Graft-versus-host disease after liver transplantation.

INTRODUCTION

Graft-versus-host disease (GVHD) following liver transplantation (LT) is an uncommon complication but has high mortality and represents a major diagnostic challenge. GVHD occurs when immunocompetent donor lymphocytes originating from the transplanted liver undergo activation and clonal expansion, allowing them to mount a destructive cellular immune response against recipient tissues. Humoral GVHD is usually seen after an ABO-mismatched liver transplant, but cellular GVHD is directed against the major histocompatibility complex and often results in severe multisystem disease with high mortality.1

In 1988, Burdick et al.2 first described acute GVHD after orthopic liver transplantation (OLT). The incidence was reported to be 0.1% by United Networks of Organ Sharing, however some clinical trials reported an incidence of up to 1%.1,3 Skin rash and fever are the most frequent early signs, followed by leukopenia. The mortality rate of acute GVHD following OLT exceeds 75%.4 In most cases, death results from overwhelming sepsis or gastrointestinal bleeding as a consequence of bone-marrow involvement.4

It appears worthwhile to analyze our case against the background of a broad literature review, because of the low incidence of GVHD after LT.

CASE REPORT

A 64-year-old male with hepatitis C virus infection, alcohol-related cirrhosis and hepatocellular carcinoma in segments V, VI and VIII received a liver transplant from an ABO-identical (blood group A) 53-year-old male cadaveric donor. The donor was cytomegalovirus-seronegative and toxoplasma-seropositive. The recipient was cytomegalovirus-seropositive and toxoplasma-seropositive and had a body mass index of 24.5 kg/m2. The Child–Pugh score was A6 and the model end-stage liver disease score was 10. During transplantation, 2 units of concentrated red cells and 4 units of fresh frozen plasma were transfused. Initial immunosuppressants comprised tacrolimus (through levels 8–10 ng/ml) and Corticosteroid (500 mg methylprednisolone intraoperatively, 250 mg postoperatively, 1 mg/kg body weight on days 1 to 4, 0.5 mg/kg body weight on day 5, 0.4 mg/kg body weight on days 6 to 10, then tapering).

On day 9, an increase in hepatic enzymes aspartate aminotransferase and alanine aminotransferase was identified from a hepatic biopsy, where acute cellular rejection was diagnosed. The postoperative laboratory examinations are shown in detail in Tables 1 and 2.

The treatment was steroid pulse therapy using 500 mg methylprednisolone on five consecutive days. Sixteen days later, a new hepatic biopsy showed regression of the rejection. After recovery in timely fashion the patient was discharged home on day 25. The patient was readmitted on day 31 and presumptive diagnosis of GVHD was made on clinical grounds, which was supported by the presence of a skin rash and generalized maculopapular eruption (most accentuated on the abdomen, trunk and face) in conjunction with erythema and palm rash, fever, severe leukopenia (0.45 mil/mm3), anemia, low hemoglobin and low blood pressure levels and watery diarrhea. Skin biopsies were consistent with GVHD, showing vacuolar degeneration of the basal layer of the epithelium, epidermal infiltration by lymphocytes and necrotic eosinophilic keratinocytes. Other findings were as follows: spongiosis, basal cell hydropic changes, many apoptotic keratinocytes, and lymphocytic exocytosis (including satellite-cell necrosis) in the epidermis. Furthermore, there was subepidermal cleft formation (grade III of acute GVHD) (Figures 1 and 2). A myelogram performed a few days later revealed a hypoplastic bone marrow resulting in aplasia. The main microscopic features were single-cell necrosis (apoptosis) in the mucosa of all three organs. No specific infectious agents could be identified in those samples. The gastric mucosa had some gland abscesses and partial mucosal denudation. Genomic DNA from recipient peripheral blood showed the presence of both donor and recipient antigens on day 32 (chimerism). Flow cytometry indicated the level of donor T-lymphocyte macrochimerism to be between 3 and 4%. The patient received 1 g intravenous methylprednisolone for 3 days, starting on day 31, and antithymocyte globulin (500 mg i.v. on five consecutive days): there was no improvement in the skin rash.

Figure 1

Skin biopsy stained with hematoxylin–eosin at ×20 magnification, showing many apoptotic keratinocytes, lymphocytic exocytosis and spongiosis in addition to the subepidermal cleft.

Figure 2

Skin biopsy stained with hematoxylin–eosin at ×20 magnification, showing the epidermis with basal cell hydropic changes, satellite-cell necrosis (near the dermis) and multiple apoptotic keratinocytes.

On day 36, there was a progressive worsening of the patient's clinical condition, with pulmonary and renal insufficiency, agranulocytosis, and, subsequently, multi-organ failure resulting in death.

DISCUSSION

In 1966, Billigham5 described the essential requirements for the development of GVHD: first, the graft must contain immunologically competent cells; second, the recipient must be recognized as foreign by the graft; and, third, the recipient must be unable to reject the graft before it mounts an effective immune response.

The pathogenesis of acute GVHD involved clearly proinflammatory cytokine release caused by leukocyte destruction. Interleukin-2 was demonstrated to be a key mediator for the development of GVHD. Hence, its membrane-bound ligand, CD25, appears to be an attractive target for drug intervention in GVHD. There are three reported cases of patients in whom anti-CD25 monoclonal antibodies have been administered. All three patients were cured of GVHD.6,7

Tumor necrosis factor-alpha also plays an important role in the pathogenesis of GVHD and may therefore be an interesting therapeutic target. There are some single reports of the use of infliximab, a chimeric anti-tumor necrosis factor-alpha monoclonal antibody, against GVHD. Despite reducing some of the symptoms and organ manifestations, reported outcomes were poor.8,9

Chimerism, the coexistence of genetically different cells in the same organ or organism, was first recognized after LT in 1969 and may include replacement donor reticuloendothelial cells, endothelium, bile-duct epithelium, and hepatocytes with recipient tissue.10,11 Systemic microchimerism, where donor-derived cells (especially hematopoietic cells) establish themselves in the recipients, was first demonstrated after LT in 1992.12

As an estimated 109–1010 donor lymphoid cells are transplanted together with a liver graft,13 chimerism regularly occurs over a period of 3–4 weeks after LT. Thus, GVHD predominantly occurs in the first few weeks after LT.

It is assumed that macrochimerism with more than 1% of circulating nucleated cells of donor origin in the peripheral blood commonly precedes GVHD but this is not totally accepted at the time of diagnosis.14,15

Two main risk factors for the development of GVHD after OLT have been determined: human leukocyte antigen (HLA) matching between the donor and the recipient; and the recipient's age.1 Donor–recipient compatibility for HLA-B but not for HLA-A or DR was identified as a significant risk factor for the development of GVHD.16 With an HLA-A and HLA-B mismatch of 3–4, the relative risk of the development of GVHD after OLT was estimated to be 1%. Relative risk increased to 7% in the presence of 0–1 HLA-A and HLA-B mismatches, and reached approximately 12.5% in the additional presence of 0–1 HLA-DR mismatches.1

With increasing age of the recipient the risk of GVHD seems to rise. It was reported to be nine-fold higher for recipients older than 65 years of age compared with younger recipients,3 as was shown in our case. Concerning the risk factors for developing GVHD after LT, no correlation of autoimmune hepatitis or alcoholic liver cirrhosis in combination with glucose intolerance and hepatocellular carcinoma could be detected in our case.

Usually, the first signs of GVHD are skin lesions manifesting as a skin rash.17 GVHD can also affect other organs systems such as lung, intestine and brain.18 Pancytopenia, which is uncommon in GVHD after stem-cell transplantation, manifests regularly in patients with GVHD after LT.14 GVHD after OLT occurs less frequently than it does after stem-cell transplantation, but mortality is markedly higher. Basically in stem-cell transplantation the liver is a frequent target organ of GVHD, it is the origin of T cells which regularly affect the bone marrow thus leading to pancytopenia. Importantly, macrochimerism is only a diagnostic tool in GVHD after LT.

In many cases, the first manifestation of the immune reaction of donor lymphoid tissue against host tissue occurs in the skin. A maculopapular eruption can be a clue to the diagnosis and may facilitate early modification of the therapeutic strategy. Differential diagnosis of skin symptoms includes drug-induced eruptions and viral infections. An accurate diagnosis can be achieved by using specific histological and immunohistochemical criteria.19,20 Histological changes include the following: in grade I, lymphocytic infiltrates in the upper dermis without epidermal changes; in grade II, vacuolization of basal cells; in grade III, subepidermal clefts through confluence of basal vacuolization; and, in grade IV, massive necrosis of keratinocytes resembling toxic epidermal necrolysis GVHD.21

Our patient had an indisputable form of GVHD with the entire spectrum of signs and symptoms. On day 31, the patient developed a fever, a skin rash, diarrhea, profound leukopenia, anemia, low hemoglobin and low blood pressure levels. A skin biopsy showed histological signs of GVHD, such as spongiosis, basal cell hydropic changes, many apoptotic keratinocytes and lymphocytic exocytosis (including satellite-cell necrosis) in the epidermis. Furthermore, there was a subepidermal cleft formation (grade III of acute GVHD). The differential diagnosis can be difficult, as many other causes of these symptoms must be considered in the post-transplantation phase, most importantly, acute organ rejection and infectious complications.22

We failed to demonstrate bacterial, viral and fungal causes of gastrointestinal symptoms and the histology of resected specimens was consistent with GVHD.

We test peripheral blood for macrochimerism upon readmission of a patient showing typical symptoms of GVHD, and we routinely treat such cases as GVHD if peripheral blood chimerism is >1%, whilst supporting evidence for the diagnosis is sought.

Standard treatment of GVHD comprises increased immunosuppression with high-dose steroids and antibody preparations such as antithymocyte globulin, antilymphocyte globulin and Prednisolone. There is no evidence that steroids alone are effective in GVHD.14,23,24,25

Our case was subjected to treatment with methylprednisolone and antithymocyte globulin, which was clearly ineffective.

As far as the treatment is concerned, the data suggest that an early start to therapy is no determinant of outcome. Broad antibiotic and antifungal prophylaxis is pivotal, because septic complications are frequent in GVHD.26 Another issue relates to the treatment of GVHD. It may be reasonable to focus treatment on the restoration of the host's immune system. Thus, there are recent reports of three patients with GVHD after OLT in whom immunosuppression was stopped. Two of them survived, indicating a better outcome with this therapeutic strategy,16,27 by inducing a host-versus-graft alloimmune response against host-reactive donor-derived cells. Moreover, withdrawal of immunosuppression may help the recipient's immune system to reconstitute itself, thereby reducing the risk of infection. On the other hand, with regard to the risk of developing uncontrollable rejection, it seems that in patients with a peripheral chimerism of more than 10% after OLT, immunosuppressants can be reduced or even withdrawn without any increased risk of rejection.28

Another theoretical option that can be considered for GVHD after LT is re-transplantation. Basically, GVHD might be terminated by just removing the graft. However, so far there are no data in the literature supporting the idea of eliminating the donor-aggressive graft as an effective therapeutic option. One of the major doubts relates to the fact that the donor-reactive alloimmune response is no longer generated by the liver itself, but is generated by donor cells, which have already spread into the periphery and bone marrow of the host.29

In conclusion, although acute GVHD is rare complication of liver transplantation and the mortality is still very high, skin lesions represent an important tool for early diagnosis. The prognosis remains poor, and further research is needed to both clarify the pathogenesis of GVHD and provide new therapeutic agents for treating this condition effectively.

Table 1

Postoperative laboratory investigation.

S. UreaS. Creatinine	180.81	mg/dlmg/dl
INRPlatelets	1.495	mil/mm3
HematocritHeamoglobinLeukocytes	33.911.173.62	%g/dlmil/mm3
S. SodiumS. PotassiumS. Glucose	1443.789	mEq/LmEq/Lmg/dl
Total BillirubinDirect BillirubinASTALT	0.950.465635	mg/dlmg/dlU/LU/L

S. – serum; INR – international normalized ratio; AST – aspartate aminotransferase; ALT – alanine aminotransferase.

Table 2

Postoperative laboratorial investigation.

	Immediately Postoperative	5th PO	10th PO	25th PO	31st PO(ICU Readmission)	33th PO (GVHD Diagnosis	36th PO
S. UreaS. Creatinine	410,77	450,55	290,71	421,02	761,25	691,27	1092,56	mg/dlmg/dl
INRPlatelets	3,2110	1,60NM	1,696	1,1114	1,253	1,557	1,8284	-mil/mm3
HematocritHeamoglobinLeukocytes	32.910,710,65(Neutrophil-88,50%)	34.110,912,55(Neutrophil-78,8%, Eosinophil 9,2%)	29.49,69,56(Neutrophil-93%, Segmented 83%)	28.49,53,18	28.09,20,45	20.16,60,1	23.17,443,36(Neutrophil-93,%, Monocytes 3,0%, Lymphocutes 3,7%)	%g/dlmil/mm3
S. SodiumS. PotassiumS. Glucose	1404,6-	138396	1423,693	1354,9-	1344,9-	1364-	1354,4-	mEq/LmEq/Lmg/dl
Total BilirubinDirect BilirubinASTALT	3,892,2523081842	6,714,74136933	9,087,48213319	2,571,625060	1,831,326064	1,420,575731	2,932,4220849	mg/dlmg/dlU/LU/L

S. – serum; INR – international normalized ratio; AST – aspartate aminotransferase; ALT – alanine aminotransferase; NM – not mentioned; ICU – intensive care unit; GVHD – graft versus host disease.

Table 3

Literature review.

Reference	Patients	Basic IS	Onset	Chimerism	Therapy	Outcome
Burdick et al. (1988)	1	CsA, AZA, PSL	21	+	ATG, PSL	Alive
Bhaduri et al. (1990)	1 child	AZA, PSL	23	+	Anti-L-AB, PSL	Dead
Marubayashi et al. (1990)	1	CsA, AZA, PSL	13	+	Anti-L-AB, PSL	Dead
Merle et al. (1990)	1	-	30	+	Anti-IL2R	Dead
Jamieson et al. (1991)	2	CsA, PSL, AZA, IL2-R blocker	18/30	+	CsA, PSL, ATG	1x dead
Roberts et al. (1991)	4	CsA, AZA, PSL	18–42	ND	3x IS increase with PSL	4x dead
Comenzo et al. (1992)	1 child	CsA, PSL	95	+	IS increase	Alive
Collins et al. (1992)	1	CsA, AZA, PSL	35	+	PSL	Dead
De Paoli et al. (1992)	1	–	14	+	ATG, PSL	Dead
Joysey et al. (1992)	1	–	38	+	ATG, PSL	Dead
Mazzaferro et al. (1993)	1	CsA, PSL	17	+	PSL	Dead
Rosen et al. (1993)	1	–	24	–	Anti L-AB	Dead
Redondo et al. (1993)	1	–	25	+	Muromonab-CD3, PSL	Alive
Neumann et al. (1994)	1	CsA, AZA, PSL	32	+	ATG, Muromonab-CD3	Dead
Cattral et al. (1994)	1 child	CsA, PSL	16	+	PSL	Alive
Pageaux et al. (1995)	1	CsA, AZA, PSL	18	+	ATG, PSL	Dead
Connors et al. (1996)	1	FK506, PSL	24	+	-	Dead
Sanchez et al. (1996)	1	CsA, AZA, PSL	34	+	Muromonab-CD3	Dead
Whitington et al. (1996)	1 child	CsA, AZA, PSL	34	+	ATG	Alive
Burt et al. (1996)	1	–	28	+	PSL	Dead
Kiuchi et al. (1998)	1 child	–	27	+	–	Dead
Aziz et al. (1998)	1	CsA, AZA, PSL	15	–	ATG	Alive
Paizis et al. (1998)	1	–	21	+	Muromonab-CD3	Alive
Schmuth et al. (1999)	1	FK506, PSL	7	+	AZA, PSL	Dead
Joseph et al. (1999)	1	CsA, AZA, PSL	35	+	CsA, cyclophosphamide	Dead
Merhav et al. (1999)	1	FK506, PSL	30	+	CsA, PSL, ATG	Dead
Hahn et al. (2000)	2	CsA, PSL/FK506, PSL	35/21	+	Muromonab-CD3/Stop IS	Dead/Alive
Au et al. (2000)	1	FK506, PSL	20	+	AZA, PSL	Dead
Hanaway et al. (2001)	1	–	18	–	ATG, PSL	Dead
Romognoulo et al. (2000)	1	PLS, CsA	23	–	AZA, PSL	Dead
Knox et al. (2002)	1	FK506, MMF, PSL	17	+	PSL	Alive
Lehner et al. (2002)	1	MMF, IL-2R	21	+	Stop IS	Alive
Smith et al. (2003)	13	CNI, AZA, PSL	8–115	+	IS increase PSL, AntiL-AB	12x Dead
Sudhindran et al. (2003)	2	FK506, PSL, AZA	24/31	+	PSL, IL-2R blocker	Alive/Dead
Soejima et al. (2004)	4	CsA, PSL, FK506	27–114	+	IS increase FK506, PSL, CsA, ATG	2x Dead
Key et al. (2004)	7	CNI, AZA, PSL	14–56	+	IS increase PSL, ATG, IL-2R blocker	5x Dead
Hara et al. (2004)	1	CsA, PSL	20	+	Change CsA to FK506, ATG	Dead
Walling et al. (2004)	1	FK506, PSL	70	+	MMF, PSL	Alive
Pollack et al. (2005)	1	FK506, MMF, PSL	240	+	Muromonab-CD3, SCT	Dead
Kamei et al. (2006)	8	–	14–114	–	–	8x Dead
Sun et al. (2006)	1	FK506, MMF, PSL	122	+	PSL	Dead
Schappi et al. (2006)	1 child	MMF, FK506, PSL, IL2-R blocker	1	+	IL-2R blocker, alemtuzumab, ATG, PSL	Dead
Ghali et al. (2007)	1	IL2-R blocker, MMF, and PSL, FK506	ND	+	ATG, PSL, IL-2R blocker, G-CSF, erythropoietin	Dead
Chinnakotta et al. (2007)	3	2x MMF, FK506, PSL/1x CsA, PSL, RAPA	07-70	+	Stop IS	2x Alive
Perri et al. (2007)	5	Standard IS	23–35	+	PSL, ATG and antiIL2R	5x Dead
Wang et al. (2007)	2	FK506, PSL, MMF/CsA, PSL	24/32	ND	PSL, G-CSF, GM-CSF	Dead/Alive
Cho et al. (2007)		FK506, PSL	56	+	IS increase	Dead
Guo et al. (2008)	2	FK506, PSL	40–59	+	PSL	2x Dead
Kohler et al. (2008)	5	1x IL2-R blocker, CSA, AZA, PSL/4x PSL, FK506	20–60	+	ATG, Muromonab-CD3/PSL, ATG/PSL, ATG/PSL	5x Dead
Thin et al. (2008)	1	PSL, FK506, AZA	20	+	G-CSF, PSL, CsA, MMF, etanercept	Alive
Grosskreutz et al. (2008)	1	FK506, PSL	45	+	PSL	Alive
Lu et al. (2008)	1	Radiosone, PSL, FK506	18	ND	Stop IS, thymosin Alpha 1, ATG, IL-2R blocker	Alive
Stotler et al. (2009)	1	–	20	+	Alefacept	Alive
Piton et al (2009)	1	FK506, PSL	21	+	PSL, ATG, infliximab	Alive

ATG, antithymocyte globulin; AZA, azathioprine; CNI, calcineurin inhibitor; CsA, cyclosporine; FK506, tacrolimus; G-CSF, granulocyte colony stimulating factor; GM-CSF, granulocyte macrophage colony stimulating factor; IL-2R blocker, interleucin-2 receptor blocker; IS, immunosuppression; MMF, mycophenolate mofetil; PSL, prednisolone; RAPA, rapamycin; SCT, stem-cell transplantation.

ND, not described.