Hypoparathyroidism is a disease of chronic hypocalcemia and hyperphosphatemia due to a deficiency of parathyroid hormone (PTH). PTH and analogs of the hormone are of interest as potential therapies. Accordingly, we examined the pharmacological properties of a long-acting PTH analog, [Ala1,3,12,18,22, Gln10,Arg11,Trp14,Lys26]-PTH(1–14)/PTHrP(15–36) (LA–PTH) in thyroparathyroidectomized (TPTX) rats, a model of HP, as well as in normal monkeys. In TPTX rats, a single intra-venous administration of LA-PTH at a dose of 0.9 nmol/kg increased serum calcium (sCa) and decreased serum phosphate (sPi) to near-normal levels for longer than 48 hours, while PTH(1–34) and PTH(1–84), each injected at a dose 80-fold higher than that used for LA-PTH, increased sCa and decreased sPi only modestly and transiently (< 6 hours). LA-PTH also exhibited enhanced and prolonged efficacy versus PTH(1–34) and PTH(1–84) for elevating sCa when administered subcutaneously (SC) into monkeys. Daily SC administration of LA-PTH (1.8 nmol/kg) into TPTX rats for 28-days elevated sCa to near normal levels without causing hypercalciuria or increasing bone resorption markers, a desirable goal in the treatment of hypoparathyroidism. The results are supportive of further study of long-acting PTH analogs as potential therapies for patients with hypoparathyroidism.
Parathyroid hormone (PTH) is essential for calcium homeostasis and its action is mediated by the PTH type 1 receptor (PTHR1), a class B G-protein-coupled receptor. Hypoparathyroidism and osteoporosis can be treated with PTH injections; however, no orally effective PTH analogue is available. Here we show that PCO371 is a novel, orally active small molecule that acts as a full agonist of PTHR1. PCO371 does not affect the PTH type 2 receptor (PTHR2), and analysis using PTHR1–PTHR2 chimeric receptors indicated that Proline 415 of PTHR1 is critical for PCO371-mediated PTHR1 activation. Oral administration of PCO371 to osteopenic rats provokes a significant increase in bone turnover with limited increase in bone mass. In hypocalcemic rats, PCO371 restores serum calcium levels without increasing urinary calcium, and with stronger and longer-lasting effects than PTH injections. These results strongly suggest that PCO371 can provide a new treatment option for PTH-related disorders, including hypoparathyroidism.
Background and purpose: Orally administered withanoside IV (a compound isolated from the roots of Withania somnifera) improved memory deficits in mice with a model of Alzheimer's disease induced by the amyloid peptide . Sominone, an aglycone of withanoside IV, was identified as an active metabolite after oral administration of withanoside IV. We aimed to identify receptors or associated molecules of sominone, and to investigate the effects of sominone on memory in normal mice. Experimental approach: Phosphorylation levels of 71 molecules were compared between control and sominone-stimulated cortical cultured cells to search for target molecules of sominone. Object location memory and neurite density in the brain were evaluated in sominone-injected mice. Key results: Phosphorylation of RET (a receptor for the glial cell line-derived neurotrophic factor, GDNF) was increased in neurons by sominone, without affecting the synthesis and secretion of GDNF. Knockdown of RET prevented sominone-induced outgrowths of axons and dendrites. After a single i.p. injection of sominone into normal mice, they could better memorize scenery information than control mice. Sixty minutes after sominone injection, RET phosphorylation was increased, particularly in the hippocampus of mice. After the memory tests, the densities of axons and dendrites were increased in the hippocampus by sominone administration. Conclusions and implications: Sominone could reinforce the morphological plasticity of neurons by activation of the RET pathway and thus enhance memory. Sominone, a compound with low molecular weight, may be a GDNF-independent stimulator of the RET pathway and/or a novel modulator of RET signalling.
Previously we showed that steroidal sapogenin, sominone improved memory after a single i.p. injection into normal mice. However, it had not been reported that sominone could recover memory deficits in a severe Alzheimer's disease (AD) model animal. Therefore, we aimed to investigate that sominone improved memory impairments in the 5XFAD mouse, model for AD. In the current study, we used sominone that we had synthesized. 5XFAD mice were given 10 μmol/kg sominone intraperitoneally for 9 days. In addition to object recognition memory, axonal density, amyloid plaque number, and activated microglia in the brain were evaluated. Sominone treatment significantly improved object recognition memory compared with vehicle control treatment. Sominone treatment significantly enhanced axonal densities in the frontal cortex and parietal cortex but had no effects on amyloid plaque number and activated microglia. In cultured cortical neurons, the axonal length was significantly reduced by Aβ(1-42) treatment. However, that was markedly recovered 5 days after the treatment with 1 μM sominone. Neuronal loss was not observed in the cortex and hippocampus of 5XFAD mice at 6-8 months of age. These results suggest that memory deficits in AD may be improved by sominone independently of reducing amyloid plaques and neuroinflammation.
Background : We previously hypothesized that achievement of recovery of brain function after the injury requires the reconstruction of neuronal networks, including neurite regeneration and synapse reformation. Kihi-to is composed of twelve crude drugs, some of which have already been shown to possess neurite extension properties in our previous studies. The effect of Kihi-to on memory deficit has not been examined. Thus, the goal of the present study is to determine the in vivo and in vitro effects of Kihi-to on memory, neurite growth and synapse reconstruction.
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