Lipids in Signaling

The phosphorylation and dephosphorylation of seryl, threonyl, and tyrosyl residues regulate the activity of certain enzymes of lipid and carbohydrate metabolism and the properties of proteins that participate in signal transduction cascades. 

While the fluid mosaic model of membrane stmcture has stood up well to detailed scrutiny, additional features of membrane structure and function are constantly emerging. Two structures of particular current interest, located in surface membranes, are tipid rafts and caveolae. The former are dynamic areas of the exo-plasmic leaflet of the lipid bilayer enriched in cholesterol and sphingolipids they are involved in signal transduction and possibly other processes. Caveolae may derive from lipid rafts. Many if not all of them contain the protein caveolin-1, which may be involved in their formation from rafts. Caveolae are observable by electron microscopy as flask-shaped indentations of the cell membrane. Proteins detected in caveolae include various components of the signal-transduction system (eg, the insutin receptor and some G proteins), the folate receptor, and endothetial nitric oxide synthase (eNOS). Caveolae and lipid rafts are active areas of research, and ideas concerning them and their possible roles in various diseases are rapidly evolving. 

Immunocytochemical methods have been widely applied to visualize proteins, carbohydrates, or lipids in sectioned material. The advantage of using immunocytochemistry is to be able to localize the molecules of interest within the tissue. Several procedures have been described. Basically, these procedures can be split into four main steps that are described in subheadings (1) tissue preparation, (2) the primary antibodies, (3) the visualization of the target, and (4) enhancement of signals with antibody complexes. In addition, a protocol for alkaline phosphatase will be presented in detail in Subheading 5. The terms primary and secondary antibodies refer to the order in which they are applied to the target. The immunocytochemical procedures are not limited to sectioned... 

Compared to lipids in the subcutaneous fat layer and in the bone marrow (TiR O.S s), musculature shows a clearly slower longitudinal relaxation (Ti 1.0 s). For this reason, musculature has lost more signal intensity than fat in Ty weighted images, when compared with proton density weighting (Fig. 5a... 

In Section 5.1 usual strategies to obtain reliable calibration by external and internal references are reported. Section 5.2 presents techniques for analysing overlapping resonance lines with symmetric and well-defined lineshapes. Section 5.3 shows a more suitable approach for differentiation of IMCL and EMCL in the complex signal patterns of lipids in muscle spectra. 

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