Ossification of the presumptive trabecular bone in the mandibular condyle and the presumptive cortical bone in the mandibular corpus of the pig mandible was investigated during development, using micro-computed tomography (microCT). Three-dimensional architecture and mineralization characteristics were assessed from ten pigs of different developmental ages. In the condyle, increases in trabecular thickness and separation and a decrease in the trabecular number, led to an unchanged bone volume fraction. A conversion from rod-like into plate-like trabeculae was observed. Bone volume and trabecular thickness were always higher in the corpus, where an increase in bone volume fraction was caused by an increase in the trabecular thickness and a decrease in separation. A transition from a plate-like structure into a more compact structure took place. The average degree of mineralization in the condyle and the corpus increased with age. In the corpus, the degrees of mineralization were higher than in the condyle. The differences between the condyle and corpus and the changes with age could be explained by differences in the distribution of mineralization within the trabecular elements. Generally, the degrees of mineralization increased from the surface toward the centers of the trabecular elements, indicating growth of the trabecular elements by the surface apposition of new mineral.
Numerous neurohumoral factors such as endothelin (ET)-1 and angiotensin (Ang) II as well as the stretch stimulus act concertedly in the in vivo overloaded heart in inducing hypertrophy and failure. The primary culture of rat neonatal cardiomyocytes is the only in vitro model that allows the comparative analysis of growth responses and signaling events in response to different stimuli. In the present study, we examined stretched rat cardiomyocytes grown on flexible bottomed culture plates for hypertrophic growth responses (protein synthesis, protein/DNA ratio, and cell volume), F-actin filaments rearrangement (by confocal laser scanning microscopy), and for signaling events (activation of phospholipase C [PLC]-β, protein kinase C [PKC], mitogenactivated protein [MAP] kinases) and compared these responses with ET-1 (10 -8 M)-stimulated cells. Cyclic stretch for 48 h induced hypertrophic growth in cardiomyocytes indicated by increases in the rate of protein synthesis, cell volume, and diameter, which were less pronounced in comparison to stimulation by ET-1. During cyclic stretch, we observed disoriented F-actin, particularly stress-fibers whereas during ET-1 stimulation, Factins rearranged clearly in alignment with sarcomeres and fibers. The upstream part of signaling by cyclic stretch did not follow the PLCβ-PKC cascade, which, in contrast, was strongly activated during ET-1 stimulation. Cyclic stretch and, to greater extent, ET-1 stimulated downstream signaling through ERK, p38 MAP kinase, and JNK pathways, but the involvement of tyrosine kinase and PI3 kinase-Akt signaling during cyclic stretch could not be proven. Taken together, our results demonstrate that both cyclic stretch and ET-1 induce hypertrophic responses in cardiomyocytes with different effects on organization of F-actin stress fibers in case of stretch. Furthermore, on the short-term basis, cyclical stretch, unlike ET-1, mediates its hypertrophic response not through activation of PLC-β and PKC but more likely through integrin-linked pathways, which both lead to downstream activation of the MAP kinase family.
Dietary n-6 and n-3 polyunsaturated fatty acids (PUFAs) have potent biological effects on the blood(cells), the vasculature and they myocardium. In the epidemiological studies in which the benefit from the regular ingestion of n-3 PUFAs was reported, the responsible mechanisms remain obscure. A great deal of the PUFA-effect can be explained by the known interference with the eicosanoid metabolism. Many processes, believed to be involved in atherogenesis such as adhesion and infiltration of bloodcells (in)to the vasculature, platelet aggregation, secretion of endothelium-derived factors and mitogenic responses of vascular smooth muscle cells are partially mediated by receptor-activated phospholipases C-beta and A2. As PUFAs take part at many steps of the signalling pathways, the latter could represent important action sites to beneficially interfere with atherogenesis. In this brief review, we have discussed the results of studies on the influence of alteration of PUFA composition of the membrane phospholipids or of exogenously administered non-esterified PURAs on phospholipid signalling. For convenience, we have mainly focused our discussion on those studies available on the myocardium. By changing the PUFA composition of the phospholipids, the endogenous substrates for the membrane-associated phospholipase C-beta and A2 are changed. This is accompanied by changes in their hydrolytic action on these substrates resulting in altered products (the molecular species of 1,2-diacylglycerols and the non-esterified PUFAs) which on their turn evoke changes in events downstream of the signalling cascades: activation of distinct protein kinase C isoenzymes, formation of distinct eicosanoids and non-esterified PUFA effects on Ca2+ channels. It has also become more clear that the membrane physicochemical properties, in terms of fluidity and cholesterol content of the bilayer, might undergo changes due to altered PUFA incorporation into the membrane phospholipids. The latter effects could have consequences for the receptor functioning, receptor-GTP-binding protein coupling, GTP-binding protein-phospholipase C-beta or A2 coupling as well. It should be noted that most of these studies have been carried out with cardiomyocytes isolated from hearts of animals on PUFA diet or incubation of cultured cardiomyocytes with non-esterified PUFAs in the presence of albumin. Studies need to be performed to prove that the PUFA-diet induced modulations of the phospholipid signalling reactions do occur in vivo and that these effects are involved in the mechanism of beneficial effects of dietary PUFAs on the process of atherosclerosis.
. The influence of increased incorporation of linoleic acid (18:2n-6) and eicosapentaenoic acid (20:5n-3) in membrane phospholipids on receptor-mediated phospholipase C (PLC-) activity in cultured rat ventricular myocytes was investigated. For this purpose, cells were grown for 4 days in control, stearic acid (18:0)/oleic acid (18:1n-9), 18:2n-6 and 20:5n-3 enriched media, and subsequently assayed for the basal-and phenylephrine-or endothelin-1-induced total inositol phosphate formation. The various fatty acid treatments resulted in the expected alterations of fatty acid composition of membrane phospholipids. In 18:2n-6-treated cells, the incorporation of this 18:2n-6 in the phospholipids increased from 17.1 mol % in control cells to 38.9 mol %. In 20:5n-3-treated cells, incorporation of 20: 5n-3 and docosapentaenoic acid (22:5n-3) in the phospholipids increased from 0.5 and 2.7 mol % in control cells to 23.2 and 9.7 mol %, respectively. When 20:5n-3-treated cells were stimulated with phenylephrine or endothelin-1, the inositolphosphate production decreased by 33.2% and increased by 43.4%, respectively, as compared to cells grown in control medium. No effects were seen in 18:2n-6-treated cells. When 18:0/18:1n-9-treated cells were stimulated with endothelin-1, inositolphosphate formation increased by 26.4%, whereas phenylephrine-stimulated inositolphosphate formation was not affected. In saponin-permeabilized cells, that were pre-treated with 20:5n-3, the formation of total inositolphosphates after stimulation with GTP S, in the presence of Ca 2+ , was inhibited 19.3%. This suggests that the 20:5n-3 effect on intact cardiomyocytes could be exerted either on the level of agonist-receptor, receptor-GTP-bindingprotein coupling or GTP-binding-protein-PLC-interaction. Investigation of the time course of saponin-induced permeabilization of the cardiomyocytes, measured by the release of lactate dehydrogenase, unmasked a slight decrease in the rate of permeabilization by 20:5n-3 pretreatment, indicating a protective effect. This led the authors to measure the cholesterol/phospholipid molar ratio, the double bond index of membrane phospholipids, and the membrane fluidity; the latter by using a diphenylhexatriene probe. In 20:5n-3-pretreated cells, a strong increase in the cholesterol/ phospholipid molar ratio (from 0.23 to 0.39), a marked increase in the double bond index (from 1.76 to 2.33), and a slight decrease in fluidity (steady-state anisotropy r ss of the diphenylhexatriene probe increased from 0.196 to 0.217) were observed. Thus, treatment of cardiomyocytes for 4 days with 20:5n-3, but not with 18:2n-6, causes alterations of receptor-mediated phospholipase C activity. A causal relationship may exist between the 20:5n-3-induced alterations of the physicochemical properties in the bilayer and of the agonist-stimulated phosphatidylinositol cycle activity.
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