Chronic kidney disease pathogenesis involves both tubular and vascular injuries. Despite abundant investigations to identify the risk factors, the involvement of chronic endothelial dysfunction in developing nephropathies is insufficiently explored. Previously, soluble thrombomodulin (sTM), a cofactor in the activation of protein C, has been shown to protect endothelial function in models of acute kidney injury. In this study, the role for sTM in treating chronic kidney disease was explored by employing a mouse model of chronic vascular activation using endothelial-specific TNF-α-expressing (tie2-TNF) mice. Analysis of kidneys from these mice after 3 mo showed no apparent phenotype, whereas 6-mo-old mice demonstrated infiltration of CD45-positive leukocytes accompanied by upregulated gene expression of inflammatory chemokines, markers of kidney injury, and albuminuria. Intervention with murine sTM with biweekly subcutaneous injections during this window of disease development between months 3 and 6 prevented the development of kidney pathology. To better understand the mechanisms of these findings, we determined whether sTM could also prevent chronic endothelial cell activation in vitro. Indeed, treatment with sTM normalized increased chemokines, adhesion molecule expression, and reduced transmigration of monocytes in continuously activated TNF-expressing endothelial cells. Our results suggest that vascular inflammation associated with vulnerable endothelium can contribute to loss in renal function as suggested by the tie2-TNF mice, a unique model for studying the role of vascular activation and inflammation in chronic kidney disease. Furthermore, the ability to restore the endothelial balance by exogenous administration of sTM via downregulation of specific adhesion molecules and chemokines suggests a potential for therapeutic intervention in kidney disease associated with chronic inflammation. 相似文献
Quantum dots (QDs) are nanocrystals of semiconducting material possessing quantum mechanical characteristics with capability to get conjugated with drug moieties. The particle size of QDs varies from 2 to 10 nm and can radiate a wide range of colours depending upon their size. Their wide and diverse usage of QDs across the world is due to their adaptable properties like large quantum yield, photostability, and adjustable emission spectrum. QDs are nanomaterials with inherent electrical characteristics that can be used as drug carrier vehicle and as a diagnostic in the field of nanomedicine. Scientists from various fields are aggressively working for the development of single platform that can sense, can produce a microscopic image and even be used to deliver a therapeutic agent. QDs are the fluorescent nano dots with which the possibilities of the drug delivery to a targeted site and its biomedical imaging can be explored. This review is mainly focused on the different process of synthesis of QDs, their application especially in the areas of malignancies and as a theranostic tool. The attempt is to consolidate the data available for the use of QDs in the biomedical applications. 相似文献
Brachypodium distachyon is a widely recognized model plant belonging to subfamily Pooideae with a sequenced genome. To gain a better understanding of the male reproductive development in B. distachyon we examined pollen morphology and cytochemical changes of microspore cytoplasm from pollen mother cell stage to mature pollen using light, fluorescent and scanning electron microscopy. Our results show that B. distachyon exhibits a typical monocot-type pollen ontogeny. Meiosis in the pollen mother cells is accomplished by successive cytokinesis generating isobilateral tetrads. Cytochemical examination indicated that microspore cytoplasm contains variable amounts of insoluble carbohydrates and proteins at different developmental stages. Deposition of starch in the cytoplasm of microspores starts at the bicellular stage and continues till the mature pollen stage. The formation of the exine wall progresses by the deposition of sporopollenin from the tapetum layer of the anther. The mature pollen is trinucleate, spheroidal in shape and possesses a single pore with an annulus and operculum. The exine pattern is smooth and of granular type. 相似文献
Summary This study investigates the long-term angiogenic effects of ANG-1 and VEGF in a swine chronic myocardial ischemia model. Four-weeks after gradual occlusion of the left circumflex coronary artery by ameroid constrictor, animals were injected with recombinant adenoviral vectors carrying either human ANG-1 (n=9), human VEGF165 (n=10) or empty vector (n=7) into the left ventricle free wall supplied by the constricted artery. Left ventricular perfusion in animals that received AdANG-1 (3.25±0.16 ml/min/g, p<0.05) recovered robustly 4 weeks after gene transfer while ischemia persisted in the AdVEGF (1.09±0.13 ml/min/g) and empty vector (1.20±0.03 ml/min/g) groups. Microvascular densities in the left ventricles of animals that received AdANG-1 (19.61±1.76/0.572 mm2 myocardial tissue, p<0.05) and AdVEGF (18.17±1.43/0.572 mm2 myocardial tissue, p<0.05) were significantly higher than animals that received empty vector (13.53±0.92/0.572 mm2 myocardial tissue) 12 weeks after gene transfer. ANG-1, but not VEGF, contributed to enhanced regional perfusion by increasing arteriolar density (1.9±0.4/0.572 mm2 myocardial tissue vs. 0.7±0.2/0.572 mm2 myocardial tissue, p<0.05) of large-sized (50–100 μm) arterioles. These data demonstrate that gene transfer of ANG-1 and VEGF enhances angiogenesis, but ANG-1 promotes sustained improvement of ventricular perfusion that expedites recovery of ischemic myocardium via arteriogenesis. 相似文献
The R6/2 transgenic mouse model of Huntington’s disease (HD) carries several copies of exon1 of the huntingtin gene that contains a highly pathogenic 120 CAG-repeat expansion. We used kinome analysis to screen for kinase activity patterns in neural tissues from wildtype (WT) and R6/2 mice at a pre-symptomatic (e.g., embryonic) and symptomatic (e.g., between 3 and 10 weeks postnatal) time points. We identified changes in several signaling cascades, for example, the Akt/FoxO3/CDK2, mTOR/ULK1, and RAF/MEK/CREB pathways. We also identified the Rho-Rac GTPase cascade that contributes to cytoskeleton organization through modulation of the actin-binding proteins, cofilin and profilin. Immunoblotting revealed higher levels of phosphoSer138-profilin in embryonic R6/2 mouse samples (cf. WT mice) that diminish progressively and significantly over the postnatal, symptomatic course of the disease. We detected sex- and genotype-dependent patterns in the phosphorylation of actin-regulators such a ROCK2, PAK, LIMK1, cofilin, and SSH1L, yet none of these aligned consistently with the changing levels of phosphoSer138-profilin. This could be reflecting an imbalance in the sequential influences these regulators are known to exert on actin signaling. The translational potential of these observations was inferred from preliminary observations of changes in LIMK-cofilin signaling and loss of neurite integrity in neural stem cells derived from an HD patient (versus a healthy control). Our observations suggest that a pre-symptomatic, neurodevelopmental onset of change in the phosphorylation of Ser138-profilin, potentially downstream of distinct signaling changes in male and female mice, could be contributing to cytoskeletal phenotypes in the R6/2 mouse model of HD pathology.
This study reports the isolation of bacterial cultures, capable of selective removal of nitrogen and sulfur from carbazole and dibenzothiophene, respectively. The isolates utilizing carbazole were found to be suitable for biorefining. These were designated as P10 and P11, and were identified as Pseudomonas sp. Growing cells of P10 and P11 could utilize 77% carbazole in 250 and 120 h, respectively. Isolates showing utilization of dibenzothiophene were not suitable for biorefining industry. Results suggest these Pseudomonas isolates may be useful in petroleum biorefining for the selective removal of organically bound nitrogen from petroleum. 相似文献
Rising tropospheric ozone (O3) and temperature, the two most important stresses caused due to climate change. Both stresses have now become foremost concerns for production of tomato worldwide due to their role in immensely afflicting productivity. These stresses have been found to occur concomitantly, and tomato is very sensitive to both heat stress and elevated O3. This paper reviews the individual effects of high temperature and elevated O3 on the overall performance of tomato and the defense strategies responsible for varying sensitivities among the genotypes. High temperature influences photosynthesis directly, and Fv/Fm ratio was widely used in identifying the sensitivity of tomato cultivars. It also affects pollen viability and germination, which ultimately results in the decline of fruit set and yield. Phytohormones are crucial for reducing the negative impacts of high temperature on tomato. Besides, several heat-shock proteins and factors and stress-regulated genes were upregulated in tomato under heat stress. An increase in surface O3 level causes reductions in photosynthesis, biomass accumulation, pollen viability, fruit quality, and yield. Various molecular and physiological processes deployed during elevated O3 conditions are believed to be intervened by signaling molecules like ethylene and jasmonic acid. The review concludes that responses of tomato to both the stresses are somewhat similar, but their nature and effects may vary with intensity and duration of stresses, genotypes, and other environmental factors. Since these stresses occur simultaneously, their combined effects need to be understood to avoid the yield losses under future scenarios of climate change.
