Clcn7F318L/+ as a new mouse model of Albers-Schönberg disease.

Dominant negative mutations in CLCN7, which encodes a homodimeric chloride channel needed for matrix acidification by osteoclasts, cause Albers-Schönberg disease (also known as autosomal dominant osteopetrosis type 2). More than 25 different CLCN7 mutations have been identified in patients affected with Albers-Schönberg disease, but only one mutation (Clcn7G213R) has been introduced in mice to create an animal model of this disease. Here we describe a mouse with a different osteopetrosis-causing mutation (Clcn7F318L). Compared to Clcn7+/+ mice, 12-week-old Clcn7F318L/+ mice have significantly increased trabecular bone volume, consistent with Clcn7F318L acting as a dominant negative mutation. Clcn7F318L/F318L and Clcn7F318L/G213R mice die by 1month of age and resemble Clcn7 knockout mice, which indicate that p.F318L mutant protein is non-functional and p.F318L and p.G213R mutant proteins do not complement one another. Since it has been reported that treatment with interferon gamma (IFN-G) improves bone properties in Clcn7G213R/+ mice, we treated Clcn7F318L/+ mice with IFN-G and observed a decrease in osteoclast number and mineral apposition rate, but no overall improvement in bone properties. Our results suggest that the benefits of IFN-G therapy in patients with Albers-Schönberg disease may be mutation-specific.

Vancomycin pharmacokinetics, renal handling, and nonrenal clearances in normal human subjects.

The renal handling of vancomycin is unknown. Previously reported studies have not achieved steady-state conditions with constant vancomycin concentrations. We measured systemic vancomycin clearance simultaneously with the renal clearances of vancomycin, creatinine, inulin, and para-aminohippurate in nine healthy subjects at steady-state serum vancomycin concentrations of 7 and 14 mg/L. For all steady-state observations the renal clearance of vancomycin was 89 +/- 11 ml/min (mean +/- SE), the clearance of inulin 105 +/- 9 ml/min, the clearance of creatinine 117 +/- 9 ml/min, and the clearance of para-aminohippuric acid 496 +/- 41 ml/min. The systemic clearance of vancomycin was 131 +/- 7 ml/min. The clearances of creatinine, inulin, and para-aminohippuric acid and the renal clearance of vancomycin were not statistically different at both steady-state vancomycin concentrations. The ratio of the renal clearance of vancomycin to the clearance of inulin was 0.89 +/- 0.06 and to creatinine clearance 0.79 +/- 0.05. Both ratios were independent of vancomycin concentration, urine flow rate, and filtration fraction. The systemic clearance of vancomycin was 10% greater at serum vancomycin concentrations of 14 mg/L than at 7 mg/L (p less than 0.05) because of an increase in the nonrenal clearance. Therefore in healthy subjects, 30% of the systemic vancomycin clearance is by nonrenal mechanisms and this nonrenal clearance is concentration dependent. Assuming protein binding to be between 10% and 20%, renal vancomycin excretion is predominantly by glomerular filtration. Small amounts of tubular vancomycin transport cannot be excluded by these techniques.

Phenazopyridine-induced hemolytic anemia.

An elderly man was seen with hemolytic anemia due to the urinary tract analgesic, phenazopyridine hydrochloride. The mechanisms underlying this toxic reaction are presented. Cautious use of this drug in elderly patients and in those with renal insufficiency is emphasized.