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BRIEF REPORT
From Partners AIDS Research Center, Massachusetts
General Hospital, Charlestown, and the Department of Adult Oncology,
Dana Farber Cancer Institute, Harvard Medical School, Boston, MA; the
Department of Epidemiology and Biostatistics, University of California,
San Francisco; and the Departments of Microbiology and Medicine, Myles
H. Thaler Center for AIDS Research, University of Virginia Health
Systems, Charlottesville.
Kaposi sarcoma-associated herpesvirus (KSHV) has been associated
with several diseases, but the association between KSHV and multiple
myeloma (MM) remains controversial. To address this issue, we studied
patients with MM for the presence of viral RNA transcripts as well as
KSHV-specific cellular immune responses. Highly sensitive reverse
transcription-polymerase chain reaction assays for detection of viral
transcripts of KSHV open reading frame (ORF) 26, ORF72, and ORF74 did
not detect viral gene transcripts in long-term cultures of bone marrow
stromal cells from 23 patients with MM. Moreover, sensitive assays for
KSHV ORF65-specific and ORF73-specific cytotoxic T-lymphocyte (CTL)
activity that readily and routinely detect CTLs specific for ORF65 and
ORF73 in patients positive for human immunodeficiency virus and KSHV
did not show any specific responses in 16 patients with MM, despite the
presence of positive Epstein-Barr virus-specific CTLs in all cases.
These data therefore do not show a biologically important association
between ongoing KSHV infection and MM.
(Blood. 2002;100:698-700) Since the initial discovery of Kaposi
sarcoma-associated herpesvirus (KSHV) in Kaposi sarcoma (KS) tissue,
seroepidemiologic studies have associated this virus with KS,
multicentric Castleman disease, and primary effusion
lymphomas.1 In contrast, since the first detection of KSHV
DNA in long-term cultured bone marrow stromal cells from patients with
multiple myeloma (MM), the association between KSHV and MM has remained
controversial.2-6 Different explanations have been offered
to account for inconsistencies in seroepidemiologic and virologic
studies searching for an association of KSHV with MM, including the
presence of viral variants. Indeed, Ma et al7 reported
unique KSHV open reading frame (ORF) 65 sequences that were detected
exclusively in patients with MM but not in patients without MM who were
seropositive for KSHV. Interestingly, in some MM patients, a
mutation at the C-terminal end of ORF65 resulted in an extension
of the ORF by 33 amino acids. These sequences were found only in
samples from patients with MM and were suggested as a possible unique
target of KSHV serologic immune responses in such patients, who lack
seroreactivity against the "conventional" ORF65
protein.2-5
To investigate whether MM is associated with KSHV infection, we
assayed 38 patients with MM for the presence of viral transcripts, virus-specific cellular immune responses, or both, including immune reactivity against this novel, MM-specific ORF65 protein sequence. Our
findings do not support the hypothesis that an association of KSHV and
MM has a biologic relevance.
Patients
Detection of KSHV transcripts by reverse
transcription- polymerase chain reaction (RT-PCR) assay
Synthetic peptides Overlapping peptide sets spanning the entire KSHV ORF 65 and ORF 73 amino acid sequence were synthesized as 22-mer peptides overlapping by 15 amino acids. The sequence of these peptides was based on the previously reported KSHV viral sequence from the KSHV-infected BC-1 cell line.9 In addition, 5 22-mer peptides were synthesized that correspond in sequence to the previously described, MM-unique 33-amino acid sequence at the C-terminal end of KSHV ORF65 (TLSSTTETAPPRWPTRGNPPLA, PRWPTRGNPPLAKRNRQRLDNR, LAKRNRQRLDNRGVTSTTSLFC, DNRGVTSTTSLFCQPSPPGTPIG, SLFCQPSPPGTPIGRPLFV).7 Control peptides derived from Epstein-Barr virus (EBV) were selected from previously described cytotoxic T-lymphocyte (CTL) epitopes.10 Up to 36 EBV control peptides were included per EBV control pool. All KSHV-encoded peptides were placed into pools containing 4 to 7 peptides and used at a final concentration of 10 µg/mL per individual peptide in enzyme-linked immunospot (ELISPOT) assays.ELISPOT analysis ELISPOT assays were performed by using frozen peripheral blood mononuclear cells (PBMCs) that were thawed overnight, counted, and plated at 1 × 105 to 2 × 105 cells/well.11 The cells were incubated in duplicate wells for 16 hours with and without the peptide pools, and the plates were then washed and developed, as described previously.11 Responses were considered positive when they were increased at least threefold above those of the no-antigen controls and when at least 3 spots/well were detectable. Thus, the lower cutoff level for specific responses was 15 antigen-specific cells/106 PBMCs. CD4 and CD8 T-cell separations were done to verify that all responses detected were mediated by CD8+ T cells (data not shown).
Our previous studies showed that in 88% of cases, KSHV gene sequences can be amplified from DNA isolated from LT-BMSCs and peripheral blood dendritic cells obtained from patients with MM.5,6,12 However, positive PCR results were also obtained with DNA in up to 37% of our samples from healthy donors. These results suggested that KSHV could be involved in MM, but our incidence of KSHV detection exceeded current serologic estimates for the general population several-fold.13 Although these results were based on detection of DNA using a nested PCR approach and may represent nonspecific amplification products, detection of KSHV DNA in these samples in the absence of serologic evidence suggested 3 other possibilities: 1) the KSHV virus was present but in quantities too low to induce a serologic response; 2) a KSHV variant is associated with the pathogenesis of MM; or 3) KSHV is not associated with MM. Because our previous studies were designed to detect KSHV-specific sequences in as little as 0.01 pg total DNA (corresponding to 1 viral copy in 1 × 103 cells12), the very low copy number could explain the lack of serologic reactivity in patients with MM. Furthermore, sequence variability, such as the reported MM-specific ORF65 sequence, also could account for why KSHV was not detected in serum from MM patients.7 However, it seems unlikely that none of the serologic targets of KSHV would be conserved in patients with MM. We therefore further analyzed patients with MM for the presence of
viral transcripts to assess active viral replication by performing
RT-PCR. Eighty percent of these patients had DNA amplified for
KSHV-specific gene products in previous studies.5 KSHV gene sequences, however, were identified only on nested PCR and not on
first-round PCR. RT-PCR for KSHV ORF26, ORF72, and ORF74 was performed
with RNA samples isolated from LT-BMSCs from 23 patients with MM, as in
previous studies.6,9 After RT and PCR amplification, none
of these samples yielded any positive PCR product (Figure
1). These data suggest that no active
viral gene transcription had occurred in these patients, even in
LT-BMSCs assayed after prolonged in vitro culture, as was necessary to obtain positive PCR products in all previous studies. These results support the hypothesis that active KSHV infection is not associated with MM.
In addition to these molecular analyses, we also conducted assays for
virus-specific immune responses in the MM patients. Because our
previous studies had shown that no serologic responses were detectable
in MM patients,5,6 we next assayed cellular KSHV-specific
immune responses. Thus, PBMCs from 16 patients with MM were tested in
an ELISPOT assay for specific reactivity against a panel of overlapping
peptides spanning the KSHV ORF73 amino acid sequence, as well as the
ORF65 sequence with the 33 MM-KSHV unique residues.14 Of
these 16 patients, 12 were included in our analysis of viral
replication (Figure 1). No significant immune responses against these 2 proteins were detectable in these patients with MM, despite positive
responses against EBV-derived control peptides (Table
1). In contrast, strong ELISPOT
responses against ORF73 and ORF65 were detected in the KSHV-positive
controls. Interestingly, very weak responses against the reported
MM-specific 33-amino acid-long extension of the ORF65 sequence were
detected in 2 of 14 controls seropositive for KSHV, despite significant
responses against the ORF65 sequence derived from the BC-1 cell line.
EBV-specific CTL responses were also measured to provide a positive control in the ELISPOT assay to confirm immune competence in these patients. In the current study, only those with a positive EBV response were included; however, an additional 11 patients with MM who did not respond to the EBV-positive control were tested and excluded. The unresponsiveness to EBV does not necessarily reflect immune incompetence, because these patients represented a broad range of different HLA alleles examined by using one set of defined, HLA class I-restricted CTL epitopes.10 Nevertheless, the nonresponders to EBV analyses excluded from these analyses were also all negative for KSHV-specific CTL reactivity. The lack of significant CTL responses specific for KSHV ORF65 and ORF73 in patients with MM, coupled with the inability to detect viral transcripts against ORF26, ORF72, and ORF74, suggest that KSHV does not play an important role in the pathogenesis of MM. However, our conclusions have some limitations. First, the level of viral replication may be very low and not detectable with the sensitive RT-PCR method used. Such low-level viral replication could also lead to an antigenic load insufficient for induction of humoral and cellular immune responses. Second, it has been suggested that a variant of KSHV that does not induce a humoral immune response detectable by available serologic tests is present in patients with MM.4,7 However, our data suggest that these possibilities are unlikely, because very sensitive RT-PCR analyses, with a detection limit of 1 viral copy in 10 × 103 cells, was performed by using primers specific for 3 different KSHV genes.6,12 To avoid detection by this RT-PCR, the virus in patients with MM would have to be changed in all these locations and represent a very distant relative of KSHV. Moreover, if all those KSHV proteins that have been shown to be targeted by humoral or cellular immune responses were either altered or completely absent in the virus associated with MM, the elusive infectious agent would likely be unrelated to the KSHV described by Chang et al in 1994.15 Nevertheless, to examine such a possibility, we included the recently described ORF65 sequence unique to patients with MM7 in the ELISPOT analyses. No specific responses were detected in any of our patients with MM. Although we cannot rule out the possibility that ongoing viral replication was insufficient to maintain detectable memory CTL responses against the lytic ORF65 protein, one would expect to detect at least some responses against the latent gene product of ORF73, which is required for viral genome persistence.8,16 Although we cannot completely rule out the existence of a KSHV-related virus in patients with MM, the current findings constitute a strong indication that there is no ongoing KSHV viral replication in these patients at a level sufficient to induce humoral or cellular CTL responses. The apparent lack of viral transcripts in samples from MM patients, coupled with the absence of cellular immune responses readily and generally detectable in patients infected with KSHV, provide strong evidence against an association between KSHV and the pathogenesis of MM.
Submitted October 23, 2001; accepted February 11, 2002.
Supported by National Institutes of Health Grants RO-1 50947 and PO-1 78378, the Multiple Myeloma Research Foundation (N.R., D.H., and T.H.), and the Doris Duke Distinguished Clinical Research Scientist Award (K.C.A.).
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: Kenneth C. Anderson, Jerome Lipper Multiple Myeloma Center, Department of Adult Oncology, Dana Farber Cancer Institute, 44 Binney Street, Boston, MA 02115; e-mail: kenneth_anderson{at}dfci.harvard.edu.
1. Cesarman E, Knowles DM. Kaposi's sarcoma-associated herpesvirus: a lymphotropic human herpesvirus associated with Kaposi's sarcoma, primary effusion lymphoma, and multicentric Castleman's disease. Semin Diagn Pathol. 1997;14:54-66[Medline] [Order article via Infotrieve].
2.
Rettig MB, Ma HJ, Vescio RA, Pold M, et al.
Kaposi's sarcoma-associated herpesvirus infection of bone marrow dendritic cells from multiple myeloma patients.
Science.
1997;276:1851-1854
3.
Cathomas G, Regamey N, Stalder A, Kurrer M, Joller-Jemelka H, Erb P.
Multiple myeloma and HHV-8 infection.
Blood.
1998;91:4391-4392 4. Said JW, Heppner K, Shintaku IP, et al. Multiple myeloma and HHV-8 infection. Blood. 1998;91:4392-4393.
5.
Chauhan D, Bharti A, Raje N, et al.
Detection of Kaposi's sarcoma herpesvirus DNA sequences in multiple myeloma bone marrow stromal cells.
Blood.
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Raje N, Gong J, Chauhan D, Teoh G, et al.
Bone marrow and peripheral blood dendritic cells from patients with multiple myeloma are phenotypically and functionally normal despite the detection of Kaposi's sarcoma herpesvirus gene sequences.
Blood.
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Ma HJ, Sjak-Shie NN, Vescio RA, et al.
Human herpesvirus 8 open reading frame 26 and open reading frame 65 sequences from multiple myeloma patients: a shared pattern not found in Kaposi's sarcoma or primary effusion lymphoma.
Clin Cancer Res.
2000;6:4226-4233 8. Kedes DH, Operskalski E, Busch M, Kohn R, Flood J, Ganem D. The seroepidemiology of human herpesvirus 8 (Kaposi's sarcoma-associated herpesvirus): distribution of infection in KS risk groups and evidence for sexual transmission. Nat Med. 1996;2:918-924[CrossRef][Medline] [Order article via Infotrieve].
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Russo JJ, Bohenzky RA, Chien MC, et al.
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Goulder P, Altfeld M, Rosenberg E, et al.
Substantial differences in specificity of HIV specific cytotoxic T cells in acute and chronic HIV infection.
J Exp Med.
2001;193:181-194 12. Raje N, Kica G, Chauhan D, et al. Kaposi's sarcoma-associated herpesvirus gene sequences are detectable at low copy number in primary amyloidosis. Amyloid. 2000;7:126-132[Medline] [Order article via Infotrieve].
13.
Martin JN, Ganem DE, Osmond DH, Page-Shafer KA, Macrae D, Kedes DH.
Sexual transmission and the natural history of human herpesvirus 8 infection.
N Engl J Med.
1998;338:948-954 14. Brander C, Goulder P. The evolving field of HIV CTL epitope mapping: new approaches for the identification of novel epitopes. In: Korber B,Brander C,Walker B, et al., eds. HIV Molecular Immunology Database. Part IV. Los Alamos, NM: Los Alamos National Laboratory, Theoretical Biology and Biophysics; 2000:1-18.
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Chang Y, Cesarman E, Pessin MS, Lee F, Culpepper J, Knowles DM, Moore PS.
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© 2002 by The American Society of Hematology.
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  W. Chen, Q. Huang, C. W. Zuppan, E. H. Rowsell, J. D. Cao, L. M. Weiss, and J. Wang Complete Absence of KSHV/HHV-8 in Posttransplant Lymphoproliferative Disorders: An Immunohistochemical and Molecular Study of 52 Cases Am J Clin Pathol, May 1, 2009; 131(5): 632 - 639. [Abstract] [Full Text] [PDF]
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 A. Kreuter, S. Bischoff, M. Skrygan, U. Wieland, N. H. Brockmeyer, M. Stucker, P. Altmeyer, and T. Gambichler High Association of Human Herpesvirus 8 in Large-Plaque Parapsoriasis and Mycosis Fungoides Arch Dermatol, August 1, 2008; 144(8): 1011 - 1016. [Abstract] [Full Text] [PDF]
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 K. Lan, S. C. Verma, M. Murakami, B. Bajaj, R. Kaul, and E. S. Robertson Kaposi's sarcoma herpesvirus-encoded latency-associated nuclear antigen stabilizes intracellular activated Notch by targeting the Sel10 protein PNAS, October 9, 2007; 104(41): 16287 - 16292. [Abstract] [Full Text] [PDF]
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 C. Henke-Gendo, M. Mengel, M. M. Hoeper, K. Alkharsah, and T. F. Schulz Absence of Kaposi's Sarcoma-associated Herpesvirus in Patients with Pulmonary Arterial Hypertension Am. J. Respir. Crit. Care Med., December 15, 2005; 172(12): 1581 - 1585. [Abstract] [Full Text] [PDF]
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 K. Lan, D. A. Kuppers, S. C. Verma, N. Sharma, M. Murakami, and E. S. Robertson Induction of Kaposi's Sarcoma-Associated Herpesvirus Latency-Associated Nuclear Antigen by the Lytic Transactivator RTA: a Novel Mechanism for Establishment of Latency J. Virol., June 15, 2005; 79(12): 7453 - 7465. [Abstract] [Full Text] [PDF]
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K. Lan, D. A. Kuppers, and E. S. Robertson Kaposi's Sarcoma-Associated Herpesvirus Reactivation Is Regulated by Interaction of Latency-Associated Nuclear Antigen with Recombination Signal Sequence-Binding Protein J{kappa}, the Major Downstream Effector of the Notch Signaling Pathway J. Virol., March 15, 2005; 79(6): 3468 - 3478. [Abstract] [Full Text] [PDF]
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 D. SenGupta, P. J. Norris, T. J. Suscovich, M. Hassan-Zahraee, H. F. Moffett, A. Trocha, R. Draenert, P. J. R. Goulder, R. J. Binder, D. L. Levey, et al. Heat Shock Protein-Mediated Cross-Presentation of Exogenous HIV Antigen on HLA Class I and Class II J. Immunol., August 1, 2004; 173(3): 1987 - 1993. [Abstract] [Full Text] [PDF]
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 L. A. Dourmishev, A. L. Dourmishev, D. Palmeri, R. A. Schwartz, and D. M. Lukac Molecular Genetics of Kaposi's Sarcoma-Associated Herpesvirus (Human Herpesvirus 8) Epidemiology and Pathogenesis Microbiol. Mol. Biol. Rev., June 1, 2003; 67(2): 175 - 212. [Abstract] [Full Text] [PDF]
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Top
Abstract
Introduction
-actin served as an internal control to ensure
adequacy of RNA.
