynamic. Concurrent detection of CCCs and linear DNAs indicated that
both lytic and latent infections were initiated shortly after exposure
to virus (Figure 3B).
Viral transcripts associated with lytic replication after HHV-8 infection of fMVDECs Total RNA prepared from fMVDECs was analyzed just prior to virus infection, on sequential days after infection, and 9 days after the first passage ("Materials and methods") (Figure 4). T1.1 encodes a polyadenylated nuclear RNA of unknown function, which is highly transcribed during the HHV-8 lytic cycle.27,28,45 Figure 4A, top, shows that T1.1 could be readily detected by Northern blot hybridization, indicating that lytic RNAs were more rapidly and effectively transcribed following HHV-8 infection of fMVDECs than had been demonstrated. Steady-state levels of T1.1 RNAs increased throughout the 10 days of primary infection (Figure 4A), suggesting that infection spread through the cell population. RNAs specific for late antigens, such as the virion envelope glycoprotein gp35/37 encoded by genomic fragment K8.1,33,46,47 also increased during this period, as evidenced by appearance of a major 0.7-kb RNA (Figure 4B). Additional lytic transcripts, ie, ORF26 (early), KS Bam330 (late), and ORF29 (late),7 which were analyzed by RT-PCR, could be readily detected (not shown).
Interestingly, RT-PCR analysis of RNAs encoded by ORF74, the lytic
cycle vGPCR,8,9,48 displayed cyclic variation in the
relative abundance of these RNAs on sequential days (Figure 4C, top)
when compared with a GAPDH control in the same experiment (Figure 4C,
bottom). The level of steady-state transcripts of this gene fluctuated
with a periodicity of approximately 48 to 72 hours, consistent with the
duration of a typical The oligonucleotide primers synthesized to reverse-transcribe the ORF74 coding sequence 129372-130400,50 generated 2 PCR fragments, the expected 1045-bp fragment as well as an approximately 850-bp fragment (Figure 4C). Splicing of a potential exon between 130116 and 130336, inclusive, could generate an additional 857-bp fragment,48,49 the size of the second fragment observed. Taken together, these results demonstrate that abundant transcription of lytic cycle genes accompanies initial infection of fMVDECs with HHV-8. Detection of HHV-8 transcripts associated with latency by RNA blot hybridization The transcriptional program associated with HHV-8 persistence or latency is complex and differs in distinct cell types.50-53 Moreover, latent herpesviral RNAs are often less abundantly transcribed than lytic transcripts.7,27 The HHV-8 cyclin (vCYC) encoded by ORF72 constitutes a predominantly latent-cycle product in both immortalized B lymphocytes (PEL lines) in vitro53,54 and spindle cells (KS biopsies) in vivo.55 In PEL lines, 2 major latent transcripts of 6 kb and 2 kb, known as LT1 and LT2 respectively, encode vCYC. As seen in Figure 5A (and Figure 4), expression of the abundant lytic transcript T1.1 could be detected by RNA blot hybridization beginning at day 3 to 4 after HHV-8 infection of fMVDECs and was more strongly detected after 8 days. When a cDNA probe encoding the entire ORF72 reading frame was used to reprobe the identical blot, LT1 and LT2 transcripts of characteristic size, although undetectable at 3 days, were apparent by day 8 (Figure 5B, top) (a minor 1-kb fragment additionally detected in some PEL lines upon hybridization with an ORF72 probe was not assessed).56 Thus, both lytic and latent transcripts could be detected after the end of the first week in culture.
MVDECs from distinct tissues and HUVECs support efficient HHV-8 infection, whereas 293 cells do not To determine whether other primary vascular endothelial cell populations were susceptible to HHV-8 infection and to assess whether significant differences in susceptibility to infection existed among these cell populations, adult bMVDECs, mMVECs, HUVECs, as well as 293L cells (a clonal derivative of 293 epithelial cells reported to be more susceptible to HHV-8 infection than the parent line21) were analyzed by RNA blot hybridization following HHV-8 infection. As shown in Figure 6A-B, bMVDECs and mMVECs as well as HUVECs could be efficiently infected, as demonstrated by the cumulative detection of steady-state T1.1 RNAs from days 3 and 4 to day 8 after infection. Major differences in viral gene transcription were not detected between the different sources. In contrast, no RNA could be detected in 293L cells by RNA blot hybridization (Figure 6A) although, as previously reported,21 transcripts were detectable by RT-PCR. Figure 6A, bottom inset, shows detection of the 394-bp T1.1 fragment during the first 4 days after infection; although the fragment did not persist to day 7, its presence is consistent with the prior suggestion that virus titer was not the limiting factor in efficient infection of 293 cells.32 Comparison of different lots of MVDECs (Figure 6C, left and right) further revealed that there was variation in the infectivity of cells from the distinct lots controlled for the same passage. As shown in Figure 6C, infection under identical conditions with the same virus preparation (either VP2 or VP3) at 2 different dilutions resulted in increased production of T1.1 RNA in the fMVDEC lot displayed on the right as compared with that on the left. The current results demonstrate that vascular endothelial cells derived from diverse tissues can support initial infection and lytic transcription of HHV-8 and that no major differences were detected among the cell populations studied.
Since its discovery in 1994, substantial information has accumulated about the biology of HHV-8 in KS on the basis of analyses of biopsy specimens and investigations of isolated viral genes. The absence of an appropriate culture system that effectively duplicates the composite mechanisms believed to govern the initiation and maintenance of HHV-8 infection (lytic and latent) in KS endothelial cells, however, has left many questions about pathogenesis unresolved. Although infections of several cell types have been carefully documented, they have proved relatively inefficient and often self-abort. In this report, we provide evidence that the initial events that occur upon HHV-8 infection of normal vascular endothelial cells in vitro are efficient. In addition, we examine the cell biology of the virus-cell interactions that occur at these earliest time points. HHV-8 attachment, internalization, genome configuration, and patterns of viral gene expression during initial infection were surveyed in normal primary fMVDECs and compared with those of other susceptible endothelial populations. The results of this study demonstrate the usefulness of primary vascular endothelial cell culture for studying virion entry and for investigating the cellular and viral events regulating initiation of HHV-8 transcription. Although many cell types susceptible to HHV-8 infection have been
identified, little is known about their relative ability to bind virus.
Attachment of HHV-8 to the cell populations targeted by KSHV, which
subsequently become involved in virus-associated diseases such as PEL
and MCD, has not been characterized. Although we observed that
FITC-virus attached to all of the cell populations examined, we
identified a highly reproducible rank order for binding: greatest for
fMVDECs, intermediate for B cells or monocytes, and significantly less
for T/NK cells. Interestingly, this rank order reflects the
known cellular tropism of HHV-8 in pathologic specimens from patients
with HHV-8-associated disease (reviewed in Moore and
Chang7). These observations suggest that receptor density may be a salient determinant of susceptibility to HHV-8 infection and
are consistent with recent studies suggesting that low-affinity interactions between several viral membrane proteins and widely expressed cell surface glycosaminoglycans, such as heparan sulfate, constitute the initial HHV-8-binding event.17,57 A high
density of low-affinity cellular receptors could compensate for the
absence of a single high-affinity attachment receptor such as that
found for the related EM analysis with HHV-8 confirmed that virions attached to multiple
sites on the exposed endothelial cell surface, providing visual
evidence that these virions rapidly fused with cellular membranes and
became internalized into the cytosol or cytoplasmic vesicles, probably
endosomes. Because Although complex and potentially novel patterns of HHV-8 gene transcription were observed after virus entry, a temporal analysis that coordinated viral genome structure with the appearance of specific RNAs provided clear evidence that both lytic and latent infection were initiated. The stable lytic cycle RNAs T1.1 (early) and K8.1 (late) could be detected by RNA blot hybridization at 72 hours and accrued until passage, whereas ORF74 RNAs (early lytic) fluctuated on sequential days. Assessment of a primary infected culture during a 9-day time interval revealed alternating cycles of ORF74 RNA detection with a periodicity typical of herpesvirus replicative cycles (48 to 72 hours). This suggested that the initial rounds of lytic replication were synchronous. ORF74 transcripts have been shown to be early lytic RNAs, detectable only between 20 and 30 hours after lytic cycle induction of a PEL cell line.63 Their alternating pattern of expression in newly infected fMVDECs was highly suggestive that replication was synchronous, as this pattern could not otherwise have been identified. ORF74 encodes a vGPCR that, when expressed independently of virus signals constitutively as well as in response to certain chemokines, up-regulates vascular endothelial growth factor and, in animal models, induces angiogenesis of endothelial cells.9,64-68 In KS lesions, vGPCR is hypothesized to drive proliferation of neighboring cells; however, vGPCR is expressed only in lytically infected cells, which are the minority, and for a limited window of time. The role of ORF74 in KS pathogenesis and specifically in facilitating lytic replication remains unknown. Detection of the latent vCYC RNA by RNA blot hybridization later in the course of the same primary infection additionally suggested that a potentially immortalizing HHV-8 infection was concurrently or consecutively established. The detection of the vCYC encoded by the latent ORF72 is important in that vCYC inactivates pRB, the checkpoint protein that inhibits entry into S phase.10,69-74 By manipulating the host cell cycle, HHV-8 contributes to cell immortalization and tumorigenesis. Although several groups have now reported HHV-8 infection of MVDECs, robust initiation and durable maintenance of immortalization in culture systems has remained elusive.13-17 MVDECs immortalized with the human papilloma virus-16 oncoproteins E6 and E7 have also been shown to support establishment and effective spread of HHV-8 latency; however, the modifications of cell cycle regulation and apoptosis by E6 and E7 potentially complicate the studies of the unique contributions by HHV-8. The current studies demonstrate that HHV-8, concentrated and devoid of inducing agent, obtained from the PEL line BCBL-1, efficiently mediates viral entry and transcriptional initiation of a mixed lytic and latent infection in cultured vascular endothelial cells. The model presented in this study will facilitate detailed analysis of early pathogenic events relevant to the development of KS.
We thank Michael Gill for critical evaluation of the manuscript, Larry Coffin for computer assistance, Don Ganem for supplying pBS T1.1, and Dan Brown of the EM facility at Beth Israel Deaconess Medical Center.
Submitted August 9, 2000; accepted March 25, 2002.
Supported by National Institutes of Health grants P30AR42689 (Pilot Project), R01DE12186, and K24CA85083, and by an Established Investigator Award from the American Heart Association.
The publication costs of this article were defrayed in part by page charge payment. Therefore, and solely to indicate this fact, this article is hereby marked "advertisement" in accordance with 18 U.S.C. section 1734.
Reprints: Joyce D. Fingeroth, Harvard Institutes of Medicine, 4 Blackfan Circle, Room 353, Boston, MA 02115; e-mail: jfingero{at}caregroup.harvard.edu.
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Abstract
Introduction
80°C freezer until use. Gradient-purified HHV-8 was fluorescein
isothiocyanate (FITC)-conjugated, as previously described for
EBV,
as has
been observed for other members of the herpesvirus
family.
-herpesviruses