EPO synthesis induced by HIF-PHD inhibition is dependent on myofibroblast transdifferentiation and colocalizes with non-injured nephron segments in murine kidney fibrosis.

AIM: Erythropoietin (EPO) is regulated by hypoxia-inducible factor (HIF)-2. In the kidney, it is produced by cortico-medullary perivascular interstitial cells, which transdifferentiate into collagen-producing myofibroblasts in response to injury. Inhibitors of prolyl hydroxylase domain (PHD) dioxygenases (HIF-PHIs) activate HIF-2 and stimulate kidney and liver EPO synthesis in patients with anemia of chronic kidney disease (CKD). We examined whether HIF-PHIs can reactivate EPO synthesis in interstitial cells that have undergone myofibroblast transdifferentiation in established kidney fibrosis. METHODS: We investigated Epo transcription in myofibroblasts and characterized the histological distribution of kidney Epo transcripts by RNA in situ hybridization combined with immunofluorescence in mice with adenine nephropathy (AN) treated with HIF-PHI molidustat.  Lectin absorption chromatography was used to assess liver-derived EPO.  In addition, we examined kidney Epo transcription in Phd2 knockout mice with obstructive nephropathy. RESULTS: In AN, molidustat-induced Epo transcripts were not found in areas of fibrosis and did not colocalize with interstitial cells that expressed α-smooth muscle actin, a marker of myofibroblast transdifferentiation. Epo transcription was associated with megalin-expressing, kidney injury molecule 1-negative nephron segments and contingent on residual renal function. Liver-derived EPO did not contribute to serum EPO in molidustat-treated mice. Epo transcription was not associated with myofibroblasts in Phd2 knockout mice with obstructive nephropathy. CONCLUSIONS: Our studies suggest that HIF-PHIs do not reactivate Epo transcription in interstitial myofibroblasts and that their efficacy in inducing kidney EPO in CKD is dependent on the degree of myofibroblast formation, the preservation of renal parenchyma and the level of residual renal function.

Rapid detection of erythropoiesis-stimulating agents in urine and serum.

A rapid and easy-to-use test kit, EPO WGA MAIIA, which can be used for distinguishing various endogenous human erythropoietins (hEPOs) and several recombinant hEPO and EPO analogues, has been evaluated. The test is based on chromatographic separation of the glycosylated isoforms of EPO using wheat germ agglutinin (WGA) and a sensitive immunoassay using anti-EPO carbon black nanostrings and image scanning for quantification. All of the reactions take place along the porous layer of a lateral flow microcolumn containing WGA and anti-EPO zones. The presence of molecules resembling hEPOs, such as Mircera, was detected by the aberrant affinity interaction with the antibody zone on the strip. It was possible to distinguish nine recombinant hEPOs expressed in hamster and human cell lines, as well as Aranesp and Mircera, from endogenous urine hEPO. The required amount of EPO in the samples, a few picograms, is very low compared with other methods for EPO isoform identification. This EPO isoform determination method opens the possibility to monitor recombinant EPO therapy for clinical research and seems to be a valuable candidate to the arsenal of EPO doping control tests.

Rapid affinity purification of erythropoietin from biological samples using disposable monoliths.

Identification of post-translational modifications of proteins in biological samples often requires access to preanalytical purification and concentration methods. In the purification step high or low molecular weight substances can be removed by size exclusion filters, and high abundant proteins can be removed, or low abundant proteins can be enriched, by specific capturing tools. In this paper is described the experience and results obtained with a recently emerged and easy-to-use affinity purification kit for enrichment of the low amounts of EPO found in urine and plasma specimens. The kit can be used as a pre-step in the EPO doping control procedure, as an alternative to the commonly used ultrafiltration, for detecting aberrantly glycosylated isoforms. The commercially available affinity purification kit contains small disposable anti-EPO monolith columns (6 µL volume, Ø7 mm, length 0.15 mm) together with all required buffers. A 24-channel vacuum manifold was used for simultaneous processing of samples. The column concentrated EPO from 20 mL urine down to 55 µL eluate with a concentration factor of 240 times, while roughly 99.7% of non-relevant urine proteins were removed. The recoveries of Neorecormon (epoetin beta), and the EPO analogues Aranesp and Mircera applied to buffer were high, 76%, 67% and 57%, respectively. The recovery of endogenous EPO from human urine was 65%. High recoveries were also obtained when purifying human, mouse and equine EPO from serum, and human EPO from cerebrospinal fluid. Evaluation with the accredited EPO doping control method based on isoelectric focusing (IEF) showed that the affinity purification procedure did not change the isoform distribution for rhEPO, Aranesp, Mircera or endogenous EPO. The kit should be particularly useful for applications in which it is essential to avoid carry-over effects, a problem commonly encountered with conventional particle-based affinity columns. The encouraging results with EPO propose that similar affinity monoliths, with the appropriate antibodies, should constitute useful tools for general applications in sample preparation, not only for doping control of EPO and other hormones such as growth hormone and insulin but also for the study of post-translational modifications of other low abundance proteins in biological and clinical research, and for sample preparation prior to in vitro diagnostics.

Ultra-sensitive immunochromatographic assay for quantitative determination of erythropoietin.

An ultra-sensitive quantitative EPO (erythropoietin) lateral flow immunochromatographic test with a detection limit of 1.2 fM (10(-15) M), 0.035 ng EPO/L, which is 50-100 times more sensitive than a corresponding enzyme based immunoassay, is presented. In comparison with commercial lateral flow tests for other analytes, like cardiac troponins that also require high sensitivity, the detection limit achieved in the presented test is about three orders of magnitude lower. The thin zone for capture and concentration of the analyte, the carbon black nano-strings used as label and the use of a conventional image scanner for the quantitative determination are the key components that enable the high sensitivity obtained. The convective flow in the lateral flow monolith creates short diffusion distances between immobilised antibody, analyte and labelled antibody thus enhancing the binding efficiency. This rapid and sensitive EPO test procedure can be used both to process hundreds of samples in 1 h and be utilized as a 15-minute dipstick test for single determinations. The technique is demonstrated by measuring EPO in urine. EPO, like many of the other urine proteins, is often found in the urine precipitates and the specimens are therefore treated with a urine precipitate dissolvation buffer before analysis. It is shown that EPO in urine from normal individuals occurs in low concentration in a wide range between 1.7 and 51 ng/L. The concentration is however subjected to a wide variation during the day due to the EPO production variation and the urine concentration by the kidneys. It is also shown that the presented lateral flow device can be used as a miniaturized affinity column to distinguish an analyte (EPO) from its analogue (darbepoetin), directly by comparing the affinity profiles obtained after interaction with the immobilised antibody. The method for measuring the amount of EPO present in urine, the possibility to rapidly check the amount of EPO after a pre-treatment concentration step, and the potential to identify affinity differences between EPO and its analogues should make the presented method a valuable tool in the fight against EPO doping.