[Vascular Calcification - Pathological Mechanism and Clinical Application - . Vascular calcification in aged mice].

Vascular calcification is a risk factor for cerebral and cardiovascular events and has a high prevalence among elderly. To finding ways of prevent or cure vascular calcification may leads to not only a healthy longevity but also medical expenditure reduction. However, the molecular mechanism underlying this pathogenic process is still obscure. To clarify the mechanism of vascular calcification, the development of animal models that exhibit extensive and robust vascular calcification is an important issue for research in vascular biology.

Antibodies against muscle-specific kinase impair both presynaptic and postsynaptic functions in a murine model of myasthenia gravis.

Antibodies against acetylcholine receptors (AChRs) cause pathogenicity in myasthenia gravis (MG) patients through complement pathway-mediated destruction of postsynaptic membranes at neuromuscular junctions (NMJs). However, antibodies against muscle-specific kinase (MuSK), which constitute a major subclass of antibodies found in MG patients, do not activate the complement pathway. To investigate the pathophysiology of MuSK-MG and establish an experimental autoimmune MG (EAMG) model, we injected MuSK protein into mice deficient in complement component five (C5). MuSK-injected mice simultaneously developed severe muscle weakness, accompanied by an electromyographic pattern such as is typically observed in MG patients. In addition, we observed morphological and functional defects in the NMJs of EAMG mice, demonstrating that complement activation is not necessary for the onset of MuSK-MG. Furthermore, MuSK-injected mice exhibited acetylcholinesterase (AChE) inhibitor-evoked cholinergic hypersensitivity, as is observed in MuSK-MG patients, and a decrease in both AChE and the AChE-anchoring protein collagen Q at postsynaptic membranes. These findings suggest that MuSK is indispensable for the maintenance of NMJ structure and function, and that disruption of MuSK activity by autoantibodies causes MG. This mouse model of EAMG could be used to develop appropriate medications for the treatment of MuSK-MG in humans.

A novel organ culture model of aorta for vascular calcification.

Vascular calcification is a characteristic feature of aging, atherosclerosis, diabetes mellitus, and end-stage renal disease. The use of organ culture provides complementary information that may bridge the gap between traditional cell culture and animal models, and establishes easily controlled experimental conditions. Therefore, we investigated whether organ culture of the aorta could be used as a model of vascular calcification, applying it to animal models of other conditions. Thoracic aortas were dissected from C57BL/6 mice and cultured. To induce vascular calcification, stimulation with inorganic phosphate (Pi) was performed. Morphometric assessment of medial calcium deposition was quantitatively performed, and the amount of dissolved calcium was measured. Pi-stimulation induced calcium deposition in medial layers in a time- and dose-dependent manner. To investigate the phenotypic change of vascular smooth muscle cells (VSMC), the expression of Runx2, osterix, osteocalcin, and ALP activity were determined. Finally, to investigate the influence of Pi-stimulation on the cultured aorta in other models, aortas from streptozotocin (STZ)-induced diabetic mice, aged mice, and Sirt1 knockout (+/-) mice were dissected. These cultures showed a greater tendency for aortic calcification by Pi-stimulation than did control cultures. These results indicate that organ culture of the aorta from mice reflects the state of calcification and suggests that this model will be useful to explore the molecular mechanisms of vascular calcification and the pathology of senescence.

3,4-Diaminopyridine improves neuromuscular transmission in a MuSK antibody-induced mouse model of myasthenia gravis.

This study investigated the effect of 3,4-diaminopyridine (3,4-DAP), a potent potentiator of transmitter release, on neuromuscular transmission in vivo in a mouse model of myasthenia gravis (MG) caused by antibodies against muscle-specific kinase (MuSK; MuSK-MG) and ex vivo in diaphragm muscle from these mice. 3,4-DAP significantly improved neuromuscular transmission, predominantly by increasing acetylcholine (ACh) release, supporting presynaptic potentiation as an effective treatment strategy for MuSK-MG patients who have defective transmitter release. In MuSK-MG, we suggest that only low-dose acetylcholinesterase (AChE) inhibitors be used to avoid side effects, and we propose that 3,4-DAP may be effective as a symptomatic therapy.

Testosterone deficiency accelerates neuronal and vascular aging of SAMP8 mice: protective role of eNOS and SIRT1.

Oxidative stress and atherosclerosis-related vascular disorders are risk factors for cognitive decline with aging. In a small clinical study in men, testosterone improved cognitive function; however, it is unknown how testosterone ameliorates the pathogenesis of cognitive decline with aging. Here, we investigated whether the cognitive decline in senescence-accelerated mouse prone 8 (SAMP8), which exhibits cognitive impairment and hypogonadism, could be reversed by testosterone, and the mechanism by which testosterone inhibits cognitive decline. We found that treatment with testosterone ameliorated cognitive function and inhibited senescence of hippocampal vascular endothelial cells of SAMP8. Notably, SAMP8 showed enhancement of oxidative stress in the hippocampus. We observed that an NAD(+)-dependent deacetylase, SIRT1, played an important role in the protective effect of testosterone against oxidative stress-induced endothelial senescence. Testosterone increased eNOS activity and subsequently induced SIRT1 expression. SIRT1 inhibited endothelial senescence via up-regulation of eNOS. Finally, we showed, using co-culture system, that senescent endothelial cells promoted neuronal senescence through humoral factors. Our results suggest a critical role of testosterone and SIRT1 in the prevention of vascular and neuronal aging.

Muscle weakness and neuromuscular junctions in aging and disease.

A critical issue in today's super-aging society is the need to reduce the burden of family care while continuing to make our medical institutions supportive. A rapidly emerging, major health concern is the debilitating effect of muscle weakness and atrophy from aging, termed sarcopenia; however, the molecular basis of this condition is not well understood. Our research aim is to elucidate the molecular mechanisms of age-related muscle atrophy and to devise new measures for preventing and treating this disability. A promising treatment for muscle atrophy is the promotion of muscle regeneration by recruiting stem cells into the targeted region. The first requirement is to understand how the motor system, which consists of muscles and motoneurons, is maintained to accomplish that goal. Recent studies in the field of neuroscience have focused on neuromuscular junctions (NMJ), which play important roles in the maintenance of both motor nerves and muscle fibers. Signaling between muscles and motoneurons at NMJ supports interactions within the motor system. To understand the mechanisms involved, we focus our research on the pathogenic processes underlying neuromuscular diseases. The well-known autoimmune disease, myasthenia gravis (MG), serves as a model not only for tracking the pathogenesis and treatment outcomes of all autoimmune diseases, but also for understanding synaptic functions in maintaining the motor system. Here, we describe recent insights into the molecular mechanisms required for the maintenance of NMJ and the related causes of muscle atrophy.