Role of fatty acid structure in the reversible activation of phosphatidylcholine synthesis in lymphocytes

Fatty acids rapidly accelerate (1.5-7.0-fold) the incorporation of [methyl-3H]choline chloride into the phosphatidylcholine fraction of bovine lymphocyte lipids. This ability of fatty acids to activate choline phospholipid synthesis has been correlated with certain structural features of fatty acids. Mono- and polyenoic unsaturated fatty acids of 18 and 20 carbons in length are highly active, whereas their saturated analogues are nearly inactive. Among the unsaturated fatty acids, the cis-isomers are active, while the trans-isomers are relatively ineffective. The delayed addition of bovine serum albumin (5 mg/ml) and other lipid-binding proteins to activated cells rapidly counteracts the lipid effects. The activated state of the cell membrane thus appears to be a dynamic one, requiring the continued interaction of the fatty acid with a lipid-sensitive target molecule of the cell surface that in turn appears to coordinate the enzymatic components of this pathway.     

Analysis of the effects of fatty acids and related compounds on the synthesis of phosphatidylcholine in lymphocytes

Phosphatidylcholine synthesis in cultured bovine lymphocytes is stimulated by cis-unsaturated fatty acids. This stimulation is correlated with an activation of the enzyme cytidyltransferase (EC 2.7.7.15) and its apparent translocation from the cytosol to the membrane/particulate of cells. In addition, these agents increase the levels of cytidine diphosphocholine - a product of the cytidyltransferase reaction and a precursor to phosphatidylcholine. Retinoic acid and 5,8,11,14-eicosatetraynoic acid both activate cytidyltransferase activity and raise cytidine diphosphocholine levels, yet they are ineffective as stimulators of overall phosphatidylcholine synthesis. The effects of all of these lipids are reversed by the delayed addition of bovine serum albumin. The data point to the view that cytidyltransferase activation is required but is not sufficient for stimulation of phosphatidylcholine synthesis: regulation at another step is suggested.     

Improved methods for using glass coverslips in cell culture and electron microscopy.

For many applications, cells or tissue must be cultured on an optical surface of high quality. For such applications laboratories often prepare "special dishes," which are made by affixing a glass coverslip beneath a hole in a plastic petri dish bottom. In this report, we offer an improved method, using Parafilm as a dry mount adhesive, for the preparation of special dishes, and show that the resulting dish is non-toxic to neurons in culture. The Parafilm bond is stable at 60 degrees C, permitting electron microscopy resins to be poured directly into the dishes and cured. The glass coverslip can be readily removed from the cured resin mechanically. The techniques we describe offer time-saving and reliable improvements for the use of glass coverslips in cell culture and electron microscopy.     

A temporospatial map of adhesive molecules in the organ of corti of the mouse cochlea

In the nervous system, several classes of cell-surface and extracellular matrix molecules have been implicated in processes such as neural growth, fasciculation, pathfinding, target recognition and synaptogenesis, which require cell-to-cell or cell-to-substrate binding. In the developing mouse cochlea, little is known about the types of cell-surface and extracellular matrix molecules existing along the neural growth paths or their possible roles in development. Whole mount and sectioned cochlear tissue were immunolabeled for six different adhesive molecules - neural cell adhesion molecule (NCAM), polysialic acid (PSA), neural cell adhesion molecule L1, E-cadherin, syndecan-1 and tenascin-C. A temporospatial map of adhesive molecule distribution in the basal turns of the mouse cochlea was generated. Distributions of adhesive molecules were compared to each other and to the known progress of neural development in the region. This comparison demonstrated differences in the complements of adhesive molecules between the inner and outer hair cell regions, and variations in the expressions of adhesion molecules among different types of nerve fibers. In addition, developmental changes in the adhesive environment around and beneath the outer hair cells coincided with the known timing of the appearance of morphologically defined efferent synapses. These observations raise the possibility that molecular differences at the cell surface of inner and outer hair cells are one way that ingrowing neurites distinguish different environments to determine their growth routes and synaptic partners in the cochlea. In addition these observations demonstrate the potential for differential signaling of afferent and efferent innervation by altering the microenvironments in which synapses are formed.