Because human herpesvirus-8 (HHV-8) DNA has been found in multiple myeloma (MM) patients by polymerase chain reaction, it was suggested that HHV-8 may play a role in the transformation of monoclonal gammopathy of undetermined significance (MGUS) to MM. Therefore, 362 MGUS sera with and without progression to MM were tested for IgG antibody to HHV-8. Only 7.8% of the MGUS sera contained HHV-8 antibody to lytic proteins, and IgG antibody to HHV-8 latent antigen was even lower than lytic antibody (2.9%). No differences were observed in the distribution of antibody to HHV-8 in sera from MGUS patients who progressed to MM. The seroprevalences of HHV-8 in MGUS (7.8%), MM (5.4%), and healthy donors (5.9%) were similar, thus arguing for the lack of epidemiologic evidence of HHV-8 participation in the pathogenesis of MM. MGUS patients were immune competent in response to Epstein-Barr virus (EBV) infection because 97% contained antibody to EBV virus capsid antigen.

After Rettig et al1 presented evidence that human herpesvirus (HHV)-8 DNA is present in the bone marrow dendritic cells of patients with multiple myeloma (MM), other reports quickly followed confirming2-10 or refuting the association of HHV-8 with MM, using polymerase chain reaction (PCR) techniques with various HHV-8 primers.11-16 In addition, a few reports also showed that MM patients lack antibody to HHV-8.11-14,16-20 Gao et al,21however, did find HHV-8 IgG antibody in MM patients by latent nuclear antigen (LNA) immunoblot in 81% of the cases. The HHV-8 antibody data in this report were not convincing enough to establish a serologic relation of MM with HHV-8.14 MM patients often have antibodies to either γ-herpesvirus (Epstein-Barr virus [EBV]) or β-herpesviruses (cytomegalovirus, HHV-6, HHV-7), which supports the hypothesis that MM patients have no defect in their immunologic syste ms.11-13,16,17 19 

One fourth of patients with monoclonal gammopathy of undetermined significance (MGUS) develop MM or related serious B-cell disorders. Because Rettig et al1 suggested that HHV-8 (also called KSHV [Kaposi sarcoma–associated herpesvirus]) may be required for the transformation from MGUS to MM and for perpetuation of the growth of malignant plasma cells, we tested sera from 362 MGUS patients and 110 MM patients. To make sure our serologic assays were able to detect accurately IgG antibody to HHV-8, we used a whole-virus enzyme-linked immunosorbent assay (ELISA), latent antinuclear antigen immunofluorescence assay (LANA IFA), and an IFA to lytic antigens. To see whether MGUS patients were immunocompetent, we also tested study sera for the presence of EBV virus capsid antigen (VCA) antibody.

MGUS sera were collected and frozen at −20°C by Drs M. B. Rettig, J. R. Berenson, and R. A. Kyle. Samples of MM, Kaposi sarcoma/human immunodeficiency virus-1 (KS/HIV), and classic KS were obtained frozen from Drs M. Kaplan, A. Friedman-Kien, D. Viza, and P. Gill. Donor sera were from a well-characterized panel used at Advanced Biotechnologies Inc (Columbia, MD). All sera were screened for antibodies to lytic proteins by the whole-virus lysate ELISA kit (Advanced Biotechnologies Inc).22 Positive sera were confirmed by IFA for lytic HHV-8 antigens.22 D. Bourboulia did the testing for IgG antibody to LANA by the IFA method of Simpson et al23 in the laboratory of Dr C. Boshoff in London. The EBV-VCA ELISA was done using native gp125 as a source of antigen.22 All samples were coded before testing.

Table 1 shows the seroprevalence of antibodies to HHV-8 lytic proteins for MGUS, MM, KS, and healthy controls. Twenty-six of 362 MGUS sera (7.1%), 6 of 110 MM sera (5.4%), 20 of 20 KS sera (100%), and 6 of 102 sera of healthy blood donors (5.9%) were positive by ELISA for IgG antibodies to HHV-8 antigen. For confirmation, the positive samples were retested by IFA, and all tested positive except for 2 of the MGUS sera and 2 of the donor sera (Table 2). These results show that the prevalence of antibody to lytic HHV-8 proteins in MGUS and MM patients is similar to that observed in the healthy donor population (Table 1). To ensure that we were not missing patients who had antibody only to latent proteins, we also used the LANA IFA to test randomly picked MGUS sera (95), MM sera (65), KS sera (20), and donor sera (50). For the samples tested, 3 MGUS (3.2%), 3 MM (4.6%), 18 KS (90%), and 2 healthy donors (4.0%) were LANA positive. The prevalence of antibody to the LANA in MGUS and MM is even lower than that of antibody to lytic proteins (Table 1). Analysis of HHV-8 antibody status in MGUS patients with and without progression to MM indicated no change in seroprevalence (Table 3). This argues against any role for HHV-8 in the transformation or pathogenicity of MGUS to MM.

Table 1.

Distribution of HHV-8 (KSHV) IgG antibody in sera from MGUS, MM, KS, and healthy donors detected by whole-virus lysate ELISA and by IFA to latent antigens

Serum IDELISAAntibody to latent antigens
No. positive/no. testedNo. positive/no. tested
MGUS 26/362  (7.1%) 3/95  (3.2%) 
MM 6/110  (5.4%) 3/65  (4.6%)  
Classic KS (positive control) 20/20  (100.0%) 18/20  (90.0%)  
Healthy donors (adult) 6/102  (5.9%) 2/50  (4.0%) 
Serum IDELISAAntibody to latent antigens
No. positive/no. testedNo. positive/no. tested
MGUS 26/362  (7.1%) 3/95  (3.2%) 
MM 6/110  (5.4%) 3/65  (4.6%)  
Classic KS (positive control) 20/20  (100.0%) 18/20  (90.0%)  
Healthy donors (adult) 6/102  (5.9%) 2/50  (4.0%) 

ELISA and IFA to lytic antigens were performed according to the assay of Chatlynne et al,22 using the HHV-8 ELISA and IFA kits from Advanced Biotechnologies Inc. For ELISA, the sera were diluted at 1:100, and for IFA, the sera were diluted at 1:40. IFA to lytic antigens was used to confirm the ELISA-positive sera for antibody to HHV-8. Antibody to latent antigens was tested by IFA using a 1:100 dilution according to the procedure of Simpson et al.23 

Table 2.

MGUS, MM, KS, and healthy donors testing positive by HHV-8 whole-virus lysate ELISA and then tested by IFA to lytic antigens for confirmation

Serum IDELISA positive sera tested by lytic IFA no. positive/no. tested (% correlation between the two tests)
MGUS 24/26 (92.3) 
MM 6/6 (100.0)  
Classic KS (positive control) 20/20 (100.0)  
Healthy donors (adult) 4/6 (67.0) 
Serum IDELISA positive sera tested by lytic IFA no. positive/no. tested (% correlation between the two tests)
MGUS 24/26 (92.3) 
MM 6/6 (100.0)  
Classic KS (positive control) 20/20 (100.0)  
Healthy donors (adult) 4/6 (67.0) 
Table 3.

Analysis of MGUS patients' sera for IgG antibody to HHV-8 lytic antigens by ELISA to whole virus*

MGUS patients' seraNo. testedNo. positive% positive
No progression to serious disease 268 21 7.8  
Progression to serious disease in less than 5 years 60 5.0  
Progression to serious disease in more than 5 years 34 5.9 
MGUS patients' seraNo. testedNo. positive% positive
No progression to serious disease 268 21 7.8  
Progression to serious disease in less than 5 years 60 5.0  
Progression to serious disease in more than 5 years 34 5.9 
*

Sera were tested against the HHV-8 virus by ELISA at Advanced Biotechnologies Inc. This preparation of the ELISA antigen contained 1.8 × 109 viral particles per liter and 1.08 mg/mL of protein.

Antibody-positive samples were confirmed by IFA to HHV-8 lytic antigens, using the procedure of Chatlynne et al.22 

Serious diseases such as MM, amyloidosis, or Waldenström macroglobulinemia.

These data are consistent with other antibody studies done largely on MM populations showing a lack of epidemiologic evidence for HHV-8 involvement in MM.11,12,16,17,19,20 Chauhan et al5 reported the analysis of 53 MM sera and found no antibody to latent or lytic proteins of HHV-8; they did, however, find HHV-8 DNA by PCR in the MM tissues. Whitby et al17 also failed to detect HHV-8 antibody in 4 MGUS patients who subsequently developed overt MM. Two other MGUS sera in their study were antibody positive but the patients had no evidence of MM after 36 and 40 months, respectively. The only study reporting the presence of HHV-8 antibodies in MM patients is by Gao et al.21 Using an immunoblot method instead of IFA,16,19 they reported the detection of antibodies to ORF-64 and LNA antigens.21 With the use of IFA, one can observe the difference in staining patterns between nonspecific and specific reactivity, but with the immunoblot method, it is possible to score only positive and negative results. If any nonspecific reactivity survived the blocking step, it would appear on the immunoblot as a positive result. This difference in technique may account for the discrepancy in results with other researchers. Therefore, on the strength of our data and that of the other researchers mentioned earlier, we conclude that it is extremely doubtful that HHV-8 has a role in the progression to MM.

To establish that MGUS patients are competent to make antibody to herpesviruses, we also tested the same 95 MGUS sera for IgG antibody to EBV-VCA using a native EBV (gp125 protein) ELISA. Ninety-two of 95 MGUS sera tested (96.8%) were positive for EBV-VCA antibody, demonstrating that MGUS patients were immunocompetent and responded to EBV infection and other human herpesviruses, as shown previously in MM patients.12,17 19 Both EBV and HHV-8 are classified as human γ-herpesviruses.

The work done by Rettig et al1 was based largely on PCR HHV-8 DNA data, as opposed to the present report, which is a study of serologic antibodies. It is interesting to note that in studies done to compare the frequency of PCR data with that of serology,24,25 the percentage of HIV-1+/KS+ patients positive for HHV-8 DNA in peripheral blood mononuclear cells by PCR is much lower than the percentage found positive for HHV-8 IgG antibodies by IFA for lytic proteins. It is therefore curious that Rettig et al1 could find cells positive for HHV-8 DNA by PCR, but could not detect HHV-8 antibodies in these patients. Berenson and Vescio2attributed the lack of serologic responses to HHV-8 in MM to interpatient differences as well as to consistent changes in ORF-65 sequencing derived from MM as compared to primary effusion B-cell lymphoma and KS patients. They argued that because ORF-65 is responsible for a major part of the serologic response to HHV-8, deletion of a base pair likely results in a change in the protein product, and this may explain the lack of or low level of serologic response to HHV-8 in MM patients.2 Although such deletions may cause a change in the function of the protein, it is unlikely that they would cause much change in antigenic response.

In light of this mounting molecular evidence based on HHV-8 data and the fact that these same patients lack HHV-8 antibody, MM patients may carry another herpesvirus yet to be identified. This theoretical herpesvirus could share common sequences with HHV-8 but be immunologically distinct from HHV-8.22,26 In much the same way, HHV-8 and EBV share homologous DNA sequences,26 but lack serologic cross reactivity.22 

We thank Ms Ruth Weinroth, Ms Alice Long, and Ms Kelly Lehr for their assistance in the preparation of this report.

Supported in part by grant CA62242 from the National Institutes of Health.

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.

1
Rettig
 
M
Ma
 
H
Vescio
 
R
et al
Kaposi's sarcoma-associated herpesvirus infection of bone marrow dendritic cells from multiple myeloma patients.
Science.
276
1997
1851
1854
2
Berenson
 
JR
Vescio
 
RA
Herpesvirus and multiple myeloma.
Blood.
93
1999
3157
3159
3
Said
 
J
Rettig
 
M
Heppner
 
K
et al
Localization of Kaposi's sarcoma-associated herpesvirus in bone marrow biopsy samples from patients with multiple myeloma.
Blood.
90
1997
4278
4282
4
Beksac
 
M
Ma
 
M
DerDanielian
 
M
et al
Frequent demonstration of human herpesvirus 8 (HHV-8) in bone marrow samples from Turkish patients with multiple myeloma [abstract].
Blood.
92(suppl 1)
1992
96a
5
Chauhan
 
D
Bharti
 
A
Raje
 
K
et al
Detection of Kaposi's sarcoma herpesvirus sequences in multiple myeloma bone marrow stromal cells.
Blood.
93
1999
1482
1486
6
Raje
 
N
Gong
 
J
Chauhan
 
D
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.
93
1999
1487
1495
7
Ma
 
H
Vescio
 
R
DerDanielian
 
M
Schiller
 
G
Berenson
 
J
The HHV-8 IL-8R homologue and interferon regulatory factor are frequently expressed in myeloma bone marrow biopsies whereas vIL-6 is rarely found [abstract].
Blood.
92(suppl 1)
1998
515a
8
Rettig
 
M
Vescio
 
R
Moss
 
T
Ma
 
H
Schiller
 
G
Berenson
 
J
Detection of Kaposi's sarcoma-associated herpesvirus in the peripheral blood of multiple myeloma patients [abstract].
Blood.
90(suppl 1)
1997
587a
9
Brousset
 
P
Meggetto
 
F
Attal
 
M
Delsol
 
G
Kaposi's sarcoma-associated herpesvirus infection and multiple myeloma.
Science.
278
1997
1972
10
Tisdale
 
JF
Stewart
 
K
Dickstein
 
B
et al
Molecular and serological examination of the relationship of human herpesvirus to multiple myeloma: ORF 26 sequences in bone marrow stroma are not restricted to myeloma patients and other regions of the genome are detected.
Blood.
92
1998
2681
2687
11
Marcellin
 
AG
Dupin
 
N
Buscary
 
D
et al
HHV-8 and multiple myeloma in France.
Lancet.
350
1997
1144
12
Masood
 
R
Zheng
 
T
Turpule
 
A
et al
Kaposi's sarcoma-associated herpesvirus infection and multiple myeloma.
Science.
278
1997
1970
1971
13
Yi
 
Q
Ekman
 
M
Anton
 
D
et al
Blood dendritic cells from myeloma patients are not sarcoma-associated herpesvirus (KSHV/HHV-8).
Blood.
82
1998
402
404
14
Tarte
 
K
Chang
 
Y
Klein
 
B
Kaposi's sarcoma-associated herpesvirus and multiple myeloma: lack of criteria for causality.
Blood.
151
1999
3159
3163
15
Cull
 
GM
Timms
 
JM
Haynes
 
A
et al
Dendritic cells cultured from mononuclear cells and CD34 cells in myeloma do not harbour human herpesvirus 8.
Br J Haematol.
100
1998
793
796
16
Olsen
 
SJ
Tarte
 
K
Sherman
 
W
et al
Evidence against KSHV infection in the pathogenesis of multiple myeloma.
Virus Res.
57
1998
197
202
17
Whitby
 
D
Boshoff
 
C
Luppi
 
M
Torelli
 
G
Kaposi's sarcoma-associated herpesvirus infection and multiple myeloma.
Science.
278
1997
1971
1972
18
Parravicini
 
C
Lauri
 
E
Baldini
 
L
et al
Kaposi's sarcoma-associated herpesvirus infection and multiple myeloma.
Science.
278
1997
1969
1970
19
Cottoni
 
F
Uccini
 
S
Kaposi's sarcoma-associated herpesvirus infection in multiple myeloma.
Science.
278
1997
1972
20
Mackenzie
 
J
Sheldon
 
J
Morgan
 
G
Cook
 
G
Schulz
 
F
Jarrett
 
R
HHV-8 and multiple myeloma in the UK.
Lancet.
350
1997
1144
1145
21
Gao
 
SJ
Alsina
 
M
Deng
 
JH
et al
Antibodies to Kaposi's sarcoma-associated herpesvirus (human herpesvirus 8) in patients with multiple myeloma.
J Infect Dis.
178
1998
846
849
22
Chatlynne
 
LG
Lapps
 
W
Handy
 
M
et al
Detection and titration of HHV-8 specific antibodies in sera from blood donors, AIDS patients, and Kaposi's sarcoma patients using whole virus ELISA.
Blood.
92
1998
53
58
23
Simpson
 
GR
Schulz
 
TF
Whitby
 
D
et al
Prevalence of Kaposi's sarcoma-associated herpesvirus infection measured by antibodies to recombinant capsid protein and latent immunofluorescence antigen.
Lancet.
48
1996
1133
1138
24
Smith
 
MS
Bloomer
 
C
Horvat
 
R
Goldstein
 
E
Casparian
 
M
Chandran
 
B
Detection of human herpesvirus 8 DNA in Kaposi's sarcoma lesions and peripheral blood of HIV+ patients and correlation with serological measurements.
J Infect Dis.
176
1997
84
93
25
Chandran
 
B
Smith
 
MS
Koelle
 
DM
Corey
 
L
Horvat
 
R
Goldstein
 
E
Reactivities of human sera with human herpesvirus 8 infected BCBL-1 cells and identification of HHV-8 specific proteins and glycoproteins and the encoding of cDNAs.
Virology.
243
1998
208
217
26
Chang
 
Y
Cesarman
 
E
Pessin
 
MS
et al
Identification of herpesvirus-like DNA sequences in AIDS-associated Kaposi's sarcoma.
Science.
266
1994
1865
1869

Author notes

Dharam V. Ablashi, Advanced Biotechnologies Inc, 9108 Guilford Road, Columbia, MD 21046-2701; e-mail:dablashi@abionline.com.

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