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Serum Concentrations of Markers of TNF and Fas-Mediated Pathways and Renal Function in Nonproteinuric Patients with Type 1 Diabetes

Monika A. Niewczas^*,,, Linda H. Ficociello^*, Amanda C. Johnson^*, William Walker^*, Elizabeth T. Rosolowsky^*,, Bijan Roshan^*, James H. Warram^*, and Andrzej S. Krolewski^*,

^* Research Division of Joslin Diabetes Center, Boston, Massachusetts; Department of Medicine, Harvard Medical School, Boston Massachusetts; Department of Immunology, Transplant Medicine and Internal Diseases, Warsaw Medical University, Warsaw, Poland; and Division of Endocrinology, Children's Hospital, Boston, Massachusetts

Correspondence: Dr. Andrzej S. Krolewski, Section on Genetics and Epidemiology, Joslin Diabetes Center, One Joslin Place, Boston, MA, 02215. Phone: 617-732-2668; Fax: 617-732-2667; E-mail: andrzej.krolewski{at}joslin.harvard.edu

	Abstract

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Background and objectives: The aim of our study was to examine serum markers of the TNF and Fas pathways for association with cystatin-C based estimated glomerular filtration rate (cC-GFR) in subjects with type 1 diabetes (T1DM) and no proteinuria.

Design, setting, participants, & measurements: The study group (the 2nd Joslin Kidney Study) comprised patients with T1DM and normoalbuminuria (NA) (n = 363) or microalbuminuria (MA) (n = 304). Impaired renal function (cC-GFR <90 ml/min) was present in only 10% of patients with NA and 36% of those with MA. We measured markers of the tumor necrosis factor (TNF) pathway [TNF, soluble TNF receptor 1 (sTNFR1), and 2 (sTNFR2)], its downstream effectors [soluble intercellular and soluble vascular adhesion molecules (sICAM-1 and sVCAM-1), interleukin 8 (IL8/CXCL8), monocytes chemoattractant protein-1 (MCP1), and IFN inducible protein-10 (IP10/CXCL10)], the Fas pathway [soluble Fas (sFas) and Fas ligand (sFasL)], CRP, and IL6.

Results: Of these, TNF, sTNFRs, sFas, sICAM-1, and sIP10 were associated with cC-GFR. However, only the TNF receptors and sFas were associated with cC-GFR in multivariate analysis. Variation in the concentration of the TNF receptors had a much stronger impact on GFR than clinical covariates such as age and albumin excretion.

Conclusions: Elevated concentrations of serum markers of the TNF and Fas-pathways are strongly associated with decreased renal function in nonproteinuric type 1 diabetic patients. These effects are independent of those of urinary albumin excretion. Follow-up studies are needed to characterize the role of these markers in early progressive renal function decline.

	Introduction

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The traditional model of the development of end-stage renal disease in type 1 diabetes mellitus (T1DM), in which microalbuminuria (MA) leads to proteinuria and then proteinuria is followed by renal function loss, has been challenged recently. Increase in urinary albumin excretion is an important determinant of diabetic nephropathy progression, but it does not entirely explain this phenomenon. For example, the loss of renal function commences earlier than previously recognized and precedes the onset of proteinuria (1). In our longitudinal study of T1DM (The First Joslin Study of Natural History of Microalbuminuria), renal function decline began with the onset of MA in about one-third of patients and progressed in a linear fashion from normal kidney function to renal insufficiency. Also, renal function decline occurred in a noticeable proportion of patients with T1DM and normal albumin excretion (1,2).

Low-grade chronic inflammation is thought to be involved in the pathogenesis of diabetic nephropathy (3,4). Tumor necrosis factor alpha (TNF/TNF) is a key mediator of inflammation and plays a role in apoptosis. In animal models, its effects on kidneys include reduced glomerular filtration rate (GFR) and increased albumin permeability (3). It mediates its signal via two distinct receptors, TNF receptor 1 (TNFR1/TNFRSF1A) and TNF receptor 2 (TNFR2/TNFRSF1B), which are membrane-bound and also present in soluble form in serum (5). TNF mediates its inflammatory effects by induction of a broad spectrum of chemokines, including interleukin 8 (IL8/CXCL8); monocyte chemotactic protein-1 (MCP-1/CCL2); IFN- inducible protein-10 (IP-10/CXCL10); and adhesion molecules such as intercellular adhesion molecule-1 (ICAM-1) and vascular adhesion molecule-1 (VCAM-1) (6,7).

The Fas pathway mediates apoptosis and may play a role in the progression of diabetic nephropathy (8–11). The binding of Fas ligand (FasL) to Fas, its membrane-bound receptor that is also present in serum in soluble form (sFasL, sFas), leads to an apoptotic response (12,13).

Most studies on serum markers of TNF-mediated inflammation and apoptosis in diabetic nephropathy have explored their association with MA and proteinuria rather than with GFR (14).

The goal of this large cross-sectional study was to investigate whether serum concentrations of markers mediated by TNF (sTNFR1, sTNFR2, sICAM-1, sVCAM-1, IL8, MCP-1, IP-10) or involved in Fas-related apoptosis (sFasL and sFas) are associated, independently from albuminuria, with variation in renal function in patients with T1DM who do not have proteinuria or advanced renal function impairment. This knowledge should facilitate the development of new diagnostic tools for identifying patients with early renal function decline and help the search for intervention protocols for high-risk patients that may be more effective if implemented 5 to 10 yr earlier in the disease course.

In this study, the GFR was estimated by a cystatin C-based formula (cC-GFR), previously shown as an accurate way of evaluating renal function in patients with diabetes (15,16)

	Materials and Methods

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The Committee on Human Subjects of the Joslin Diabetes Center approved the protocol and informed consent procedures for this study.

The study group was selected from the population attending the Joslin Clinic, a major center for the treatment of patients of all ages with T1DM or type 2 diabetes mellitus (T2DM). The population is about 90% Caucasian, and most reside in eastern Massachusetts. Between January 1, 2003 and December 31, 2004, patients with T1DM attending the Joslin Clinic were recruited into the Second Joslin Study on the Natural History of Microalbuminuria. Detailed descriptions of the Joslin Clinic population and the recruitment protocol for this study have been published previously (17). Eligibility criteria included residence in New England, diabetes diagnosed before age 40 yr, treatment with insulin, current age 18 to 64 yr, diabetes duration 3 to 39 yr, and multiple measurements in the preceding 2-yr interval of hemoglobin A1c (HbA1c) and urinary albumin-to-creatinine ratio (ACR). For each patient, the measurements of HbA1c were summarized by the mean, and the measurements of ACR by the median. Exclusion criteria included proteinuria (median ACR 250 for men and 355 µg/min for women), end-stage renal disease, other serious illness, extreme obesity (body mass index > 40 kg/m²), or a median HbA1c less than 6.5% (near normoglycemia).

Enrollment and Examination
Trained recruiters administered a structured interview and brief examination to eligible patients at a routine visit to the clinic (i.e., the enrollment visit). The interview solicited the history of diabetes and its treatment, other health problems, and use of medications. The recruiter measured seated blood pressure twice (5 min apart) with an automatic monitor (Omron Healthcare, Inc), averaged them to reduce variability, and obtained samples of blood and urine. At of the end of 2004, this study group included 667 participants: 304 with MA and 363 with normoalbuminuria (NA).

Assessment of Exposure Variables
Current and past use of medications (particularly angiotensin converting enzyme inhibitors, angiotensin II receptor blockers, and other antihypertensive drugs) was recorded during the enrollment interview and supplemented by examination of clinic records to confirm prescription dates. We also extracted all archived clinical laboratory measurements of HbA1c, ACR, and serum cholesterol. Details of the assays used were described previously (18,19). ACR values were converted to albumin excretion rate (AER) according to a formula published previously (19). For characterizing patients’ recent exposures, repeated measures were summarized by their median (AER) or mean (HbA1c, cholesterol, lipids).

Sample Collection and Laboratory Measurements
Enrollment blood samples were drawn by venipuncture into sterile collection tubes (SST Plus BD Vacutainer, BD, New Jersey); centrifuged at 3600 rpm for 10 min at 6°C (Centrifuge 5810 R); and then aliquoted into 1.5-ml sterile, nontoxic, nonpyrogenic tubes cryogenic tubes (CryoTubes CryoLine System; NUNC TM Serving Life Science) and frozen at –80°C until further analysis. Length of storage, defined as the interval between the dates of sample collection and assay determination (range 2 to 5 yr), was included as a covariate in the analysis to estimate the extent of degradation of each analyte during storage.

cC-GFR
Serum cystatin C concentration (Dade Behring Diagnostics) was assayed on a BN Prospec System nephelometer (Dade Behring, Inc., Newark, Delaware). The range of detection is 0.30 to 7.50 mg/L, and the reported reference range for young, healthy persons is 0.53 to 0.95 mg/L. In our laboratory, the intraindividual coefficient of variation for subjects with diabetes is 3.8 and 3.0% in samples from the lowest and highest quartiles of the cystatin C distribution, respectively (1).

The estimated GFR (cC-GFR ml/min/1.73 m²) is the reciprocal of cystatin C (mg/L) multiplied by 86.7 and reduced by subtracting 4.2. MacIsaac et al. recently developed this formula as a reliable estimate of GFR in patients with diabetes. Our method for measuring cystatin-C was similar with respect to assay, equipment, and coefficient of variation as that reported by MacIsaac et al. (15).

Serum Markers of TNF and Fas-Mediated Pathways
All markers were measured by immunoassay. Samples were thawed, vortexed, and centrifuged, and measurements were performed in the supernatant. We measured sTNFR1, sTNFR2, and IL6 by ELISA (DRT100, DRT200, and high-sensitive immunoassay HS600B, respectively; R&D, Minneapolis, Minnesota) according to the manufacturer's protocol. We measured IL6 in only a subset of the study group (156 individuals). We measured the serum concentrations of the other protein markers in a multiplex assay run on the Luminex platform. This is a multiplex particle-enhanced, sandwich type, liquid-phase immunoassay with laser-based detection system based on flow cytometry. We used adipokine-panel B (HADK2-61K-B; Linco-Milipore) to measure TNF; human sepsis-apoptosis panel (HSEP-63K; Linco-Milipore) to measure sFas, sFasL, sICAM-1, and sVCAM-1; and Beadlyte human multi-cytokine detection (48-011; Upstate-Milipore) with protocol B to measure IL8, IP-10, MCP-1. Protocols provided by vendors were followed. Briefly, the method included use of 96-well filter plates (Milipore), the capture antibodies specific for each analyte bound covalently to fluorescently labeled microspheres, biotinylated detection antibodies, and streptavidin-phycoerythrin. Detection incorporates two lasers and a high-tech fluidics system (Luminex 100S, Austin, Texas). Values of median fluorescence intensity were fitted to a five-parameter logistic standard curve (20).

Assay sensitivities were: TNF, 0.14 pg/ml; sTNFR1 and sTNFR2, 0.77 pg/ml; sFas, 7 pg/ml; sFasL, 6 pg/ml; sICAM-1, 30 pg/ml; sVCAM-1, 33 pg/ml; IL8, 0.7 pg/ml; IP-10, 1.2 pg/ml; MCP-1, 1.9 pg/ml; and IL6, 0.04 pg/ml. If required, samples were diluted (sTNFR1, sTNFR2, sFAS, sFASL, sICAM-1, and sVCAM-1). The number of freeze-thaw cycles was one for all measurements of TNF, IL8, IP-10, MCP-1, and for most measurements of the other analytes. The number did not exceed two for any measurement.

Two internal serum controls were prepared in the same manner as study samples and were stored in a large number of aliquots at –80°C. Aliquots of the two controls were included in each assay (21) for estimating the interassay coefficient of variation (CV). For most assays, interassay CV was between 8.5 and 15.8% (15.8% TNF, 13.0% sTNFR1, 12.7% sTNFR2, 8.5% sFas, 13.5% sFasL, 8.1% sVCAM-1, and 14.7% IP-10). It was higher for the remaining three (25.2% sICAM-1, 33.3% IL8, and 28.4% MCP-1). Immunoassay for TNF, sFas, and sFasL detects the free form of the protein, whereas ELISA for sTNFR1 and sTNFR2 detects the total amount of protein, free and bound with their ligand TNF, (information provided by manufacturer).

Statistical Analyses
Analyses were done in SAS (SAS Institute, Cary, North Carolina, version 9.1.3). For continuous variables and frequencies, t-tests and ² tests with alpha = 0.05 were used, respectively. Analyses in Tables 2 and 3 and Figure 1 were ANOVA for unbalanced design. Linear regression with cC-GFR as the dependent variable was used for multivariate analysis. AER and serum concentrations of the markers were transformed to their logarithms for analysis. Missing data for serum markers never decreased the study sample by more than 5% in any model, so no remedial action was taken.

View larger version (27K): [in this window] [in a new window] [as a PowerPoint slide]   Figure 1. Mean serum cystatin C GFR (cC-GFR) in the study population of individuals with type 1 diabetes according to albuminuria status (NA, normoalbuminuria; MA, microalbuminuria) and tertile (T1, T2, T3) of an inflammatory marker: (A) sTNFR1; (B) sTNFR2; (C) TNF; (D) sFas; (E) sICAM-1; and (F) IP-10. P value for trend across the tertiles in NA and MA, respectively.

	Results

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Markers of Inflammation or Apoptosis and Impaired Renal Function—Univariate Analyses
Serum concentrations of markers of inflammation or apoptosis were examined in the same manner as the characteristics shown in Table 2. Four markers (sTNFR1, sTNRF2, sFas, and sICAM-1) were significantly associated both with AER and with cC-GFR (Table 3). TNF and IP-10 were significantly associated only with the cC-GFR group and two (IL8 and C-reactive protein) were significantly associated only with the AER group.

For the six markers significantly associated with cC-GFR in Table 3, the patterns of association are illustrated in Figures 1A through 1F. Separately for the NA and MA groups, patients were grouped according to the tertiles of the distribution of each marker, and the mean cC-GFR for each subgroup was depicted as a vertical bar. In both AER groups, the decrease in cC-GFR with increasing marker concentration was steepest for sTNFR1 and sTNFR2. The pattern was similar for TNF, but the differences among subgroups were smaller. For all three markers, the decrease appeared steeper in the MA group than in the NA group. For the remaining three markers (sICAM-1, IP-10 and sFas), a pattern of differences among subgroups was less obvious

We studied these markers further by examining their correlations with each other, and with the two nephropathy measures, cC-GFR and AER (Table 4). The negative correlations between the six markers and cC-GFR recapitulate the negative associations shown in Table 3 and Figure 1. All pairs of markers are significantly correlated, but the coefficients are generally modest. Only the correlation of the two receptors (sTNFR1 and sTNFR2) with cC-GFR and with each other exceeded 0.50. Note the poor (although significant) correlations between TNF and its receptors (r = 0.11 for TNF/sTNFR1 and r = 0.20 for TNF/sTNFR2).

	Discussion

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Of the six markers, only the concentrations of sTNFR1, sTNFR2, and sFas contributed independently to cC-GFR. The effect of TNF receptors on cC-GFR was much more pronounced than the effects of clinical covariates such as age and AER (Table 5). Furthermore, serum concentrations of sTNFR1 and sTNFR2 are highly correlated (Spearman r = 0.81) and show roughly the same associations with cC-GFR. Therefore, further studies are required to determine whether measurement of both rather than just one is worthwhile. Our study provides evidence for the first time that markers of TNF- and Fas-mediated pathways are strongly associated with variation in cC-GFR in patients with T1DM and early diabetic nephropathy. This association is independent of the association of these markers with AER. Our findings support the hypothesis that inflammation and apoptosis are involved in early renal function decline in T1DM.

Other cross-sectional studies in T1DM reported that serum concentrations of TNF-related markers were elevated in comparison with healthy subjects and that the higher concentrations of these markers were associated with elevated urinary albumin excretion (14,22). Cross-sectional association between serum concentrations of sTNFR and variation in GFR has been shown in type 2 diabetes mellitus (23), as well as in nondiabetic individuals (24,25). In the prospective CARE study, high serum concentrations of sTNFR2 were found to be associated with faster progression of renal function loss (26); however, all subjects in that study had chronic kidney disease (GFR < 60ml/min/1.73m²) at baseline.

Whatever mechanisms could underlie a causal relationship between renal function decline and elevated serum concentrations of sTNFR1 or TNFR2 (and whether those mechanisms include an activated TNF pathway) remain to be discovered. Soluble receptors bind TNF and may serve as a slow-release reservoir of TNF in a diabetic (and possibly low-grade inflammatory) state (27). There is also some experimental evidence for activation of TNF-pathway in diabetes (3,28). Possible factors that could influence serum concentrations of TNF receptors include their upstream regulators in serum, such as TNF or IL1, and intramembrane activity of ADAM17 (TNF receptor sheddase) (29). Concentrations of interleukin 1 below our detection limits prevented us from measuring it reliably (data not shown), and measurement of ADAM17 was not possible with the methods we used in our study.

How elevated concentrations of soluble TNF receptors may lead to renal injury is not known. If they represent an activated TNF-pathway, several mechanisms may be involved. The TNF-pathway has a broad range of inflammatory and apoptotic properties. Dysregulation of these processes may contribute to injury of the diabetic kidney. In addition, the TNF-pathway directly increases glomerular vasoconstriction and albumin permeability. Exposure of the kidney to TNF increases mRNA expression of TNF receptors in renal tubulointerstitium and triggers cell death. Also, an apoptotic response follows exposure of human kidney cells to sTNFR as well. This effect is more pronounced after exposure to sTNFR1 than to sTNFR2 (3,30,31). Therefore, our findings may support a hypothesis that elevated serum concentrations of soluble TNF receptors, by themselves or as markers of activation of TNF pathway, contribute to early renal function decline.

One may argue that the association of TNF receptors and cC-GFR simply reflects impaired renal handling of these proteins. Indeed, these receptors are cleared mainly by the kidneys as shown by tracer studies of radiolabeled sTNFR2 in animals (32). Also, serum concentrations of soluble TNF receptors increase in advanced renal failure, as demonstrated in binephrectomized mice (32) and in human studies (33). However, most patients in our study had normal renal function, and even the renal function loss resulting from uninephrectomy does not raise serum sTNF receptor concentrations in animals (32). Moreover, serum concentrations of sFasL, which has a molecular mass similar to soluble TNF receptors, is not associated with cC-GFR, whereas the receptors are strongly associated with variation in cC-GFR. On the basis of those data, potentially decreased clearance of those molecules has to be mentioned here, but it does not stand for the most likely explanation of our findings.

Adhesion molecules and chemokines are potential downstream effectors of the TNF–sTNFRs inflammatory pathway (6). Expression of IL8, MCP-1, and IP-10 mRNA is induced in TNF-activated peripheral blood mononuclear cells taken from individuals with diabetes, but not from healthy ones (7). Expression and serum concentrations of chemokines and adhesion molecules, VCAM-1 and ICAM-1, increase as diabetic nephropathy develops (7,34). In our univariate analysis, serum concentrations of IP-10 and sICAM-1 were associated with variation in cC-GFR and they correlated with their potential upstream regulators. Nevertheless, the observed effects were weak, and disappeared in multivariate analyses, as one would expect if their effect were not independent of the TNF receptors or sFas.

Analysis of the Fas-mediated pathway revealed an independent effect of the serum concentration of sFas on variation in cC-GFR and a lack of an effect of the serum concentration of sFasL. A similar pattern of disparate effects of sFas and sFasL was previously demonstrated in individuals with advanced kidney disease (11). Also, in a few individuals with T1DM and without proteinuria, sFas was reported to correlate with both ACR and GFR (35).

The mechanism of action of soluble Fas receptor has not been well known but may be similar to that of TNF receptors in that it leads to an enhanced Fas-mediated response in the kidney. The Fas-related system is involved mainly in regulation of apoptosis (10), whereas the TNF-system regulates apoptotic and inflammatory responses. Consistent with this is the tubulointerstitial apoptosis seen in strepotozocin-induced diabetic rats (8) and in human diabetic kidneys (9). Some evidence also suggests that TNF may induce Fas-mediated apoptosis (36,37). In our study serum concentrations of TNF and sFas were markedly correlated.

The main limitation of our study is its cross-sectional study design; therefore inferences about the causality of the associations remain tentative. Furthermore, high interassay CV of some of the measured markers would have weakened or obscured true associations with cC-GFR. Furthermore, the assay for TNF only measures the free form of TNF. In low-grade chronic inflammation (which we expect to be the case in this condition), most circulating TNF is bound to its receptors and undetected by the assay used. This fact may account for the noticeably poor correlations between TNF and its receptors as well as its association with cC-GFR being weaker than that of its receptors.

In conclusion, this study provides the first clinical evidence that markers of the TNF- and Fas-mediated pathways are strongly associated with GFR in patients with T1DM and NA or MA. sTNFR1, sTNFR2, and sFas are the markers most strongly representing these associations. These findings support the hypothesis that inflammation and apoptosis are involved in renal function decline in patients with T1DM and early diabetic nephropathy.

	Disclosures

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None.

	Acknowledgments

 
This study was supported by grant DK-41526 from the National Institutes of Health.

M.A. Niewczas was supported by American Diabetes Association mentor-based fellowship # 7-03-MN-28. The authors thank Harry Spaulding for his assistance in the preparation of this manuscript.

	Footnotes

 
Published online ahead of print. Publication date available at www.cjasn.org.

Received June 18, 2008. Accepted September 8, 2008.

	References

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1. Perkins BA, Ficociello LH, Ostrander BE, Silva KH, Weinberg J, Warram JH, Krolewski AS: Microalbuminuria and the risk for early progressive renal function decline in type 1 diabetes. J Am Soc Nephrol18 :1353 –1361,2007[Abstract/Free Full Text]
2. Caramori ML, Fioretto P, Mauer M: Low glomerular filtration rate in normoalbuminuric type 1 diabetic patients: An indicator of more advanced glomerular lesions. Diabetes52 :1036 –1040,2003[Abstract/Free Full Text]
3. Navarro JF, Mora-Fernandez C: The role of TNF-alpha in diabetic nephropathy: Pathogenic and therapeutic implications. Cytokine Growth Factor Rev17 :441 –450,2006[CrossRef][Medline]
4. Galkina E, Ley K: Leukocyte recruitment and vascular injury in diabetic nephropathy. J Am Soc Nephrol17 :368 –377,2006[Abstract/Free Full Text]
5. Macewan DJ: TNF receptor subtype signaling: Differences and cellular consequences. Cell Signal14 :477 –492,2002[CrossRef][Medline]
6. Segerer S, Nelson PJ, Schlondorff D: Chemokines, chemokine receptors, and renal disease: From basic science to pathophysiologic and therapeutic studies. J Am Soc Nephrol11 :152 –176,2000[Abstract/Free Full Text]
7. Wong CK, Ho AW, Tong PC, Yeung CY, Kong AP, Lun SW, Chan JC, Lam CW: Aberrant activation profile of cytokines and mitogen-activated protein kinases in type 2 diabetic patients with nephropathy. Clin Exp Immunol149 :123 –131,2007[Medline]
8. Kumar D, Zimpelmann J, Robertson S, Burns KD: Tubular and interstitial cell apoptosis in the streptozotocin-diabetic rat kidney. Nephron Exp Nephrol96 :e77 –e88,2004[CrossRef][Medline]
9. Kumar D, Robertson S, Burns KD: Evidence of apoptosis in human diabetic kidney. Mol Cell Biochem259 :67 –70,2004[CrossRef][Medline]
10. Schelling JR, Nkemere N, Kopp JB, Cleveland RP: Fas-dependent fratricidal apoptosis is a mechanism of tubular epithelial cell deletion in chronic renal failure. Lab Invest78 :813 –824,1998[Medline]
11. Perianayagam MC, Murray SL, Balakrishnan VS, Guo D, King AJ, Pereira BJ, Jaber BL: Serum soluble Fas (CD95) and Fas ligand profiles in chronic kidney failure. J Lab Clin Med136 :320 –327,2000[CrossRef][Medline]
12. Baba K, Minatoguchi S, Sano H, Kagawa T, Murata I, Takemura G, Hirano T, Ohashi H, Takemura M, Fujiwara T, Fujiwara H: Involvement of apoptosis in patients with diabetic nephropathy: A study on plasma soluble Fas levels and pathological findings. Nephrology (Carlton)9 :94 –99,2004[CrossRef][Medline]
13. Ortiz A, Lorz C, Egido J: The Fas ligand/Fas system in renal injury. Nephrol Dial Transplant14 :1831 –1834,1999[Free Full Text]
14. Zoppini G, Faccini G, Muggeo M, Zenari L, Falezza G, Targher G: Elevated plasma levels of soluble receptors of TNF-alpha and their association with smoking and microvascular complications in young adults with type 1 diabetes. J Clin Endocrinol Metab86 :3805 –3808,2001[Abstract/Free Full Text]
15. Macisaac RJ, Tsalamandris C, Thomas MC, Premaratne E, Panagiotopoulos S, Smith TJ, Poon A, Jenkins MA, Ratnaike SI, Power DA, Jerums G: The accuracy of cystatin C and commonly used creatinine-based methods for detecting moderate and mild chronic kidney disease in diabetes. Diabet Med24 :443 –448,2007[CrossRef][Medline]
16. Perkins BA, Nelson RG, Ostrander BE, Blouch KL, Krolewski AS, Myers BD, Warram JH: Detection of renal function decline in patients with diabetes and normal or elevated GFR by serial measurements of serum cystatin C concentration: Results of a 4-year follow-up study. J Am Soc Nephrol16 :1404 –1412,2005[Abstract/Free Full Text]
17. Rosolowsky ET, Ficociello LH, Maselli NJ, Niewczas MA, Binns AL, Roshan B, Warram JH, Krolewski AS: High-normal serum uric acid is associated with impaired glomerular filtration rate in nonproteinuric patients with type 1 diabetes. Clin J Am Soc Nephrol2008
18. Ficociello LH, Perkins BA, Silva KH, Finkelstein DM, Ignatowska-Switalska H, Gaciong Z, Cupples LA, Aschengrau A, Warram JH, Krolewski AS: Determinants of progression from microalbuminuria to proteinuria in patients who have type 1 diabetes and are treated with angiotensin-converting enzyme inhibitors. Clin J Am Soc Nephrol2 :461 –469,2007[Abstract/Free Full Text]
19. Krolewski AS, Laffel LM, Krolewski M, Quinn M, Warram JH: Glycosylated hemoglobin and the risk of microalbuminuria in patients with insulin-dependent diabetes mellitus. N Engl J Med332 :1251 –1255,1995[Abstract/Free Full Text]
20. Gottschalk PG, Dunn JR: The five-parameter logistic: A characterization and comparison with the four-parameter logistic. Anal Biochem343 :54 –65,2005[Medline]
21. Aziz N, Nishanian P, Fahey JL: Levels of cytokines and immune activation markers in plasma in human immunodeficiency virus infection: Quality control procedures. Clin Diagn Lab Immunol5 :755 –761,1998[Medline]
22. Schram MT, Chaturvedi N, Schalkwijk CG, Fuller JH, Stehouwer CD: Markers of inflammation are cross-sectionally associated with microvascular complications and cardiovascular disease in type 1 diabetes—the EURODIAB Prospective Complications Study. Diabetologia48 :370 –378,2005[CrossRef][Medline]
23. Lin J, Hu FB, Rimm EB, Rifai N, Curhan GC: The association of serum lipids and inflammatory biomarkers with renal function in men with type II diabetes mellitus. Kidney Int69 :336 –342,2006[CrossRef][Medline]
24. Keller CR, Odden MC, Fried LF, Newman AB, Angleman S, Green CA, Cummings SR, Harris TB, Shlipak MG: Kidney function and markers of inflammation in elderly persons without chronic kidney disease: The health, aging, and body composition study. Kidney Int71 :239 –244,2007[CrossRef][Medline]
25. Knight EL, Rimm EB, Pai JK, Rexrode KM, Cannuscio CC, Manson JE, Stampfer MJ, Curhan GC: Kidney dysfunction, inflammation, and coronary events: A prospective study. J Am Soc Nephrol15 :1897 –1903,2004[Abstract/Free Full Text]
26. Tonelli M, Sacks F, Pfeffer M, Jhangri GS, Curhan G: Biomarkers of inflammation and progression of chronic kidney disease. Kidney Int68 :237 –245,2005[CrossRef][Medline]
27. Aderka D, Sorkine P, Abu-Abid S, Lev D, Setton A, Cope AP, Wallach D, Klausner J: Shedding kinetics of soluble tumor necrosis factor (TNF) receptors after systemic TNF leaking during isolated limb perfusion. Relevance to the pathophysiology of septic shock. J Clin Invest101 :650 –659,1998[Medline]
28. Navarro JF, Mora C: Role of inflammation in diabetic complications. Nephrol Dial Transplant20 :2601 –2604,2005[Free Full Text]
29. Bell JH, Herrera AH, Li Y, Walcheck B: Role of ADAM17 in the ectodomain shedding of TNF-alpha and its receptors by neutrophils and macrophages. J Leukoc Biol82 :173 –176,2007[Abstract/Free Full Text]
30. Navarro JF, Mora C, Gomez M, Muros M, Lopez-Aguilar C, Garcia J: Influence of renal involvement on peripheral blood mononuclear cell expression behavior of tumor necrosis factor-alpha and interleukin-6 in type 2 diabetic patients. Nephrol Dial Transplant23 :919 –926,2008[Abstract/Free Full Text]
31. Al Lamki RS, Wang J, Vandenabeele P, Bradley JA, Thiru S, Luo D, Min W, Pober JS, Bradley JR: TNFR1- and TNFR2-mediated signaling pathways in human kidney are cell type-specific and differentially contribute to renal injury. FASEB J19 :1637 –1645,2005[Abstract/Free Full Text]
32. Bemelmans MH, Gouma DJ, Buurman WA: Tissue distribution and clearance of soluble murine TNF receptors in mice. Cytokine6 :608 –615,1994[CrossRef][Medline]
33. Brockhaus M, Bar-Khayim Y, Gurwicz S, Frensdorff A, Haran N: Plasma tumor necrosis factor soluble receptors in chronic renal failure. Kidney Int42 :663 –667,1992[Medline]
34. Nelson CL, Karschimkus CS, Dragicevic G, Packham DK, Wilson AM, O'Neal D, Becker GJ, Best JD, Jenkins AJ: Systemic and vascular inflammation is elevated in early IgA and type 1 diabetic nephropathies and relates to vascular disease risk factors and renal function. Nephrol Dial Transplant20 :2420 –2426,2005[Abstract/Free Full Text]
35. Protopsaltis J, Kokkoris S, Nikolopoulos G, Spyropoulou P, Katsaros T, Salvanos L, Brestas P, Korantzopoulos P, Melidonis A: Correlation between increased serum sFas levels and microalbuminuria in type 1 diabetic patients. Med Princ Pract16 :222 –225,2007[CrossRef][Medline]
36. Elzey BD, Griffith TS, Herndon JM, Barreiro R, Tschopp J, Ferguson TA: Regulation of Fas ligand-induced apoptosis by TNF. J Immunol167 :3049 –3056,2001[Abstract/Free Full Text]
37. Boldin MP, Mett IL, Varfolomeev EE, Chumakov I, Shemer-Avni Y, Camonis JH, Wallach D: Self-association of the "death domains" of the p55 tumor necrosis factor (TNF) receptor and Fas/APO1 prompts signaling for TNF and Fas/APO1 effects. J Biol Chem270 :387 –391,1995[Abstract/Free Full Text]

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