Complement activation during an active cytomegalovirus infection after renal transplantation: due to circulating immune complexes or alternative pathway activation?

Exploration of complement split products in plasma and urine as biomarkers of kidney graft rejection

INTRODUCTION

The complement system, consisting of more than thirty different soluble and cell-bound proteins, exerts essential functions both in the innate and adaptive immune systems and is believed to be an important contributor to allograft injury in kidney transplantation. The anaphylatoxins C3a and C5a are powerful chemoattractants, recruiting immune effector cells toward the site of complement activation and enhance T-cell response, while C3dg binding to CR2 on B-cells, enhances B-cell immunity at several stages of the B-cell differentiation. Complement split products in plasma and urine could reflect ongoing inflammation and tissue injury. We, therefore, investigated if complement split products increase in plasma and urine in kidney transplant recipients with rejection.

METHOD

In this case-control feasibility study, complement factors C3a, C3dg, C4a, and C5a were measured in plasma and C3dg and sC5b-9 associated C9 neoantigen in urine in 15 kidney transplant recipients with rejection (cases) and 15 kidney transplant recipients without (controls). The groups were matched on the type of transplantation and the time from transplantation to sampling. The complement split products were compared (i) between cases and controls and (ii) within the rejection group over time, comparing the measurements at rejection with measurements where the kidney transplant recipients were clinically stable. Possible moderators were explored, and results adjusted accordingly. P values < 0.05 were considered significant. Plasma C3dg was analyzed by immune-electrophoresis, plasma C3a, plasma C4a, and plasma C5a by flow cytometry, and urine C3dg and urine C9neo by ELISA.

RESULTS

In plasma, there were no significant differences between the rejection and the control group. However, steroids and pretransplant C3dg levels significantly influenced C3dg. Within the rejection group, plasma C3a and C3dg were significantly higher at the time of rejection compared to the stable phase (p < 0.01). In urine, C3dg/creatinine and C9 neoantigen/creatinine ratios were not different between the rejection and the control group. Urine C3dg/creatinine and urine C9 neoantigen/creatinine ratios correlated to urine albumin and significantly increased after the transplantation (p < 0.001).

CONCLUSION

This study shows increased plasma C3a and C3dg in kidney transplant recipients, primarily with T cell mediated rejection. This finding suggests that consecutive measurements of C3a and C3dg in plasma could be applicable to monitor alloreactivity in kidney transplant recipients. Urine complement split products are unsuitable as rejection biomarkers since the permeability of the glomerular filtration barrier strongly influences them. Prospective longitudinal studies on plasma C3a and C3dg dynamics will be needed to validate present findings.

Secondary antibody deficiency is associated with development of infection in kidney transplantation: Results of a multicenter study

BACKGROUND

We performed a multicenter study to assess the association between secondary antibody deficiency (immunoglobulin G [IgG] hypogammaglobulinemia combined with low levels of specific antibodies) and development of infection in kidney transplantation.

METHODS

We prospectively analyzed 250 adult kidney recipients at four centers. The assessment points were before transplantation and 7 and 30 days after transplantation. The immune parameters were as follows: IgG, IgA, and IgM and complement factors C3 and C4 tested by nephelometry; specific IgG antibodies to cytomegalovirus (CMV) and IgG and IgG2 antibodies to pneumococcal polysaccharide (anti-PPS) determined using enzyme-linked immunosorbent assay. The clinical follow-up period lasted 6 months. The clinical outcomes were CMV disease and recurrent bacterial infections requiring antimicrobial therapy.

STATISTICS

Multivariate logistic regression.

RESULTS

At day 7, IgG hypogammaglobulinemia (IgG levels < 700 mg/dL) combined with low IgG anti-CMV antibody titers (defined as levels < 10 000 units) was present in 12% of kidney recipients. IgG hypogammaglobulinemia combined with low IgG anti-PPS antibody titers (defined as levels < 10 mg/dL) at 1 month after kidney transplantation were recorded in 16% of patients. At day 7 the combination of IgG hypogammaglobulinemia and low anti-CMV titers was independently associated with the development of CMV disease (odds ratio [OR], 6.95; 95% confidence interval [CI], 1.17-41.31; P = .033). At day 30 after transplantation, the combination of IgG < 700 mg/dL and IgG anti-PPS < 10 mg/dL, was independently associated with recurrent bacterial infection (OR, 5.942; 95% CI, 1.943-18.172; P = .002).

CONCLUSION

In a prospective multicenter study, early immunologic monitoring of secondary antibody deficiency proved useful for the identification of kidney recipients who developed severe infection.

Impact of in vivo complement activation and cryoglobulins on graft outcome of HCV-infected renal allograft recipients

BACKGROUND

Chronic hepatitis C virus (HCV) infection is closely associated with mixed cryoglobulinemia. Cryoglobulins can activate complement leading to vascular damage. We examined whether cryoglobulinemia and complement turnover is associated with HCV infection in renal transplant recipients and whether this has an adverse effect on graft outcome.

METHODS

Sera and fresh plasma from 31 HCV-RNA-positive patients after renal transplantation (group I) were studied for cryoglobulins, complement hemolytic activity (CH50), and complement split product C3d. In total, 80 HCV-negative renal transplant recipients (group II) and 72 untreated patients with chronic hepatitis C (group III) without renal transplantation served as controls.

RESULTS

Cryoglobulins were detected in 45, 28, and 26% of the patients in group I, II, and III, respectively. A high cryocrit ( > 5%) was present only in patients of group III (p < 0.01%). Mean CH50 values were lower and C3d levels higher in HCV-positive patients (group I and III) compared with HCV-negative patients (p < 0.0001). Cryoglobulins were not associated with extrahepatic manifestations or graft dysfunction, except in five patients of group III demonstrating cryoglobulinemic vasculitis. HCV-positive renal transplant recipients with signs of complement activation showed a significantly greater increase of serum creatinine (0.88 +/- 1.14 mg/dL) when compared with baseline than patients without complement activation (0.34 +/- 0.37 mg/dL; p = 0.035). There was also a tendency toward a higher extent of proteinuria in patients with complement activation (1.38 +/- 2.17 g/d vs. 0.50 +/- 0.77 g/d; p = 0.25, NS).

CONCLUSIONS

Cryoglobulins are common in renal allograft recipients, but do not affect graft function. However, complement activation appears to be involved in chronic allograft dysfunction in HCV-infected recipients.

Cytomegalovirus infection in the liver transplant recipient. Epidemiology, pathogenesis, and clinical management

The effects of cytomegalovirus (CMV) on the liver transplant patient can be divided into two general categories: the direct infectious disease effects (e.g. CMV mononucleosis, hepatitis, pneumonitis, GI infection) and the indirect effects that are mediated by cytokines elaborated as a consequence of the infection. These indirect effects include an immunosuppressive effect that contributes to the development of superinfection with fungi, bacteria, and Pneumocystis carinii; a role in the pathogenesis of allograft injury; and a role in the development of post-transplant lymphoproliferative disease. The two key steps in the pathogenesis of CMV infection-reactivation of the virus from latency and systemic spread-are modulated by the immunosuppressive therapy administered. New antiviral programs, primarily those involving ganciclovir, have resulted in considerable progress in the prevention and treatment of CMV disease among liver transplant recipients.

Detection of renal allograft rejection by complement components C5A and TCC in plasma and urine

Allograft rejection is associated with complement activation. Yet inconsistent results were obtained in evaluating plasma levels of complement factors or activation products as rejection markers. Therefore the human anaphylatoxin C5a and the soluble terminal complement complex (TCC) were measured by daily enzyme immunoassays on plasma (P) and urine (U) samples from 28 patients undergoing renal transplantation over a mean postoperative period of 25.8 days. The complement levels were evaluated longitudinally (cutoff of 100% increase on the previous day's level) during periods of rejection, stable graft function, acute tubular necrosis, and cytomegalovirus disease. Regarding the detection of 13 acute rejection episodes, U-C5a showed a diagnostic accuracy of 81% (sensitivity of 85%, specificity of 77%), P-C5a one of 62%, and P-TCC one of only 30%. The U-C5a increment (mean rise of 379%) preceded the clinical diagnosis of rejection by an average of 1.6 days. Cytomegalovirus diseases (n = 4) were associated with high P-C5a levels (mean increase of 251% by the time of the first detection of viral DNA). In contrast, resumption of kidney function after acute tubular necrosis (n = 10 periods) was heralded by marked peaks of U-C5a (x = 43.7 microg/l). U-TCC was not detected in any clinical setting. In conclusion, as opposed to P-TCC, U-TCC, and P-C5a, the anaphylatoxin C5a, measured daily in urine, might have potential as an early and reliable marker for acute renal allograft rejection.

The anaphylatoxin C5a, a new parameter in the diagnosis of renal allograft rejection

In the underlying study the diagnostic value of the anaphylatoxin C5a was evaluated in kidney transplantation. In 49 transplant patients the following parameters were measured daily for a mean period of 25.1 days: plasma C5a [P-C5a], urine C5a [U-C5a], serum amyloid A [SAA], serum neopterin [S-NEOP] and urine neopterin [U-NEOP]. Sensitivity, specificity and day of first significant parameter increase (exceeding a cut-off level of > 50%) were evaluated retrospectively during 30 periods of rejection and 30 periods of stable graft function. U-C5a was the parameter with the highest sensitivity (84%) and specificity (84%), increasing in the mean 1.3 days before clinical diagnosis of rejection. Sensitivity and specificity of the other markers was lower: SAA 77% and 77%, U-NEOP 68% and 65%, S-NEOP 45% and 77%, and P-C5a 45% and 48%, respectively. During four instances of cytomegalovirus disease extremely high U-NEOP (> or = 1520 +/- 518 mumol/mol creatinine) and slightly increased P-C5a levels (> or = 1.5 +/- 1.4 ng/ml) occurred. Elevated urinary excretion of C5a seems to be a reliable and early marker of renal allograft rejection. In combination with SAA and U-NEOP, the daily assessment of U-C5a differentiates between viral infection and allograft rejection.

Cytomegalovirus infection after organ transplantation: an update with special emphasis on renal transplantation

Cytomegalovirus infections are still the most important infectious complications after organ transplantation. Besides historical notes this review will deal with new aspects concerning the epidemiology of the CMV, diagnostic modalities of CMV infection, the delicate counterbalance between the immune system and the CMV, as well as the symptomatology of this infection. Furthermore, aspects like prophylaxis and new, promising therapeutic regimes for treatment of infection will be dealt with. Although this update is applicable for all types of solid organ transplantation, emphasis will be on renal transplantation.