Role of circulating soluble CD40 as an apoptotic marker in liver disease.

OBJECTIVES: To measure levels of soluble CD40, a laboratory marker of apoptosis in patients with liver disease, determine its origin, and correlate the findings with disease activity and histology. DESIGN: Laboratory research study with comparison group. SETTING: Liver Institute, Laboratory of HLA Typing and Histopathology Department, Rabin Medical Center, Israel. SUBJECTS: One hundred ten patients with liver disease and 20 healthy controls. METHODS: Serum samples were collected from all patients; in addition, paired hepatic and portal vein samples were collected from 23 patients, and bile samples from 5 patients. Soluble CD40 was measured with an enzyme-linked immunosorbent assay. Apoptotic cells in liver tissue were identified by morphological criteria and quantified with the TUNEL assay. RESULTS: Soluble CD40 concentration was significantly higher in patients with liver disease than controls (mean 112.9 +/- 197.2 pg/ml vs. 24.2 +/- 9.1 pg/ml, p = 0.0001), with highest levels in the chronic viral hepatitis group (mean 131.7 +/- 137.5 pg/ml, p = 0.0001). Levels of sCD40 were correlated with serum creatinine, alkaline phosphatase, alpha-feto protein, and the apoptotic index. In the 23 paired samples, CD40 level was higher in the hepatic vein (mean 74.9 +/- 114.5 pg/ml) than the portal vein (mean 51.6 +/- 67.9 pg/ml); it was highly detectable in bile (mean 115.6 +/- 119.6 pg/ml, p = 0.0123). Untreated patients with chronic viral hepatitis (B and C) had higher levels (mean 106.2 +/- 76.5 pg/ml) than treated patients (mean 59.3 +/- 68.6 pg/ml, p = 0.049). CONCLUSIONS: Levels of soluble CD40 increase in different types of liver disease. It probably derives from the liver and is secreted into the bile. Levels correlate with the apoptotic index and are affected by antiviral treatment. Soluble CD40 may serve as a serum marker of apoptosis in liver disease.

Replicative senescence in organ transplantation-mechanisms and significance.

In the past two decades, transplantation has become a preferred modality of treatment of end-stage failure of vital organs. Currently, with the significant improvement in short-term graft survival rates, the main effort is concentrated on prolonging the functional life span of transplanted organs. One of the theories which were put forward to explain the progressive deterioration of transplant function was that of replicative senescence. Senescence of an organ or tissue results from age and/or environmental stress-dependant modification of cellular function. With time, the accumulation of cellular alterations may lead to deleterious effects in various organs and tissues and adversely affect transplants. In this article we are reviewing the candidate mechanisms of senescence such as telomere shortening, genetic regulation and environmental-'toxic' factors and are examining the implications of the theory of replicative senescence for organ allograft. We are also presenting our experiments with renal ischemia/reperfusion in rat serving as a model of kidney transplantation, where baseline kidney telomere length and novel marker of cellular senescence--senescence associated beta-Galactosidase (SA-Gal) expression in tissue served as markers. For the first time in vivo, we were able to show that with aging of the animals the amount of senescent cells in kidney tissue was increasing, while the average renal tissue telomere length was decreasing. The degree of tissue senescence, as determined by amount of SA-Gal positively stained cells, was inversely correlated with the recovery of the kidney function after ischemia/reperfusion injury. These results confirm the theory of replicative senescence in organ ischemia for the first time in vivo, and quantitatively validate the direct correlation between the amount of senescent cells in the organ and its susceptibility to ischemic injury. We conclude that recent advances in study of the cellular basis of senescence, in vitro and especially in vivo, may hold clues to the understanding of events which could be implicated in the damage or protection of organ allografts.