Hannes Steinkellner

Neurological effects of recombinant human erythropoietin in Friedreich's ataxia: a clinical pilot trial.

In a “proof‐of‐concept” study, we demonstrated that recombinant human erythropoietin (rhuEPO) increases frataxin levels in Friedreichs ataxia (FRDA) patients. We now report a 6‐month open‐label clinical pilot study of safety and efficacy of rhuEPO treatment in FRDA. Eight adult FRDA patients received 2.000 IU rhuEPO thrice a week subcutaneously. Clinical outcome measures included Ataxia Rating Scales. Frataxin levels and indicators for oxidative stress were assessed. Hematological parameters were monitored biweekly. Scores in Ataxia Rating Scales such as FARS (P = 0.0063) and SARA (P = 0.0045) improved significantly. Frataxin levels increased (P = 0.017) while indicators of oxidative stress such as urine 8‐OHdG (P = 0.012) and peroxide levels decreased (P = 0.028). Increases in hematocrit requiring phlebotomies occurred in 4 of 8 patients. In this explorative open‐label clinical pilot study, we found an evidence for clinical improvement together with a persistent increase of frataxin levels and a reduction of oxidative stress parameters in patients with FRDA receiving chronic treatment with rhuEPO. Safety monitoring with regular blood cell counts and parameters of iron metabolism is a potential limitation of this approach.

Carbamylated erythropoietin increases frataxin independent from the erythropoietin receptor.

Eur J Clin Invest 2010; 40 (6): 561–565

A high throughput electrochemiluminescence assay for the quantification of frataxin protein levels.

Friedreichs ataxia (FRDA) is an autosomal recessive neurodegenerative disease affecting 1 in 50,000 people and is caused by a GAA-trinucleotide expansion in the frataxin gene located on chromosome locus 9q13 which results in a markedly reduced expression of frataxin, a small mitochondrial protein. The exact function of frataxin is still unknown and currently there is no approved treatment available. In the near future there will be a high demand for measuring frataxin protein levels due to the development of therapeutic strategies for FRDA based on manipulating frataxin expression levels in vivo. In this paper we describe the development of an electrochemiluminescence assay (ECLIA) to measure frataxin protein levels in a 96-well plate format. The ECLIA for frataxin is able to measure human and mouse samples and is highly quantitative, accurate and reproducible, with low intra- and inter-assay error throughout a wide working range. The assay has an excellent precision and provides a new tool for the set up of high-throughput screening for basic research and for clinical studies with FRDA patients.

Correlation of frataxin content in blood and skeletal muscle endorses frataxin as a biomarker in Friedreich ataxia.

Friedreich ataxia is an autosomal recessive disorder caused by mutations in the frataxin gene, leading to reduced levels of the mitochondrial protein frataxin. Assays to quantitatively measure frataxin in peripheral blood have been established. To determine the validity of frataxin as a biomarker for clinical trials, we assessed frataxin in clinically affected tissue.

S-carbamoylation impairs the oxidant scavenging activity of cysteine: its possible impact on increased LDL modification in uraemia.

Carbamoylation is the non-enzymatic reaction of cyanate with amino-, hydroxy- or thiol groups. In vivo, amino group modification (N-carbamoylation) resulting in altered function of proteins/amino acids has been observed in patients suffering from uraemia due to urea-derived cyanate. Uraemia has been linked to impaired antioxidant defense. As thiol-compounds like cysteine, N-acetyl cysteine and GSH have oxidant scavenging properties one may speculate that thiol-group carbamoylation (S-carbamoylation) may impair their protective activity. Here we report on the effect of S-carbamoylation on the ABTS free radical and HOCl scavenging property of cysteine as well on its ability to protect LDL from atherogenic modification induced by AAPH generated peroxylradicals or HOCl. The results show that S-carbamoylation impaired the ABTS free radical and HOCl scavenging property of the thiol-compounds tested. The ability of the thiols to protect LDL from lipid oxidation and apolipoprotein modification was strongly diminished by S-carbamoylation. The data indicate that S-carbamoylation could impair the free radical and HOCl scavenging of thiol-amino acids reducing their protective property against LDL atherogenic modification by these oxidant species. As S-carbamoylation is most effective at pH 7 to 5 in vivo thiol-carbamoylation may especially occur at sites of acidic extracellular pH as in hypoxic/inflammatory macrophage rich areas like the atherosclerotic plaque where increased LDL oxidation has been found and may contribute to the higher oxidative stress in uraemia.

Detection of Survival Motor Neuron Protein in Buccal Cells Through Electrochemiluminescence-Based Assay

Spinal muscular atrophy (SMA) is a severe autosomal recessive disorder affecting one in every 10,000 live births. The disease is characterized by loss of alpha-motor neurons in the spinal cord that leads to progressive atrophy and weakness of limb and trunk muscles. This neuromuscular disorder results from deletions and/or mutations within the survival motor neuron 1 (SMN1) gene, leading to a pathologically decreased expression of functional full-length SMN protein. Here we report on the investigation to measure SMN protein levels through electrochemiluminescence immunoassay (ECLIA). This simple assay is a highly quantitative method able to measure SMN protein levels in human, mouse, and rat samples throughout a wide working range with low intra- and interassay error. The sensitivity for human SMN is 30 pg/mL and provides a new tool for the set up of high-throughput screening for basic research. Moreover, we describe a novel tool for a noninvasive assessment of SMN in buccal cells derived from healthy donors, SMA carriers, and SMA patients. The availability of a validated quantitative ECLIA should improve the investigation of novel compounds for the treatment of SMA.

In vitro study on the effects of iron sucrose, ferric gluconate and iron dextran on redox-active iron and oxidative stress.

Concerns exist that administration of intravenous (i.v.) iron preparations is associated with oxidative stress. Therefore iron sucrose (CAS 8047-67-4), ferric gluconate (CAS 34098-81-1) and iron dextran (CAS 9004-66-4) were assessed for redox-active iron by a dichlorofluorescein assay and for intracellular reactive oxygen species (ROS) generation and cytotoxicity in HepG2 cells. Examining each i.v. iron preparation at its maximum concentration achieved following clinically frequently used doses in a 70 kg individual in in vitro experiments, redox-active iron was highest with ferric gluconate, followed by iron dextran and iron sucrose. Interestingly, when the i.v. iron preparations were diluted in human serum instead of buffer, redox-active iron was highest with iron dextran, followed by iron sucrose, and practically disappeared with ferric gluconate. ROS production in HepG2 cells was increased by all i.v. iron preparations. However, in the neutral red cytotoxicity assay all i.v. iron preparations were non-toxic. In conclusion, ferric gluconate showed the highest increase in intracellular ROS-production in HepG2 cells and the highest amount of redox-active iron in buffer in the in vitro assays. In contrast to the other i.v. iron preparations, redox-active iron from ferric gluconate was rendered completely redox-inactive by serum, indicating that redox-active iron in the various preparations has different chemical properties.

Identification and molecular characterisation of a homozygous missense mutation in the ADAMTS10 gene in a patient with Weill–Marchesani syndrome

Weill–Marchesani syndrome is a rare disorder of the connective tissue. Functional variants in ADAMTS10 are associated with Weill–Marchesani syndrome-1. We identified a homozygous missense mutation, c.41T>A, of the ADAMTS10 gene in a 19-year-old female with typical symptoms of WMS1: proportionate short stature, brachydactyly, joint stiffness, and microspherophakia. The ADAMTS10 missense mutation was analysed in silico, with conflicting results as to its effects on protein function, but it was predicted to affect the leader sequence. Molecular characterisation in HEK293 Ebna cells revealed an intracellular mis-targeting of the ADAMTS10 protein with a reduced concentration of the polypeptide in the endoplasmic reticulum. A large reduction in glycosylation of the cytoplasmic fraction of the mutant ADAMTS10 protein versus the wild-type protein and a lack of secretion of the mutant protein are also evident in our results.In conclusion, we identified a novel missense mutation of the ADAMTS10 gene and confirmed the functional consequences suggested by the in silico analysis by conducting molecular studies.

Review: Friedreich Ataxia and Erythropoietin

In vitro and in vivo studies have provided evidence for neuroprotective properties of Erythropoietin in neurodegenerative disorders. Although the magnitude of effect is still controversial, very recent findings point to neuronal protection in the central nervous system by Erythropoietins. Erythropoietin is a powerful growth factor which enhances cellular size and ultimatively increases the number of mitochondria. Friedreich Ataxia (FA), an inherited neurodegenerative disorder is caused by a loss of function mutation in the first intron on chromosome 9. FA patients therefore suffer a marked reduction of Frataxin, a mitochondrial protein which is involved in mitochondrial iron homeostasis and/or assembly of iron-sulfur (FeS) proteins and heme synthesis. Mitochondrial dysfunction results in a deleterious energy deficit especially in tissues highly dependent on oxidative phosphorylation such as neurons, muscle cells or pancreatic insular cells. Beneficial effects of recombinant human Erythropoietin (rhuEPO) may derive from an increase in Frataxin levels through currently unknown post-transcriptional and/or post-translational mechanisms. Moreover, additional effects via BDNF and through mitochondrial iron chelation may complete the spectrum of rhuEPOs actions in FA and may be part of its beneficial treatment effects. However, there are clear limitations to chronic rhuEPO treatment. Apart from hematopoietic side effects, tumor growth may be enhanced by rhuEPO application. In this review we provide an overview of studies using rhuEPO in FA and discuss potential beneficial effects of Erythropoietin in FA.