Syngeneic graft-versus-host disease (sGVHD) has been described after hematopoietic cell transplantation (HCT) but remains poorly defined. We retrospectively reviewed adult syngeneic HCTs at our center (1980-2002) for sGVHD to investigate incidence, morbidity, and risk factors with a primary focus on parity. Among 119 transplantations, there were 21 cases of biopsy-proven sGVHD. The cumulative incidence was 18%, with multiorgan involvement in 6 cases and 1 death. sGVHD was more frequent when the donor was parous (32%) than nulliparous (9%) or male (13%; P = .03) and when the recipient was parous (31%) than nulliparous (7%) or male (13%; P = .02). Other univariable risk factors included older age (P < .01), busulfan/melphalan/thiotepa conditioning (P < .01), interleukin-2 (P = .02), HLA-A26 (P = .03), and more recent transplantation year (P < .01). Overall, risk factors were similar to those described in GVHD. Although an independent effect of parity could not be completely separated from other factors, donor and recipient pregnancy history merits further investigation.

Cutaneous and gastrointestinal graft-versus-host disease (GVHD) are described after syngeneic hematopoietic cell transplantation (HCT), but the occurrence of syngeneic GVHD (sGVHD) remains controversial and seems to defy the concept that the host must appear “foreign” to the graft.1-8  Although a number of mechanisms could potentially explain this observation, recent studies reveal that women harbor fetal cells decades after pregnancy, suggesting that HLA-incompatible fetal cells could be infused from parous donors.9  We hypothesized that donor or recipient parity was a risk factor for sGVHD, and as an initial study retrospectively reviewed adult syngeneic HCTs over 22 years at our center for biopsy-proven sGVHD. In addition to a focused analysis on donor and recipient parity as potential risk factors, we also describe the incidence, morbidity, and other risk factors of this poorly defined syndrome.

Study design and subjects

We retrospectively reviewed 126 consecutive first adult syngeneic bone marrow or peripheral blood HCTs at Fred Hutchinson Cancer Research Center (FHCRC) between January 1, 1980, and April 1, 2002. As sGVHD diagnosis required physician suspicion and biopsy, transplantations prior to the first sGVHD report (October 1979) were not considered.1  There were 7 patients excluded (death before day 14 after transplantation, n = 5; insufficient data, n = 2), leaving 119 subjects. The FHCRC institutional review board approved the study.

Monozygosity testing

Siblings sharing birth date and sex underwent testing to determine whether they could be monozygotic (identical). Testing in earlier years involved matching human leukocyte antigens (HLAs), blood group, and red blood cell (RBC) antigens/isoenzymes. Although informative markers are identified in at least 80% of sibling pairs with this method, blood transfusion may lead to RBC antigen detection in a patient genetically negative for the antigen.10  In 9 twin pairs (one with sGVHD), 1 to 3 RBC antigens in recipients were not present in their donors. Mismatches were attributed to blood transfusions. In 1991, DNA amplification of variable nucleotide tandem repeats (VNTRs) to confirm monozygosity became common. Informative polymorphisms can be identified in virtually all sibling pairs by testing 6 VNTR sequences.10 

sGVHD definition

sGVHD was defined by characteristic histologic changes on a skin, intestinal, or liver biopsy with no evidence of infection. Skin biopsies earlier than day 20 were excluded. GVHD histologic findings included lymphocytic infiltration of the cutis/epidermis, apoptotic changes, vacuolar degeneration of epithelial basal cell layers, and eosinophilic coagulation necrosis (skin); apoptotic crypt endothelial cells and crypt cell dropout with/without lymphocytic aggregates (intestine); and apoptosis, dysmorphic small bile duct changes, ductopenia, and lobular acidophilic bodies (liver).

Candidate predictors

Potential risk factors included age, sex, cytomegalovirus (CMV) serostatus, pregnancy history, disease type, HLA (A26, DR2, DR3, DR4, DR7), cell source, cell dose infused, immunosuppression/graft manipulation, immunotherapy, conditioning regimen, donor buffy coat infusion, and transplantation year. Risk factors were abstracted from medical records and the FHCRC Transplant Database. Transfusion history outside our center could not be accurately determined. Some patients received methotrexate (n = 16) in an attempt to standardize syngeneic and allogeneic transplantations for future comparison studies. A stem cell infusion without conditioning was administered for aplastic anemia (n = 3) and paroxysmal nocturnal hemoglobinuria (n = 1). Inference of HLA-A26 from HLA-A10 (n = 2) was based on ethnicity.

Statistical analysis

Time to event analyses were performed to determine sGVHD incidence and risk factors. Cumulative incidence estimates treated death, relapse, or second transplantation before day 100 as competing events for sGVHD.11  All survivors were censored 100 days after transplantation. Univariable comparisons used log-rank tests. Overall P values compared parous women with nulliparous women and men in univariable analysis. Analyses comparing parous with nulliparous women were performed in multivariable analyses. Hazard ratios (HRs) and associated 95% confidence intervals (CIs) were obtained using Cox proportional hazard regression models limited to 2 factors.

Donor, recipient, and transplant characteristics are summarized in Table 1. Among 119 syngeneic hematopoietic cell transplant recipients, 21 developed biopsy-proven sGVHD, for a cumulative incidence of 18%. Median time to diagnosis was 35 days (range, 20-79 days). Disease course was often self-limited. Single organs (skin, n = 10; intestine, n = 5) were affected more frequently than multiple organs (n = 6). Treatment included no therapy (n = 8), supportive therapy (n = 2), corticosteroids (n = 10), and cyclosporine (CSP) and anti–thymocyte globulin (ATG; n = 1). Untreated cases were self-limited or diagnosed by autopsy or skin biopsy at discharge.

Table 1.

Donor, recipient, and transplant characteristics of 119 syngeneic HCTs


Factor

No. (%) or mean (range)
Age   42 (17-68)  
Sex  
    Female   49 (41)  
    Male   70 (59)  
Parity in female donors, N = 45  
    Nulliparous   11 (22)  
    Parous   34 (69)  
Parity in female recipients, N = 49  
    Nulliparous   14 (29)  
    Parous   35 (71)  
Donor/recipient parity, N = 45  
    Nulliparous/nulliparous   5 (11)  
    Nulliparous/parous   6 (13)  
    Parous/nulliparous   8 (18)  
    Parous/parous   26 (58)  
CMV serostatus, donor/recipient, N = 76  
    Negative/negative   28 (37)  
    Positive/negative   6 (8)  
    Negative/positive   8 (11)  
    Positive/positive   34 (45)  
Disease type  
    Hematologic malignancy   104 (87)  
    Other malignancy   10 (8)  
    Nonmalignant condition   5 (4)  
HLA antigens  
    A26, N = 117   6 (5)  
    DR2, N = 90   30 (33)  
    DR3, N = 90   23 (26)  
    DR4, N = 90   30 (33)  
    DR7, N = 90   15 (17)  
Immunosuppression/graft manipulation, N = 118  
    Methotrexate   16 (14)  
    CD34 selection   1 (1)  
    CD4 depletion, HIV infection   1 (1)  
Conditioning regimen, N = 118  
    TBI-containing   86 (73)  
    BUMELT   12 (10)  
    Other chemotherapy   16 (14)  
    None—simple infusion   4 (3)  
Cell source  
    Bone marrow   88 (74)  
    PBSC   31 (26)  
Cell counts  
    TNC/kg × 108 in BM, N = 80   2.1 (0.0-4.8)  
    TMNC/kg × 108 in PBSC, N = 21   7.6 (4.7-17.2)  
    CD34/kg × 106 in PBSC, N = 28   8.1 (1.5-14.0)  
Donor buffy coat infusion   32 (27)  
Immunotherapy  
    IL-2   9 (8)  
    Anti-idiotype myeloma vaccine   1 (1)  
    Alpha-interferon   1 (1)  
Transplantation year  
    1980 to 1987   58 (49)  
    1988 to 1995   43 (36)  
    1996 to 2002
 
18 (15)
 

Factor

No. (%) or mean (range)
Age   42 (17-68)  
Sex  
    Female   49 (41)  
    Male   70 (59)  
Parity in female donors, N = 45  
    Nulliparous   11 (22)  
    Parous   34 (69)  
Parity in female recipients, N = 49  
    Nulliparous   14 (29)  
    Parous   35 (71)  
Donor/recipient parity, N = 45  
    Nulliparous/nulliparous   5 (11)  
    Nulliparous/parous   6 (13)  
    Parous/nulliparous   8 (18)  
    Parous/parous   26 (58)  
CMV serostatus, donor/recipient, N = 76  
    Negative/negative   28 (37)  
    Positive/negative   6 (8)  
    Negative/positive   8 (11)  
    Positive/positive   34 (45)  
Disease type  
    Hematologic malignancy   104 (87)  
    Other malignancy   10 (8)  
    Nonmalignant condition   5 (4)  
HLA antigens  
    A26, N = 117   6 (5)  
    DR2, N = 90   30 (33)  
    DR3, N = 90   23 (26)  
    DR4, N = 90   30 (33)  
    DR7, N = 90   15 (17)  
Immunosuppression/graft manipulation, N = 118  
    Methotrexate   16 (14)  
    CD34 selection   1 (1)  
    CD4 depletion, HIV infection   1 (1)  
Conditioning regimen, N = 118  
    TBI-containing   86 (73)  
    BUMELT   12 (10)  
    Other chemotherapy   16 (14)  
    None—simple infusion   4 (3)  
Cell source  
    Bone marrow   88 (74)  
    PBSC   31 (26)  
Cell counts  
    TNC/kg × 108 in BM, N = 80   2.1 (0.0-4.8)  
    TMNC/kg × 108 in PBSC, N = 21   7.6 (4.7-17.2)  
    CD34/kg × 106 in PBSC, N = 28   8.1 (1.5-14.0)  
Donor buffy coat infusion   32 (27)  
Immunotherapy  
    IL-2   9 (8)  
    Anti-idiotype myeloma vaccine   1 (1)  
    Alpha-interferon   1 (1)  
Transplantation year  
    1980 to 1987   58 (49)  
    1988 to 1995   43 (36)  
    1996 to 2002
 
18 (15)
 

Unless otherwise stated, percentages within a group were calculated using a denominator of 119 patients. TBI indicates total body irradiation; BUMELT, busulfan/melphalan/thiotepa; PBSC, peripheral blood stem cell; TNC, total nuclear cell count; TMNC, total mononuclear cell count, and IL-2, interleukin-2.

One death attributed to sGVHD occurred in a parous 47-year-old woman with acute myelogenous leukemia. Both twins were CMV seronegative and the donor was nulliparous. The patient underwent bone marrow transplantation with busulfan, cytoxan, and fractionated total body irradiation conditioning and did not receive methotrexate or immunotherapy. Severe rash, diarrhea, and hyperbilirubinemia developed. A skin biopsy was consistent with GVHD (day 23). Despite corticosteroids, CSP, and ATG, she died, with extensive GVHD findings on autopsy (day 63). Monozygosity testing of this twin pair involved HLA and blood group match. The twins may have been dizygotic (fraternal), as VNTR analysis was not performed. Genetic testing in other sGVHD cases was more extensive: HLA/VNTR (n = 15), HLA/VNTR/RBC antigen/isoenzyme panel (n = 3), HLA/RBC antigen/isoenzyme panel (n = 1), and HLA only (n = 1).

In univariable analysis, factors significantly associated with sGVHD included older age, parous donors, parous recipients, parous donor/recipient combinations, HLA-A26, IL-2, busulfan/melphalan/thiotepa (BUMELT), and more recent transplantation year (Table 2). Recipient parity remained a significant independent risk factor in multivariable analysis after adjusting individually for acute lymphocytic leukemia (P = .03), BUMELT (P = .01), IL-2 (P = .02), any immunotherapy (P = .02), donor buffy coat infusion (P = .03), HLA-A26 (P = .03), DR2 (P = .02), and year of transplantation (P = .02). Adjusting for age (P = .14) or recipient CMV status (P = .07) diminished the effect of recipient parity.

Table 2.

Univariable analysis of factors associated with syngeneic GVHD


Factor

No.

GVHD incidence, No. (%)

HR

95% Cl

Level-specific P value, > 2 levels

Overall P value, log-rank test
Age, y       
    16 to 39   50   3 (6)   1.0   Reference   NA   
    40 to 68   69   18 (26)   5.0   1.5-16.8   NA   < .01  
Sex       
    Male   70   9 (13)   1.0   Reference   NA   
    Female   49   12 (24)   2.0   0.8-4.8   NA   .11  
Donor parity, N = 115       
    Nulliparous   11   1 (9)   1.0   Reference   Reference   
    Parous   34   11 (32)   4.6   0.6-35.9   .07   
    Male   70   9 (13)   1.7   0.2-13.1   .61   .03  
Recipient parity       
    Nulliparous   14   1 (7)   1.0   Reference   Reference   
    Parous   35   11 (31)   6.0   0.8-46.2   .03   
    Male   70   9 (13)   2.1   0.3-16.5   .44   .02  
CMV serostatus       
    Donor serostatus, N = 76        
        Negative   37   8 (22)   1.0   Reference   NA   
        Positive   41   11 (27)   1.4   0.5-3.4   NA   .51  
    Recipient serostatus, N = 105        
        Negative   46   6 (13)   1.0   Reference   NA   
        Positive   57   15 (26)   2.3   0.9-6.1   NA   .07  
Acute lymphocytic leukemia       
    No   112   18 (16)   1.0   Reference   NA   
    Yes   7   3 (43)   2.7   0.8-9.2   NA   .10  
HLA-A26, N = 117       
    No   111   18 (16)   1.0   Reference   NA   
    Yes   6   3 (50)   3.6   1.0-12.2   NA   .03  
HLA-DR2, N = 90       
    No   60   10 (17)   1.0   Reference   NA   
    Yes   30   9 (30)   1.8   0.7-4.4   NA   .19  
Cell source       
    PBSC   31   8 (26)   1.0   Reference   NA   
    Bone marrow   88   13 (15)   0.5   0.2-1.3   NA   .15  
Donor buffy coat infusion       
    No   87   18 (21)   1.0   Reference   NA   
    Yes   32   3 (9)   0.5   0.1-1.5   NA   .19  
Immunotherapy       
    No   108   17 (16)   1.0   Reference   NA   
    Yes   11   4 (36)   2.5   0.9-7.6   NA   .08  
IL-2 therapy       
    No   112   18 (16)   1.0   Reference   NA   
    Yes   9   4 (44)   3.5   1.2-10.3   NA   .02  
Conditioning regimen       
    Non-BUMELT   107   16 (15)   1.0   Reference   NA   
    BUMELT   12   5 (42)   3.6   1.3-9.8   NA   < .01  
Transplantation year       
    1980 to 1987   58   3 (5)   1.0   Reference   Reference   
    1988 to 1995   43   12 (28)   5.2   1.5-18.6   < .01   
    1996 to 2002
 
18
 
6 (33)
 
7.5
 
1.9-30.1
 
< .01
 
< .01
 

Factor

No.

GVHD incidence, No. (%)

HR

95% Cl

Level-specific P value, > 2 levels

Overall P value, log-rank test
Age, y       
    16 to 39   50   3 (6)   1.0   Reference   NA   
    40 to 68   69   18 (26)   5.0   1.5-16.8   NA   < .01  
Sex       
    Male   70   9 (13)   1.0   Reference   NA   
    Female   49   12 (24)   2.0   0.8-4.8   NA   .11  
Donor parity, N = 115       
    Nulliparous   11   1 (9)   1.0   Reference   Reference   
    Parous   34   11 (32)   4.6   0.6-35.9   .07   
    Male   70   9 (13)   1.7   0.2-13.1   .61   .03  
Recipient parity       
    Nulliparous   14   1 (7)   1.0   Reference   Reference   
    Parous   35   11 (31)   6.0   0.8-46.2   .03   
    Male   70   9 (13)   2.1   0.3-16.5   .44   .02  
CMV serostatus       
    Donor serostatus, N = 76        
        Negative   37   8 (22)   1.0   Reference   NA   
        Positive   41   11 (27)   1.4   0.5-3.4   NA   .51  
    Recipient serostatus, N = 105        
        Negative   46   6 (13)   1.0   Reference   NA   
        Positive   57   15 (26)   2.3   0.9-6.1   NA   .07  
Acute lymphocytic leukemia       
    No   112   18 (16)   1.0   Reference   NA   
    Yes   7   3 (43)   2.7   0.8-9.2   NA   .10  
HLA-A26, N = 117       
    No   111   18 (16)   1.0   Reference   NA   
    Yes   6   3 (50)   3.6   1.0-12.2   NA   .03  
HLA-DR2, N = 90       
    No   60   10 (17)   1.0   Reference   NA   
    Yes   30   9 (30)   1.8   0.7-4.4   NA   .19  
Cell source       
    PBSC   31   8 (26)   1.0   Reference   NA   
    Bone marrow   88   13 (15)   0.5   0.2-1.3   NA   .15  
Donor buffy coat infusion       
    No   87   18 (21)   1.0   Reference   NA   
    Yes   32   3 (9)   0.5   0.1-1.5   NA   .19  
Immunotherapy       
    No   108   17 (16)   1.0   Reference   NA   
    Yes   11   4 (36)   2.5   0.9-7.6   NA   .08  
IL-2 therapy       
    No   112   18 (16)   1.0   Reference   NA   
    Yes   9   4 (44)   3.5   1.2-10.3   NA   .02  
Conditioning regimen       
    Non-BUMELT   107   16 (15)   1.0   Reference   NA   
    BUMELT   12   5 (42)   3.6   1.3-9.8   NA   < .01  
Transplantation year       
    1980 to 1987   58   3 (5)   1.0   Reference   Reference   
    1988 to 1995   43   12 (28)   5.2   1.5-18.6   < .01   
    1996 to 2002
 
18
 
6 (33)
 
7.5
 
1.9-30.1
 
< .01
 
< .01
 

All P values are 2-sided. Variables listed include those with a P value ≤ .2 on univariable log-rank test. Level-specific P values were based on likelihood ratio tests from regression models. PBSC indicates peripheral blood stem cell; IL-2, interleukin-2; BUMELT, busulfan/melphalan/thiotepa; and NA, not applicable.

sGVHD appears to share many risk factors with autologous and allogeneic GVHD. Prior reports associated donor parity and GVHD, hypothesizing that allosensitization of maternal T cells to fetal antigens during pregnancy could prime cells to similar antigens in a transplant recipient.12-14  Another intriguing hypothesis originates in the finding that fetal cells persist in parous women decades after childbirth. The recent finding that male DNA is frequently present in apheresis products from female donors suggests that donor fetal cells may be transferred during HCT.9,15  In addition, host (recipient) tolerance to fetal cells from prior pregnancies may be altered with myeloablative therapy, potentially explaining an association between sGVHD and recipient parity. Other sGVHD risk factors are consistent with those identified in autologous or allogeneic GVHD. Thymic aging may lead to increased autoreactivity in older adults. IL-2 and BUMELT are associated with autologous GVHD.16-18  Finally, the association with more recent transplantation likely reflects increased physician awareness and lower threshold to biopsy tissue.

Limitations of our study include small numbers of nulliparous women and sGVHD cases, which made it difficult to separate a parity effect from all other factors. Another limitation is the need to analyze a variety of risk factors within a relatively small cohort. Finally, it is also possible that a dizygotic twin pair may have been misclassified as monozygotic. However, in 48% of sGVHD cases, identity of HLA, blood group, and 4 unlinked genetic loci (VNTR) would theoretically result in a less than 1 in 500 chance of misclassification.10 

Despite prior reports of GVHD-like syndromes, sGVHD remains controversial.7,19  Our report of 21 sGVHD cases with associated morbidity and mortality suggests that the diagnosis be considered and treatment initiated. sGVHD is most likely multifactorial and shares many risk factors with autologous and allogeneic GVHD. Parity as a GVHD risk factor is essentially unexamined and merits further investigation.

Prepublished online as Blood First Edition Paper, April 29, 2004; DOI 10.1182/blood-2004-02-0508.

Supported by grants HD01264, AI41721, and AI45659 from the National Institutes of Health and the Jose Carreras Foundation Against Leukemia.

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.

We would like to acknowledge Dr Paul Martin for his expert advice and Kara Kendall, Chris Davis, Dimitri Oparin, and Mary Kay Carrithers for their assistance with data collection, abstraction, and obtaining medical records.

1
Rappeport J, Mihm M, Reinherz E, Lopansri S, Parkman R. Acute graft-versus-host disease in recipients of bone-marrow transplants from identical twin donors.
Lancet
.
1979
;
2
:
717
-720.
2
Hood AF, Vogelsang GB, Black LP, Farmer ER, Santos GW. Acute graft-vs-host disease: development following autologous and syngeneic bone marrow transplantation.
Arch Dermatol
.
1987
;
123
:
745
-750.
3
Billingham R. The biology of graft-versus-host reactions.
The Harvey Lecture Series, 1966-1967
. Vol
62
. Orlando, FL: Academic Press;
1968
:
21
-78.
4
Hinterberger W, Rowlings PA, Hinterberger-Fischer M, et al. Results of transplanting bone marrow from genetically identical twins into patients with aplastic anemia.
Ann Intern Med
.
1997
;
126
:
116
-122.
5
Spaner D, Lowsky R, Fyles G, et al. Acute intestinal graft-versus-host disease in a syngeneic bone marrow transplant recipient.
Transplantation
.
1998
;
66
:
1251
-1253.
6
Einsele H, Ehninger G, Schneider EM, et al. High frequency of graft-versus-host-like syndromes following syngeneic bone marrow transplantation.
Transplantation
.
1988
;
45
:
579
-585.
7
Glazier A, Tutschka PJ, Farmer ER, Santos GW. Graft-versus-host disease in cyclosporin A-treated rats after syngeneic and autologous bone marrow reconstitution.
J Exp Med
.
1983
;
158
:
1
-8.
8
Hwang WY, Goh YT, Tan CH, How GF, Tan HC. Severe acute graft-versus-host disease occurring after syngeneic BMT for AML in a patient not given prior cyclosporin a therapy.
Bone Marrow Transplant
.
2000
;
25
:
205
-207.
9
Adams KM, Nelson JL. Microchimerism: an investigative frontier in autoimmunity and transplantation.
JAMA
.
2004
;
291
:
1127
-1131.
10
Bryant E, Martin P. Documentation of engraftment and characterization of chimerism following hematopoietic cell transplantation. In: Thomas E, Blume K, Forman S, eds.
Hematopoietic Cell Transplantation
. 2nd ed. Boston, MA: Blackwell Science;
1999
:
197
-206.
11
Kalbfleisch J, Prentice R.
The Statistical Analysis of Failure Time Data
. New York, NY: John Wiley and Sons;
1980
:
168
-169.
12
Flowers ME, Pepe MS, Longton G, et al. Previous donor pregnancy as a risk factor for acute graft-versus-host disease in patients with aplastic anaemia treated by allogeneic marrow transplantation.
Br J Haematol
.
1990
;
74
:
492
-496.
13
Kollman C, Howe CW, Anasetti C, et al. Donor characteristics as risk factors in recipients after transplantation of bone marrow from unrelated donors: the effect of donor age.
Blood
.
2001
;
98
:
2043
-2051.
14
Verdijk RM, Kloosterman A, Pool J, et al. Pregnancy induces minor histocompatibility antigen-specific cytotoxic T cells: implications for stem cell transplantation and immunotherapy.
Blood
.
2004
;
103
:
1961
-1964.
15
Adams KM, Lambert NC, Heimfeld S, et al. Male DNA in female donor apheresis and CD34-enriched products.
Blood
.
2003
;
102
:
3845
-3847.
16
Tzung SP, Hackman RC, Hockenbery DM, Bensinger W, Schiffman K, McDonald GB. Lymphocytic gastritis resembling graft-vs.-host disease following autologous hematopoietic cell transplantation.
Biol Blood Marrow Transplant
.
1998
;
4
:
43
-48.
17
Massumoto C, Benyunes MC, Sale G, et al. Close simulation of acute graft-versus-host disease by interleukin-2 administered after autologous bone marrow transplantation for hematologic malignancy.
Bone Marrow Transplant
.
1996
;
17
:
351
-356.
18
Holmberg L, Gooley T, Kikuchi K, et al. Gastrointestinal graft-versus-host disease after autologous stem cell transplant: incidence, outcome, and risk factors [abstract].
Biol Blood Marrow Transplant
.
2004
;
10
(supp 1):
15
.
19
Thein SL, Goldman JM, Galton DA. Acute “graft-versus-host disease” after autografting for chronic granulocytic leukemia in transformation.
Ann Intern Med
.
1981
;
94
:
210
-211.
Sign in via your Institution