Epithelial folding in vitro: studies on the cellular mechanism underlying evagination of thyrocyte monolayers.

Epithelial monolayers in suspension culture fold in a way which closely resembles epithelial evagination. We have used freshly isolated segments of porcine thyroid follicles to study the mechanism underlying this evagination process. Epithelial folding was accompanied by dramatic changes in cell shape: the cells elongated and apical cell surfaces widened, whereas the basal cell portions were narrowed to about 20% of their original width. Apparently, enzymatic separation of thyroid epithelial cells from their underlying extracellular matrix resulted in an extension of the lateral cell-cell interactions on the expense of the basal cell surface area. Epithelial folding in vitro was Ca2+ dependent and reversibly blocked by cytochalasin D, by which the reorganization of the F-actin network was disturbed. This inhibitory effect was also observed by the action of cAMP analogues known to cause rounding of cells by their effect on cortical F-actin. Moreover, evagination in vitro was reversibly blocked at intracellular pH values of 5.8 and below. Under these conditions, protein phosphorylation was entirely inhibited. Inhibitors of protein kinases, specifically of myosin light chain kinase, were able to disrupt the evagination process, suggesting that protein phosphorylation, presumably of the myosin light chain, was essential for folding. We conclude that enzymatic separation of epithelial monolayers from their extracellular matrix initiated a cascade consisting of extended cell-cell interactions of the lateral plasma membranes and of reorganization of the apical actin-myosin network, finally resulting in profound changes in cell shape characteristic of epithelial evagination.

Structural basis of the phospholipid acyltransferase enzyme substrate specificity: a computer modeling study of the phospholipid acceptor molecule.

The activity of the 1-acyl-sn-glycero-3-phosphocholine acyltransferase enzyme (E.C. 2.3.1.??) was measured with three radically different acceptor substrates: 1-palmitoyl-sn-glycero-3-phosphocholine (P-sn-G3PC), 1-palmitoyl-sn-glycero-2-phosphocholine (P-sn-G2PC), and 1-hexadecyl-sn-glycero-3-phosphocholine (He-sn-G3PC). It was found that the enzyme had similar activity with P-sn-G3PC, the natural acceptor substrate, and with P-sn-G2PC. The enzyme showed no detectable activity toward He-sn-G3PC. These results are much different than would be expected from simple examination of the structures. Computer-assisted molecular modeling was done to study the geometrical configurations and to focus upon the similarities and differences of the three substrate acceptor molecules. Three bond distances were selected as important for enzyme recognition: the distance between the oxygen of the acceptor hydroxyl group and 1) the phosphorus; 2) the nitrogen; and 3) the oxygen bridge to the hydrocarbon chain. There were striking similarities for the bond distances of two of the three acceptor substrates, P-sn-G3PC and P-sn-G2PC. These were the two molecules that were shown to have activity with the enzyme. The bond distances found for the enzymically inactive acceptor substrate, He-sn-G3PC, differed significantly from P-sn-G3PC and P-sn-G2PC. Therefore, this latter molecule probably does not fit into the active site of the enzyme. The modeling data are also consistent with the experimental observation that He-sn-G3PC is not an inhibitor.

Enzymatic acylation of ether and ester lysophospholipids in rat liver microsomes.

The acylation of lysophospholipids by rat liver acyltransferases was studied. A comparison between ester and ether lysophospholipids as substrates revealed large differences in substrate properties. For instance, oleic acid from oleoyl-CoA and arachidonic acid from arachidonoyl-CoA were not incorporated into 1-O-octadecyl-sn-glycero-3-phosphocholine under experimental conditions that allowed an optimal transfer of oleic acid and arachidonic acid to 1-O-palmitoyl-sn-glycero-3-phosphocholine. However, we observed an acyl-CoA-independent transfer of arachidonic acid from 1-O-stearoyl-2-O-arachidonoyl-sn-glycero-3-phosphoinositol to 1-O-octadecyl-sn-glycero-3-phosphocholine.

Thyroglobulin, the major and obligatory exportable protein of thyroid follicle cells, carries the lysosomal recognition marker mannose-6-phosphate.

Thyroglobulin (TG), the major exportable protein of thyroid follicle cells, is conveyed to lysosomes on a complex secretion, storage and recapture pathway by as yet unknown transport mechanisms. This report establishes that the dimeric porcine TG-molecule carries an average of six phosphate residues. Endoglycosidase digestion showed that two phosphate residues are bound to the high-mannose carbohydrate side chains (CHO), while two others are linked to the complex CHO. These four residues are also sensitive to alkaline phosphatase treatment, indicating their terminal linkage. Immunoprecipitation analyses showed that TG obtained from microsomal fractions is already phosphorylated. Most important, an enzymatic assay applied to hydrolysates of TG established that the two phosphate residues at the high mannose CHO are present as mannose-6-phosphate (M-6-P). Alkaline phosphatase treatment of biosynthetically radiophosphorylated CHO followed by hydrolysis and t.l.c. indicated that M-6-P is present at least in part in phosphomonoester linkage. Furthermore, porcine TG binds specifically to the M-6-P receptor of Chinese hamster ovary cells. It is concluded that the M-6-P residues of TG are exposed and able to operate as a ligand for the M-6-P receptor. It is unknown why the lysosomal recognition-marker M-6-P does not convey TG directly on an intracellular route to lysosomes. We propose that for the secretion of newly synthesized TG into the follicle lumen an additional export signal dominating over the M-6-P recognition-marker is required.

Radiation damage in solid 5-halouracils: free radicals in single crystals of 5-fluorouracil.

X-irradiation at 300 K of single crystals of 5-fluorouracil results in the formation of two different radical species observable by e.s.r. and ENDOR-spectroscopy. One is an alpha-fluoro radical RCF(CH2)R' formed by saturation of the 5,6-double bond of the pyrimidine ring. The principal values of its alpha-fluorine interaction are 170, -9 and -18 G; the isotropic part of the methylene beta-proton couplings are 46.3 and 28 G, respectively; the g-tensor has principal values of 2.0029, 2.0066, and 2.0052. The other radical species is formed by enolization of the C4-carbonyl function. The resulting spin-density distribution gives rise to three observable interactions, an alpha-proton (-5.2, -14.9, -11.2 G) at C6, an OH-proton from the C4--OH group (-1.7, -5.0, -4.1 G) and a residual alpha-fluorine interaction (0,0,11.2G). Irradiation at 77 K yields an e.s.r.-pattern which is tentatively assigned to the molecular anion radical. These findings are related to the radiation chemistry of solid 5-halouracils.