Antje Kirchhoff scite author profile

A 14-year-old boy presented with a 10-year history of the "sicca" form of seronegative juvenile idiopathic polyarthritis. Severely limited range of motion, pain, and capsular swelling in both small and large weight-bearing joints left him wheelchair-bound. Erythrocyte sedimentation rate and C-reactive protein were normal. Two-phase bone scan revealed tracer uptake of almost every joint at both early and late time points, indicating pathologic exudation and enhanced bone metabolism consistent with severe arthritis. However, radiographic studies revealed no erosive arthropathy but severe osteopenia, dysplastic bone changes, mega os trigonum, and platyspondylia. A magnetic resonance imaging (MRI) scan of the hips showed no signs of synovitis, pannus, or effusion but cartilage irregularities and subchondral cysts. These findings strongly suggested the diagnosis of progressive pseudorheumatoid dysplasia of childhood, an autosomal-recessive disorder of cartilage homeostasis. The patient carries a novel homozygous two-nucleotide deletion in exon 4 of the WISP3 gene. This genetic disorder is an important differential diagnosis of sicca polyarthritis.

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Chloroacetaldehyde- and acrolein-induced death of human proximal tubule cells

Schwerdt

Gordjani

Benesic

et al. 2005

Pediatr Nephrol

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Ifosfamide (ifo) is a commonly used drug in chemotherapy. It is metabolized to acrolein (acro) and chloroacetaldehyde (CAA), which are thought to be responsible for renal side effects. We studied the effects of ifo and cyclophosphamide (cyclo) as well as their metabolites, acro and CAA, on cellular protein content, necrosis, apoptosis and cytosolic calcium concentration using a human proximal tubule cell line. The protein content decreased during acro or CAA administration (15 to 300 micromol/l), but not during ifo or cyclo exposure over a time period of up to 72 h. Mild apoptosis was induced only by high acro (150, 300 micromol/l) and low CAA concentrations (15, 75 micromol/l) and only in a narrow time window (24 h). Necrosis was increased after exposure to acro or CAA at all concentrations. CAA was more potent than acro. Ifo and cyclo did not induce necrosis or apoptosis. Glutathione abolished CAA-induced cell death. Cytosolic calcium concentrations increased after acro or CAA administration and showed an oscillating pattern. Cytosolic Ca(2+) chelation did not prevent necrosis. We conclude that neither ifo nor cyclo induce cell damage, but that their metabolites acro and CAA induce cell death. This cell death occurs mainly by necrosis and not by apoptosis.

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Chloroacetaldehyde as a Sulfhydryl Reagent: The Role of Critical Thiol Groups in Ifosfamide Nephropathy

Benesic

Schwerdt

Freudinger

et al. 2006

Kidney Blood Press Res

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Chloroacetaldehyde (CAA) is a metabolite of the alkylating agent ifosfamide (IFO) and putatively responsible for renal damage following anti-tumor therapy with IFO. Depletion of sulfhydryl (SH) groups has been reported from cell culture, animal and clinical studies. In this work the effect of CAA on human proximal tubule cells in primary culture (hRPTEC) was investigated. Toxicity of CAA was determined by protein content, cell number, LDH release, trypan blue exclusion assay and caspase-3 activity. Free thiols were measured by the method of Ellman. CAA reduced hRPTEC cell number and protein, induced a loss in free intracellular thiols and an increase in necrosis markers. CAA but not acrolein inhibited the cysteine proteases caspase-3, caspase-8 and cathepsin B. Caspase activation by cisplatin was inhibited by CAA. In cells stained with fluorescent dyes targeting lysosomes, CAA induced an increase in lysosomal size and lysosomal leakage. The effects of CAA on cysteine protease activities and thiols could be reproduced in cell lysate. Acidification, which slowed the reaction of CAA with thiol donors, could also attenuate effects of CAA on necrosis markers, thiol depletion and cysteine protease inhibition in living cells. Thus, CAA directly reacts with cellular protein and non-protein thiols, mediating its toxicity on hRPTEC. This effect can be reduced by acidification. Therefore, urinary acidification could be an option to prevent IFO nephropathy in patients.

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Mesna or cysteine prevents chloroacetaldehyde-induced cell death of human proximal tubule cells

et al. 2007

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Chloroacetaldehyde (CAA) is formed in the body from the chemotherapeutically used drug ifosfamide (IFO). CAA leads to cell death in proximal tubule cells mainly through the mechanism of necrosis rather than apoptosis. During chemotherapy, 2-mercaptosulfonic acid (mesna) is used with IFO to protect the urothel from cell damage. Little is known of the effect of mesna on renal proximal tubule cells, the primary site of damage after IFO treatment. Mesna contains a sulfhydryl (SH) group. To clarify whether SH-group-containing molecules can prevent CAA-induced cell death, we studied the effect of mesna and cysteine on necrosis, apoptosis, and protein content in a human proximal tubule-derived cell line (IHKE cells) treated with CAA. Both substances prevented CAA-induced necrotic cell death and protein loss and restored CAA-inhibited caspase-3 activity. CAA also prevented cisplatin-induced apoptosis. This inhibition was reversible in the presence of glutathione (GSH). We conclude that SH-containing molecules can protect proximal tubule cells from cell death because they interact with CAA before CAA can disturb other important cellular SH groups. A sufficient supply of intra- and extracellular SH groups during IFO chemotherapy may therefore have the ability to protect renal tubule cells from cell death.

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Antje Kirchhoff

Clinical, radiographic, and genetic diagnosis of progressive pseudorheumatoid dysplasia in a patient with severe polyarthropathy

Chloroacetaldehyde- and acrolein-induced death of human proximal tubule cells

Chloroacetaldehyde as a Sulfhydryl Reagent: The Role of Critical Thiol Groups in Ifosfamide Nephropathy

Mesna or cysteine prevents chloroacetaldehyde-induced cell death of human proximal tubule cells

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