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Query: EC:3.2.1.31 (
beta-glucuronidase
)
7,680
document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)
Patients with end-stage renal disease are acidotic and often develop secondary hyperparathyroidism. Whether acidosis contributes to the bone disease observed in these patients is not clear. To determine whether acidosis and parathyroid hormone (PTH) have additive effects on net calcium efflux (JCa+) from bone and on bone cell function, we measured JCa+, osteoblastic collagen synthesis, and osteoclastic
beta-glucuronidase
release from neonatal mouse calvariae cultured in control (Ctl, pH approximately 7.4) or acidified (Met, pH approximately 7.1) medium with or without a submaximal concentration of PTH (10(-10) M) for 48 h. Compared with Ctl, from 24 to 48 h JCa+ was increased with Met and with PTH, and the combination of Met + PTH increased JCa+ further. Compared with Ctl, collagen synthesis was decreased with Met and with PTH and decreased further with Met + PTH. There was an inverse correlation between percent collagen synthesis and JCa+. Compared with Ctl,
beta-glucuronidase
release into the medium was increased with Met and with PTH and increased further with Met + PTH. There was a direct correlation between medium
beta-glucuronidase
activity and JCa+. Osteoclastic
beta-glucuronidase
activity correlated inversely with osteoblastic collagen synthesis. During cultures to 96 h, there continued to be greater JCa+ from calvariae incubated with Met + PTH than from those with either treatment alone. Thus acidosis and PTH independently stimulated JCa+ from bone, inhibited osteoblastic collagen synthesis, and stimulated osteoclastic
beta-glucuronidase
secretion, whereas the combination had a greater effect on each of these parameters than either treatment alone. These findings indicate that acidosis and PTH can have an additive effect on bone cell function and suggest that uremic
osteodystrophy
may result from a combination of a low pH and an elevated PTH.
...
PMID:Additive effects of acidosis and parathyroid hormone on mouse osteoblastic and osteoclastic function. 857 64
Phosphate homeostasis is central to diverse physiologic processes including energy homeostasis, formation of lipid bilayers, and bone formation. Reduced phosphate levels due to excessive renal loss cause hypophosphatemic rickets, a disease characterized by prominent bone defects; conversely, hyperphosphatemia, a major complication of renal failure, is accompanied by parathyroid hyperplasia, hyperparathyroidism, and
osteodystrophy
. Here, we define a syndrome featuring both hypophosphatemic rickets and hyperparathyroidism due to parathyroid hyperplasia as well as other skeletal abnormalities. We show that this disease is due to a de novo translocation with a breakpoint adjacent to alpha-Klotho, which encodes a
beta-glucuronidase
, and is implicated in aging and regulation of FGF signaling. Plasma alpha-Klotho levels and
beta-glucuronidase
activity are markedly increased in the affected patient; unexpectedly, the circulating FGF23 level is also markedly elevated. These findings suggest that the elevated alpha-Klotho level mimics aspects of the normal response to hyperphosphatemia and implicate alpha-Klotho in the selective regulation of phosphate levels and in the regulation of parathyroid mass and function; they also have implications for the pathogenesis and treatment of renal osteodystrophy in patients with kidney failure.
...
PMID:A translocation causing increased alpha-klotho level results in hypophosphatemic rickets and hyperparathyroidism. 1830 35
