Klotho mutant mice exhibit a set of phenotypes resembling human ageing. Although the function of Klotho remains unclear, mediation of its pleiotropic functions by putative humoral factor(s) has been presumed. Newly established antibodies against Klotho allowed the detection of secreted Klotho, a candidate for the putative humoral factor, in sera and cerebrospinal fluid. Surprisingly the secreted Klotho was 130 kDa, in contrast to the 70 kDa predicted form from klotho gene transcripts. The secreted as well as the membrane-bound Klotho proteins were suggested to form oligomerized complex. These results delineate post-translation processing of Klotho and possible regulatory mechanisms for secretion of Klotho in vivo.
Klotho, an antiaging gene with restricted organ distribution, is mainly expressed in the kidney tubules; the mutant mice have shortened life span, arteriosclerosis, anemia, and osteoporesis, features common to patients with chronic renal failure. Conceivably, the reduction of the Klotho gene expression may contribute to the development of kidney failure; alternatively, its overexpression may lead to the amelioration of renal injury in an ICR-derived glomerulonephritis (ICGN) mouse model with subtle immune complex-mediated disease. To address this issue, four different strains of mice were generated by cross-breeding: ICGN mice without the Klotho transgene (ICGN), ICGN mice with the Klotho transgene (ICGN/klTG), wild-type mice with the Klotho transgene (klTG), and wild-type mice without the Klotho transgene (control). At 40 weeks old, the survival rate was Ϸ30% in ICGN mice, and Ϸ70% in the ICGN/klTG group. This improvement was associated with dramatic improvement in renal functions, morphological lesions, and cytochrome c oxidase activity but a reduction in -galactosidase activity (a senescence-associated protein), mitochondrial DNA fragmentation, superoxide anion generation, lipid peroxidation, and Bax protein expression and apoptosis. Interestingly, improvement was seen in both the tubular and glomerular compartments of the kidney, although Klotho is exclusively confined to the tubules, suggesting that its gene product has a remarkable renoprotective effect by potentially serving as a circulating hormone while mitigating the mitochondrial oxidative stress.aging ͉ glomerulonephritis ͉ oxidative stress ͉ tubular interstitial disease T he Klotho gene was originally identified by insertional mutagenesis, and it encodes a 130-kDa transmembrane protein that shares sequence homology with -glucosidase (1). The gene is predominantly expressed in the kidney and, to a lesser extent, in the brain and reproductive and endocrine organs. Its deletion in mice (Kl Ϫ/Ϫ ) results in the development of a syndrome resembling human aging, including shortened life span, growth retardation, infertility, arteriosclerosis, skin and muscle atrophy, osteoporosis, and pulmonary emphysema (1). Conversely, overexpression of the Klotho gene extends the life span in mice (2). Although kl Ϫ/Ϫ mice do not show any overt renal abnormalities, the Klotho mRNA expression in the kidneys has been shown to be greatly reduced in patients with chronic renal failure (3). Notably, most of the features of Klotho gene-deleted mice are similar to those of the patients with chronic renal failure. In addition, Klotho gene expression has been found to be reduced in acute renal failure in ischemia-reperfusion injury murine models (4). These findings would imply that the reduction of Klotho protein may be relevant to the pathophysiology of renal failure. However, little is known concerning whether Klotho protein itself could exert an ameliorative effect on a diseased kidney to preserve its renal functions and thus could serve as a therapeutic target in various ...
Despite extensive research for more than 200 years, the experimental isolation of monatomic sulphur chains, which are believed to exhibit a conducting character, has eluded scientists. Here we report the synthesis of a previously unobserved composite material of elemental sulphur, consisting of monatomic chains stabilized in the constraining volume of a carbon nanotube. This one-dimensional phase is confirmed by high-resolution transmission electron microscopy and synchrotron X-ray diffraction. Interestingly, these one-dimensional sulphur chains exhibit long domain sizes of up to 160 nm and high thermal stability (~800 K). Synchrotron X-ray diffraction shows a sharp structural transition of the one-dimensional sulphur occurring at ~450–650 K. Our observations, and corresponding electronic structure and quantum transport calculations, indicate the conducting character of the one-dimensional sulphur chains under ambient pressure. This is in stark contrast to bulk sulphur that needs ultrahigh pressures exceeding ~90 GPa to become metallic.
SignificancePIEZOs are mechanically activated cation channels. Recently, loss-of-function mutations of human PIEZO1 were found among patients with familial lymphedema, suggesting a requirement of PIEZO1 in the lymphatic system. In this paper, utilizing mouse models lacking PIEZO1 in endothelial cells, we show that this ion channel is required for the formation of lymphatic valves, a key structure for proper circulation of lymph in the body. The requirement of PIEZO1 in valve formation provides mechanistic insight on how PIEZO1 variants cause lymphatic dysfunction in patients. This study also extends the relevance of PIEZOs beyond acute signaling molecules (e.g., touch sensation) and highlights the importance of these ion channels in controlling morphological/structural specification during development.
The introduction of foreign atoms, such as nitrogen, into the hexagonal network of an sp(2)-hybridized carbon atom monolayer has been demonstrated and constitutes an effective tool for tailoring the intrinsic properties of graphene. Here, we report that boron atoms can be efficiently substituted for carbon in graphene. Single-layer graphene substitutionally doped with boron was prepared by the mechanical exfoliation of boron-doped graphite. X-ray photoelectron spectroscopy demonstrated that the amount of substitutional boron in graphite was ~0.22 atom %. Raman spectroscopy demonstrated that the boron atoms were spaced 4.76 nm apart in single-layer graphene. The 7-fold higher intensity of the D-band when compared to the G-band was explained by the elastically scattered photoexcited electrons by boron atoms before emitting a phonon. The frequency of the G-band in single-layer substitutionally boron-doped graphene was unchanged, which could be explained by the p-type boron doping (stiffening) counteracting the tensile strain effect of the larger carbon-boron bond length (softening). Boron-doped graphene appears to be a useful tool for engineering the physical and chemical properties of graphene.
Cadherins, a family of transmembrane cell-cell adhesion receptors, require interactions with the cytoskeleton for normal function. To assess the mechanisms of these interactions, we studied the effect of exogenous expression of a mutant N-cadherin, cN390A, on epithelial cell-cell adhesion. The intracellular domain of cN390A was intact but its extracellular domain was largely deleted so that this molecule was not functional for cell adhesion. cDNA of cN390A was attached to the metallothionein promoter, and introduced into the keratinocyte line PAM212 expressing endogenous E-and P-cadherin. When the expression of cN390A was induced by Zn2+, cadherin-dependent adhesion of the transfected cells was inhibited, resulting in the dispersion of cell colonies, although their contacts were maintained under high cell density conditions. In these cultures, cN390A was expressed not only on the free surfaces of the cells but also at cell-cell junctions. The endogenous cadherins were concentrated at cell-cell junctions under normal conditions. As a result of cN390A expression, however, the endogenous cadherins localizing at the cell-cell junctions were largely diminished, suggesting that these molecules were replaced by the mutant molecules at these sites. As a control, we transfected the same cell line with cDNA of a truncated form of Ncadherin whose intracellular C terminus had been deleted leaving the extracellular domain intact. This molecule had no effect on cell-cell adhesion, nor did it localize to cell-cell contact sites. We also found that the association of the endogenous cadherins with a-and 3-catenins and plakoglobin was not affected by the expression of cN390A, which also formed a complex with these molecules, suggesting that no competition occurred between the endogenous and exogenous cadherins for these cytoplasmic proteins. These and other additional results suggest that the nonfunctional cadherins whose intracellular domain is intact occupy the sites where the endogenous cadherins should localize, through interactions with the cytoskeleton, and inhibit the cadherin adhesion system.
Numerous otherwise difficult applications have been realized with materials, the chemical/physical properties of which can be controlled by external stimuli such as heat, pressure, photo‐irradiation, and voltage bias. However, the complexity of design and the lack of easy‐to‐conduct synthetic methods make the creation of on‐demand stimuli responsive materials a formidable task. Here we report an electric‐stimuli‐responsive multifunctional material, [10]CPP‐I: crystalline assembly of a hydrocarbon nanoring ([10]cycloparaphenylene: [10]CPP) as an “electro‐responsive porous host” and iodine as a “potentially functional molecule”. Through applying electric stimulus, [10]CPP‐I turned to exhibit two attractive properties: electronic conductivity and white light emission. We revealed that electric stimuli trigger the cascade formation of polyiodide chains inside the [10]CPP assembly through charge transfer, leading to the emergence of these properties. This “responsive porous host” approach is expected to be applicable for different stimuli, and opens the path for devising a generic strategy to the development of stimuli‐responsive materials.
The molecular carbon nanoring, cycloparaphenylene (CPP), is fascinating as a new class of carbonaceous porous solids with the uniform structure of an all-benzene surface.
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