Baogui Li

Noninvasive diagnosis of renal-allograft rejection by measurement of messenger RNA for perforin and granzyme B in urine

BACKGROUND Acute rejection is a serious and frequent complication of renal transplantation, and its diagnosis is contingent on the invasive procedure of allograft biopsy. A noninvasive diagnostic test for rejection could improve the outcome of transplantation. METHODS We obtained 24 urine specimens from 22 renal-allograft recipients with a biopsy-confirmed episode of acute rejection and 127 samples from 63 recipients without evidence of acute rejection. RNA was isolated from the urinary cells. Messenger RNA (mRNA) encoding the cytotoxic proteins perforin and granzyme B and a constitutively expressed cyclophilin B gene were measured with the use of a competitive, quantitative polymerase chain reaction, and the level of expression was correlated with allograft status. RESULTS The log-transformed mean (+/-SE) levels of perforin mRNA and granzyme B mRNA, which encode cytotoxic proteins, but not the levels of constitutively expressed cyclophiiin B mRNA, were higher in the urinary cells from the 22 patients with a biopsy-confirmed episode of acute rejection than in the 63 recipients without an episode of acute rejection (perforin, 1.4+/-0.3 vs. -0.6+/-0.2 fg per microgram of total RNA; P<0.001; and granzyme B, 1.2+/-0.3 vs. -0.9+/-0.2 fg per microgram of total RNA; P<0.001). Analysis involving the receiver-operating-characteristic curve demonstrated that acute rejection can be predicted with a sensitivity of 83 percent and a specificity of 83 percent with the use of a cutoff value of 0.9 fg of perforin mRNA per microgram of total RNA, and with a sensitivity of 79 percent and a specificity of 77 percent with the use of a cutoff value of 0.4 fg of granzyme B mRNA per microgram of total RNA. Sequential urine samples were obtained from 37 patients during the first nine days after transplantation; and measurements of the levels of mRNA that encoded cytotoxic proteins identified those in whom acute rejection developed. CONCLUSIONS Measurement of mRNA encoding cytotoxic proteins in urinary cells offers a noninvasive means of diagnosing acute rejection of renal allografts.

In vivo expression of transforming growth factor-beta1 in humans: stimulation by cyclosporine.

BACKGROUND Transforming growth factor-beta1 (TGF-beta1) is an immunoregulatory and fibrogenic cytokine. In an earlier in vitro study, we demonstrated that cyclosporine (CsA) increases TGF-beta1 transcription rate in human T lymphocytes. Herein, we explored whether CsA augments the in vivo expression of TGF-beta1 in humans. METHODS The inherent difficulty in studying the in vivo effect of CsA in humans was circumvented by investigating stable end-stage renal disease patients who were preconditioned with CsA before their living donor renal transplantation. Sera and peripheral blood mononuclear cells were obtained from CsA-preconditioned patients and quantified for TGF-beta1 expression at the mRNA (by competitive polymerase chain reaction) and protein (sandwich enzyme-linked immunosorbent assay) levels. RESULTS Our studies demonstrated a significant increase in TGF-beta1 expression after CsA therapy. The stimulatory effect was unique to TGF-beta1, and CsA did not increase interleukin (IL)-10, IL-6, IL-2, or tumor necrosis factor-alpha expression. CONCLUSIONS Our first-time demonstration of a TGF-beta1-selective in vivo stimulatory effect of CsA in humans: (1) advances a TGF-beta1-centered hypothesis for the beneficial (immunosuppression) and detrimental (fibrosis, hypertension) effects of CsA use, and (2) broadens the mechanism of immunosuppressive action of CsA to include heightened expression of an endogenous immunosuppressive cytokine.Background.Transforming growth factor-β1(TGF-β1) is an immunoregulatory and fibrogenic cytokine. In an earlier in vitro study, we demonstrated that cyclosporine (CsA) increases TGF-β1transcription rate in human T lymphocytes. Herein, we explored whether CsA augments the in vivo expression of TGF-β1i

Tacrolimus enhances transforming growth FACTOR-β1 expression and promotes tumor progression

Background. Immunosuppressive therapy is a risk factor for the increased incidence and metastatic progression of malignancies in organ graft recipients. Transforming growth factor (TGF)-&bgr;1 has been associated with tumor invasion and metastasis, and we have implicated cyclosporine-associated TGF-&bgr;1 hyperexpression in tumor progression in mice. Methods. BALB/c mice or severe combined immunodeficient-beige mice were treated with 2 or 4 mg/kg of tacrolimus, and the effect of treatment on mouse renal cancer cell pulmonary metastasis was investigated. We also determined whether tacrolimus induces TGF-&bgr;1 expression. Spleens from tacrolimus-treated mice were analyzed for level of expression of TGF-&bgr;1 mRNA with the use of competitive-quantitative polymerase chain reaction assay, and circulating levels of TGF-&bgr;1 protein were measured with the use of an enzyme-linked immunosorbent assay. Results. Treatment with tacrolimus resulted in a dose-dependent increase in the number of pulmonary metastases in the BALB/c mice (197±16 in untreated mice, 281±26 in mice treated with 2 mg/kg of tacrolimus, and 339±25 in mice treated with 4 mg/kg of tacrolimus; no treatment vs. 4 mg/kg tacrolimus, Bonferroni’s P <0.001) and in the severe combined immunodeficient-beige mice (117±18 in untreated mice, 137±19 in mice treated with 2 mg/kg of tacrolimus, and 216±29 in mice treated with 4 mg/kg of tacrolimus; no treatment vs. 4 mg/kg tacrolimus, P <0.05). Treatment with 4 mg/kg but not 2 mg/kg of tacrolimus resulted in a significant increase in the levels of expression of TGF-&bgr;1 mRNA and circulating levels of TGF-&bgr;1 protein. Conclusions. Tacrolimus has a dose-dependent effect on tumor progression and TGF-&bgr;1 expression, and tacrolimus-induced TGF-&bgr;1 overexpression may be a pathogenetic mechanism in tumor progression.

Molecular executors of cell death--differential intrarenal expression of Fas ligand, Fas, granzyme B, and perforin during acute and/or chronic rejection of human renal allografts.

Two distinct cytolytic pathways have been characterized: one in which the interaction between the Fas antigen and its ligand results in apoptosis, and another in which the pore forming protein perforin and the serine protease granzyme B contribute to DNA fragmentation and cell death. We investigated intrarenal expression of these molecular executors of cell death in light of the potential participation of cytolytically active cellular elements in the antiallograft repertory. Reverse transcriptase-polymerase chain reaction was used to identify intrarenal expression of Fas antigen, Fas ligand, granzyme B and perforin in eighty human renal allograft biopsies; mRNA display was correlated with the Banff histological diagnosis of renal allografts. Our studies demonstrate that: (1) intrarenal expression of Fas ligand mRNA and of granzyme B mRNA are correlates of acute but not chronic rejection; (2) Fas ligand mRNA is not detectable in allografts in the absence of rejection; (3) intrarenal coexpression of members of each lytic pathway (Fas ligand and Fas, granzyme B, and perforin) and that of both pathways (e.g., Fas ligand and granzyme B) are correlates of acute rejection; and (4) a direct correlation exists between the histological severity of acute rejection and intrarenal coexpression of mRNA encoding Fas ligand, Fas, granzyme B, and perforin. Our studies identify, for the first time, the differential expression of the two major lytic pathways in acute and chronic allograft rejection and suggest that specific therapy directed at the cytotoxic attack molecules might be efficacious in the prevention and/or treatment of acute rejection.

TGF-β1 DNA Polymorphisms, Protein Levels, and Blood Pressure

Transforming growth factor-beta1 (TGF-beta1), a multifunctional cytokine with fibrogenic properties, has been implicated in the pathogenesis of the vascular and target organ complications of hypertension. TGF-beta1 may also regulate blood pressure via stimulation of endothelin-1 and/or renin secretion. Herein we explored the hypothesis that circulating levels of TGF-beta1 protein (quantified using a TGF-beta1-specific sandwich ELISA) are correlates of blood pressure levels. This hypothesis was tested in 98 stable end-stage renal disease (ESRD) patients. (The use of ESRD patients as the study cohort eliminates renal function-dependent alterations in circulating levels of TGF-beta1 protein.) In addition, in view of the previously reported correlation among TGF-beta1 DNA polymorphisms and systolic blood pressure, TGF-beta1 codon 25 genotype and alleles were identified in 71 hypertensive subjects and 57 normotensives using amplification refractory mutation system polymerase chain reaction. Our studies demonstrate for the first time that TGF-beta1 levels (209+/-13 ng/mL, mean+/-SEM) are positive correlates (Pearson correlation analysis) of mean arterial pressure (P=0.008), systolic pressure (P=0.02), and diastolic pressure (P=0. 01). We also report that a higher percentage of hypertensives (92%) compared with normotensives (86%) are homozygous for the arginine allele at codon 25. Our observations support the idea that genetically determined TGF-beta1 protein concentrations may play a role in blood pressure regulation in humans.

Regulation of new DNA synthesis in mammalian cells by cyclosporine : demonstration of a transforming growth factor β-dependent mechanism of inhibition of cell growth

Immunosuppressants such as cyclosporine are considered to constrain cell growth by preventing the production of growth stimulatory cytokines (e.g., interleukin-2). The possibility exists, however, that CsA and other immunosuppressants might restrain cell growth by promoting the production of growth-inhibitory cytokines. We have explored herein the hypothesis that CsA stimulates the production of transforming growth factor-beta (TGF-beta), and restrains new DNA synthesis in mammalian cells via a TGF-beta-dependent mechanism. To investigate this new postulate independently of an IL-2-dependent mechanism, we utilized, as probes, two mammalian cell lines, distinguished by their sensitivity to growth inhibition by TGF-beta and resistance to IL-2: CCL-64 mink lung epithelial cells (CCL-64 cells) and A-549 human adenocarcinoma cells (A-549 cells). Our experimental approach revealed the following: (A) CsA and not cyclosporine H, an inactive analogue of CsA, mediates growth inhibition of TGF-beta-sensitive cells, CCL-64 cells, and A-549 cells; (B) CsA stimulates these mammalian cells to secrete TGF-beta; and (C) TGF-beta induced by CsA is biologically active in inducing cell growth inhibition (demonstrated by the reversal of CsA-associated inhibition with anti-TGF-beta monoclonal antibodies). Our observations suggest that CsA can regulate cell growth via a TGF-beta-dependent mechanism. Since the multifunctional cytokine TGF-beta can enhance extracellular matrix accumulation as well as augment endothelin production, our findings also advance a mechanism that links, via TGF-beta, the beneficial (immunosuppression) and the harmful (fibrosis, hypertension) consequences of CsA usage.

In vivo hyperexpression of transforming growth factor-beta1 in mice: stimulation by cyclosporine.

BACKGROUND We have demonstrated that cyclosporine (CsA) stimulates transforming growth factor (TGF) beta1 expression in vitro and that growth of mammalian cells can be arrested by CsA via a TGF-beta1-dependent mechanism. Herein, we have explored whether CsA stimulates TGF-beta1 hyperexpression in vivo. METHODS Four groups of B6AF1 mice were studied: group 1, control; group 2, CsA pretreatment; group 3, anti-CD3 monoclonal antibody pretreatment; and group 4, CsA plus anti-CD3 pretreatment. RESULTS CsA pretreatment augmented TGF-beta1 protein expression and increased intrarenal display of TGF-beta1 mRNA. This heightened TGF-beta1 expression was associated with an impaired T cell proliferative response. CONCLUSIONS Our observations, together, advance the hypothesis that CsA might function in vivo as an immunosuppressant not only by inhibiting the expression of proinflammatory cytokines (e.g., interleukin 2), but also by stimulating the expression of TGF-beta1, a potent immunosuppressive cytokine. Moreover, prevention of TGF-beta1 hyperexpression might prevent CsA-associated renal fibrosis, as TGF-beta1 is a fibrogenic cytokine.

CD103 mRNA levels in urinary cells predict acute rejection of renal allografts1

Background. CD103 is displayed on the cell surface of alloreactive CD8 cytotoxic T lymphocytes (CTLs) and is a critical component for the intraepithelial homing of T cells. Because intratubular localization of mononuclear cells is a feature of acute cellular rejection of renal allografts, we explored the hypothesis that CD103 messenger (m)RNA levels in urinary cells predict acute rejection. Methods. We collected 89 urine specimens from 79 recipients of renal allografts. RNA was isolated from the urinary cells, and we measured CD103 mRNA levels and a constitutively expressed 18S ribosomal (r)RNA with the use of real-time quantitative polymerase chain reaction assay. Results. CD103 mRNA levels, but not 18S rRNA levels, were higher in urinary cells from 30 patients with an episode of acute rejection (32 biopsies and 32 urine samples) compared with the levels in 12 patients with other findings on allograft biopsy (12 biopsies and 12 urine samples), 12 patients with biopsy evidence of chronic allograft nephropathy (12 biopsies and 12 urine samples), and 25 patients with stable graft function after renal transplantation (0 biopsies and 33 urine samples) (P = 0.001; one-way analysis of variance). Acute rejection was predicted with a sensitivity of 59% and a specificity of 75% using natural log-transformed value 8.16 CD103 copies per microgram as the cutoff value (P = 0.001). Conclusion. CD103 mRNA levels in urinary cells are diagnostic of acute rejection of renal allografts. Because CD103 is a cell surface marker of intratubular CD8 CTLs, a noninvasive assessment of cellular traffic into the allograft may be feasible by the measurement of CD103 mRNA levels in urinary cells.

SERINE PROTEINASE INHIBITOR-9, AN ENDOGENOUS BLOCKER OF GRANZYME B/PERFORIN LYTIC PATHWAY, IS HYPEREXPRESSED DURING ACUTE REJECTION OF RENAL ALLOGRAFTS

Background. Serine proteinase inhibitor (PI)-9 with a reactive center P1 (Glu)-P1′ is a natural antagonist of granzyme B and is expressed in high levels in cytotoxic T lymphocytes (CTL). In view of the role of CTL in acute rejection, we explored the hypothesis that PI-9 would be hyperexpressed during acute rejection. Because PI-9 can protect CTL from its own fatal arsenal and potentially enhance the vitality of CTL, we examined whether PI-9 levels correlate with the severity of rejection as well as predict subsequent graft function. Methods. We obtained 95 urine specimens from 87 renal allograft recipients. RNA was isolated from the urinary cells and mRNA encoding PI-9, granzyme B, or perforin and a constitutively expressed 18S rRNA was measured with the use of real-time quantitative polymerase chain reaction assay, and the level of expression was correlated with allograft status. Results. The levels of PI-9 (P =0.001), granzyme B (P <0.0001), and perforin mRNAs (P <0.0001), but not the levels of 18S rRNA (P =0.54), were higher in the urinary cells from the 29 patients with a biopsy-confirmed acute rejection than in the 58 recipients without acute rejection. PI-9 levels were significantly higher in patients with type II or higher acute rejection changes compared with those with less than type II changes (P =0.01). Furthermore, PI-9 levels predicted subsequent graft function (r =0.43, P =0.01). Conclusions. PI-9 mRNA levels in urinary cells are diagnostic of acute rejection, predict renal allograft histology grade, and predict functional outcome following an acute rejection episode.

Molecular signatures of urinary cells distinguish acute rejection of renal allografts from urinary tract infection

Acute rejection (AR) and urinary tract infection (UTI) continue to plague renal transplantation. We tested the hypotheses that UTI does not increase granzyme B mRNA levels in urinary cells, and that the levels distinguish AR from UTI. We measured the levels of granzyme B mRNA in 15 urine specimens from renal allograft recipients with UTI, 29 specimens from patients with AR but without UTI, and 14 specimens from patients without AR and without UTI. We also measured transcript levels in urine specimens from 41 nontransplant individuals, 11 with UTI and 30 without UTI. UTI did not increase granzyme B mRNA levels. Granzyme B mRNA levels were lower in renal allograft recipients with UTI compared with those with AR (P<0.0001). We conclude that bacterial UTI is unlikely to confound AR diagnosis made by measurement of granzyme B mRNA levels in urinary cells.