Inhibition of palatal epithelial cell death by altered protein synthesis.

Programmed cell death occurs in a defined region of the secondary palatal epithelium (medial edge) during its development in vivo or in vitro. The purpose of this study was to examine the effects of various inhibitors of macromolecular synthesis, particularly glycoprotein synthesis, on the death of palatal medial-edge epithelial cells in vitro. Rat palatal shelves explanted on gestational Day 15 and cultured singly showed medial-edge cell degeneration after 48 hr, whereas in the presence of 6-diazo-5-oxo-l-norleucine (DON), 2-deoxyglucose (DOG), or cycloheximide, cell death was prevented. This was in contrast to the lack of inhibition of cell death in the presence of actionomycin D or cytosine arabinoside. Selectively adding metabolites which bypass the effect of DON on various synthetic pathways demonstrated that the inhibition of cell death by DON was most likely due to a block in glucosamine formation. The synthesis and activity of various lysosomal enzymes were not affected by DON, whereas a marked decrease was observed with both cycloheximide and DOG. These results suggest that palatal epithelial cell death is not a passive event, but an active process requiring the programmed synthesis of specific proteins.     

Overexpression of cofilin stimulates bundling of actin filaments, membrane ruffling, and cell movement in Dictyostelium

Cofilin is a low molecular weight actin-modulating protein whose structure and function are conserved among eucaryotes. Cofilin exhibits in vitro both a monomeric actin-sequestering activity and a filamentous actin-severing activity. To investigate in vivo functions of cofilin, cofilin was overexpressed in Dictyostelium discoideum cells. An increase in the content of D. discoideum cofilin (d-cofilin) by sevenfold induced a co-overproduction of actin by threefold. In cells over-expressing d-cofilin, the amount of filamentous actin but not that of monomeric actin was increased. Overexpressed d-cofilin co-sedimented with actin filaments, suggesting that the sequestering activity of d- cofilin is weak in vivo. The overexpression of d-cofilin increased actin bundles just beneath ruffling membranes where d-cofilin was co- localized. The overexpression of d-cofilin also stimulated cell movement as well as membrane ruffling. We have demonstrated in vitro that d-cofilin transformed latticework of actin filaments cross-linked by alpha-actinin into bundles probably by severing the filaments. D. discoideum cofilin may sever actin filaments in vivo and induce bundling of the filaments in the presence of cross-linking proteins so as to generate contractile systems involved in membrane ruffling and cell movement.     

Effect of protein synthesis inhibitors on DNA replication. I. Effect of the short-term action of cycloheximide on cell permeability for thymidine in vitro]

The effect of protein synthesis inhibitors on DNA replication was studied on L cells. After a 10 minutes' action of the inhibitors, protein synthesis was seen to be completely blocked, and DNA synthesis decreased by 85%. Four hours after a 20-minutes' cycloheximide treatment, the cells completely restored their ability to protein synthesis and DNA replication and even surpass the control level, due, probably, to a partial cell synchronization in S period. The short action of cycloheximide did not interfere with thymidine uptake by the cells. The rate of the exogenous precursor uptake was even higher than that in the control, apparently, because of its much reduced utilization in the inhibited DNA synthesis.     

Ruffling and locomotion: Role in cell resistance to growth factor-induced proliferation

It has long been known that the growth rate of cells in vitro can be retarded by providing substrates of restricted area. Such experiments were performed with adhesive islets, made by depositing metals onto agarose layers through templates of various sizes. Since normal cells are unable to adhere to agarose, they become confined to the metallic surface. Using such haptotactic islets, we have studied the role of membrane ruffling and cell locomotion in the resistance of AG1523 human fibroblasts to growth factor-induced mitogenesis. Cells plated on small substrates, i.e., 2,150 μm² in area, initially showed vigorous ruffling, which was suppressed by 8 h after plating but had resumed again by 12 h. In contrast, cells on larger-size islets showed a rapid decline and stabilization of ruffling activity. When the growth rate was measured for single cells cultured on haptotactic islets, it was found to increase linearly from areas of 4,280 μm² up to 425,000 μm². Since the area needed to saturate the growth response was ～50-fold larger than the area occupied by a single cell, the growth inhibition was attributed in part to an interference with locomotion. The implication that locomotion provided positive input into growth control mechanisms was subjected to a direct test by evaluating the effect of nine polypeptide growth factors on the motility of serum-starved cells. All except TGF-β₁ stimulated movement. Finally, the mitogenic effect of growth factors was measured by [³H]thymidine incorporation and found to be proportional to motile activities, as quantitatively assayed. We conclude that locomotion suppression is a factor in AG1523 cell resistance to growth factor-induced mitogenesis. © 1993 Wiley-Liss, Inc.     

Gelsolin is a downstream effector of rac for fibroblast motility.

Rac, a member of the rho family of GTPases, when activated transmits signals leading to actin-based membrane ruffling in fibroblasts. Compared with wild-type fibroblasts, gelsolin null (Gsn-) dermal fibroblasts have a markedly reduced ruffling response to serum or EGF stimulation, which signal through rac. Bradykinin-induced filopodial formation, attributable to activation of cdc42, is similar in both cell types. Wild-type fibroblasts exhibit typical lamellipodial extension during translational locomotion, whereas Gsn- cells move 50% slower using structures resembling filopodia. Multiple Gsn- tissues as well as Gsn- fibroblasts overexpress rac, but not cdc42 or rho, 5-fold. Re-expression of gelsolin in Gsn- fibroblasts by stable transfection or adenovirus reverts the ruffling response, translational motility and rac expression to normal. Rac migrates to the cell membrane following EGF stimulation in both cell types. Gelsolin is an essential effector of rac-mediated actin dynamics, acting downstream of rac recruitment to the membrane.     

Acid mucopolysaccharide synthesis in the secondary palate of the developing rat at the time of rotation and fusion

The amount of hexosamines and acid mucopolysaccharides present in the rat secondary palate increases during the critical stages of palatogenesis, namely, rotation and fusion. The synthesis of acid mucopolysaccharides in vivo and in vitro in the palate was determined by the incorporation of ³H-glucosamine and Na₂S³⁵O₄. The labeled mucopolysaccharides were isolated by DEAE-cellulose chromatography and were identified on the basis of several criteria as hyaluronic acid and sulfated acid mucopolysaccharides. Hyaluronic acid accounted for approximately 60% of the total acid mucopolysaccharides synthesized in the palate both in vivo and in vitro. DON (6-diazo-5-oxonorleucine), a known inhibitor of acid mucopolysaccharide synthesis, inhibited the incorporation of ³H-glucosamine and Na₂S³⁵O₄ by palatal shelves in vitro by 70%.     

The forces behind cell movement

Cell movement is a complex phenomenon primarily driven by the actin network beneath the cell membrane, and can be divided into three general components: protrusion of the leading edge of the cell, adhesion of the leading edge and deadhesion at the cell body and rear, and cytoskeletal contraction to pull the cell forward. Each of these steps is driven by physical forces generated by unique segments of the cytoskeleton. This review examines the specific physics underlying these phases of cell movement and the origins of the forces that drive locomotion.     

Decrease by cycloheximide of calcium binding and nonesterified fatty acids in rat-intestinal Golgi-enriched membrane fractions

Rat intestinal Golgi-enriched membrane fractions bind more Ca2+ than do basolateral and microvillus-enriched membrane fractions, and this uptake is reduced by vitamin D-deficiency. The effect of the protein synthesis inhibitor, cycloheximide, on this Ca2+ binding was determined in rat fed a normal, vitamin D-sufficient diet. Cycloheximide, 1.5 mg/kg, rapidly reduced protein synthesis (measured by [3H]leucine incorporation) to 12% of control values within 15 min, but Ca2+ binding diminished gradually to 50% of control values by 60 min. Ca2+ transport across gut sacs was also decreased. The reduction in Ca2+ binding was not due to an alteration in vesicle morphology or to a direct effect of cycloheximide. Nonesterified (free) fatty acids, the probable binding sites for Ca2+ in these membrane fractions, were reduced by cycloheximide to 48% of control values by 60 min. There was no significant change in total lipid phosphate. Cycloheximide may affect the synthesis of proteins necessary for the presence of nonesterified fatty acids in these Golgi membranes.     

Effect of cycloheximide on development of methotrexate resistance of Chinese hamster ovary cells treated with inhibitors of DNA synthesis.

We examined the effects of 18 h of incubation of Chinese hamster ovary (CHO K1) cells with cycloheximide, hydroxyurea, and aphidicolin. Treatment of cells with cycloheximide alone at a concentration adequate to inhibit DNA synthesis to less than 10% of control was significantly less cytotoxic and clastogenic than treatment with hydroxyurea or aphidicolin, did not induce unbalanced cellular growth, and had no effect on the frequency of resistant cells in methotrexate selections compared with control cells. When combined with hydroxyurea or aphidicolin and compared with the effects of either drug alone, cycloheximide blocked the induction of unbalanced growth during drug treatment, reduced the frequency of chromosomal aberrations in recovering cell populations, and decreased cell killing. In addition, the increased frequency of methotrexate-resistant cells observed after treatment with hydroxyurea or aphidicolin was eliminated when cycloheximide was present during drug treatment.     

The Hurler syndrome: treatment of cultured Hurler fibroblasts with normal human serum.

Prolonged replacement of fetal calf serum by normal human serum for the enrichment of medium during tissue culture of Hurler fibroblasts resulted in increased acid mucopolysaccharides in the cells and in the medium. The predominant intracellular mucopolysaccharide had the characteristics of dermatan sulfate when Hurler cells were treated with either serum. Normal human serum contains a nonspecific coreective factor capable of augmenting the loss of 35SO4-AMPS from Hurler cells, but not from normal cells. Fetal calf serum and Hurler serum have similar corrective factor activity for labeled Hurler cells. The corrective factor activity of all three sera was recovered from reconstituted dialyzed ammonium sulfate precipitates. The corrective factor of normal human serum did not increase degradation of mucopolysaccharide, but increased secretion of macromolecular and large oligosaccharide components. Failure of the corrective factor of normal human serum to effectively decrease the dermatan sulfate content of Hurler cells during prolonged exposure may be a quantitative phenomenon due partly to the brief duration of corrective factor activity and partly to increased synthesis of mucopolysaccharide.     

Dissociation by cytochalasin B of movement, DNA synthesis and transport in 3T3 cells.

Cytochalasin B was used as a tool to study the inter-relationships between cell movement, the reinitiated DNA synthesis and the enhanced transport of specific small molecules stimulated by serum in quiescent 3T3 cells. Cytochalasin at concentrations of less than 1 mug/ml inhibits serum-stimulated movement within the monolayer and migration into a wound. Even at ten times this concentration there is little effect on the increase in DNA in the culture, indicating that movement away from neighboring cells is not required for the initiation of DNA synthesis. While DNA synthesis is not inhibited by concentrations of cytochalasin up to 10 mug/ml, the increased thymidine transport which is associated with the onset of the S phase of the cell cycle is inhibited and DNA synthesis cannot be measured by the labelling of nuclei with radioactive thymidine. Cytochalasin has a differential effect on the early transport changes produced by serum addition. Glucose transport is inhibited by low concentrations of the drug (less than 1 mug/ml) while the enhanced uptake of phosphate and uridine is unaffected by a 10-fold increase in concentration. Although the doses of cytochalasin required for 50% inhibition of hexose uptake and of cell movement are the same, no causal relationship between sugar transport and locomotion can be demonstrated. Cytochalasin affects membrane functions in at least two different ways. The drug inhibits the uptake of glucose directly but affects only the S-phase associated increase in thymidine transport.     

Influence of epidermal growth factor (EGF) on ruffling activity, pinocytosis and proliferation of cultivated human glia cells

Normal human glia cells in culture were studied with respect to ruffling activity, macro-pinocytosis and cell proliferation under standard culture conditions with 10% serum in the medium, in serum-free medium and after addition of epidermal growth factor (EGF) or serum to previously serum-free medium. Pinocytotic uptake of droplets of medium occurred only in relation to well developed ruffling membranes. Omitting the serum from the medium led to a drastic reduction in thymidine incorporation. The cells became slender under these conditions, and soon after the change of medium their ruffling activity and pinocytosis were almost completely abolished. Following the change to a medium containing 2 ng EGF/ml a rapid reappearance of ruffling and pinocytosis was observed. DNA synthesis, however, was not demonstrated until after 20 h, showing that ruffling and pinocytosis occurred before DNA synthesis had started. Thus EGF may initially induce conformational changes of the plasma membrane, resulting in its internalization due to formation of endocytotic vacuoles. The observed relationship between occurrence of well developed ruffling membranes, macro-pinocytosis and cell multiplication indicates that one of the functions of growth-promoting factors may be stimulation of plasma membrane turnover.     

Brefeldin A does not inhibit the movement of phosphatidylethanolamine from its sites for synthesis to the cell surface

Brefeldin A, a fungal metabolite which interrupts trafficking of proteins via the Golgi by causing disassembly of the Golgi stacks, has been used to investigate the mechanism of movement of phosphatidylethanolamine (PtdEtn) from its sites of synthesis to the cell surface. PtdEtn is made in hepatocytes by two major pathways, (a) from CDP-ethanolamine on the endoplasmic reticulum and (b) by decarboxylation of phosphatidylserine in mitochondria. Monolayer cultures of rat hepatocytes were incubated with radiolabeled precursors of PtdEtn ([3H]ethanolamine or [3H]serine) in the presence or absence of brefeldin A. The movement of newly made PtdEtn to the plasma membrane was studied by treatment of intact cells with trinitrobenzene sulfonate which reacted only with PtdEtn on the outside surface of the cells to produce N-trinitrophenyl-PtdEtn; PtdEtn in intracellular membranes remained underivatized by this reagent. Using this method, the incorporation of radioactivity into cell surface and intracellular PtdEtn could be differentiated. The studies showed that PtdEtn made by the two different biosynthetic routes was rapidly transported to the outside leaflet of the plasma membrane. However, the kinetics and the extent of labeling of the cell surface PtdEtn, relative to that of the intracellular PtdEtn pool, were different from each labeled precursor. The incorporation of [3H]ethanolamine into PtdEtn on the cell surface gradually increased to a constant level of 1.8% of the label of intracellular PtdEtn after 3 h. In contrast, after 0.5-1 h, cell surface PtdEtn labeled from [3H]serine comprised 4% of the intracellular PtdEtn pool; the extent of labeling gradually declined to a constant level of approximately 2.4% by 3 h. Brefeldin A did not interrupt the movement of PtdEtn, derived from either biosynthetic origin, to the cell surface even though protein secretion was greatly reduced. Thus, apparently PtdEtn and proteins are independently transported to the cell surface of hepatocytes.     

Heritability and Control of Differentiated Function in Cultured Cells

An established tissue culture cell line which retains a differentiated function in vitro is described. The cell line is of connective tissue origin, and its characteristic property is the synthesis and secretion of acid mucopolysaccharides, mainly hyaluronic acid. This differentiated cell function, the activity of which depends on continuous gene action, was found to be possessed by each of eleven clonal substrains, and is therefore a genetically heritable cell character. Rate of acid mucopolysaccharide biosynthesis falls sharply under the influence of the environmental conditions existing in crowded cultures, and this rate also declines if protein synthesis is directly inhibited with puromycin. Environmental modification of a differentiated product of gene action is thus illustrated in this study.     

An antiproliferative heparan sulfate species produced by postconfluent smooth muscle cells

Heparan sulfate was isolated form the cell surface, cell pellet, and culture medium of exponentially growing as well as postconfluent bovine aortic smooth muscle cells (SMCs). After chromatography on DEAE-Sephadex and Sepharose 4B, the various mucopolysaccharides were examined for their ability to cause growth inhibition in a SMC bioassay. The heparan sulfate isolated from the surface of postconfluent SMCs possessed approximately eight times the antiproliferative potency per cell of the heparan sulfate obtained from the surface of exponentially growing SMCs. Heparan sulfate isolated from other fractions of exponentially growing or postconfluent SMCs possesses little growth inhibitory activity. The difference in the antiproliferative activities of heparan sulfate obtained from the surface of SMCs in the two growth states could not be attributed to the synthesis of a greater mass of mucopolysaccharide by postconfluent SMCs. Indeed, heparan sulfate isolated from the surface of the postconfluent SMCs exhibits a specific antiproliferative activity which is 13-fold greater than mucopolysaccharide obtained from the surface of exponentially growing SMCs and more than 40-fold greater than commercially available heparin. In addition, exponentially growing SMCs did not exhibit an enhanced ability to degrade the complex carbohydrate. Furthermore, other investigations indicate that the small amount of growth inhibitory activity intrinsic to heparan sulfate isolated from the surface of exponentially growing SMCs is due to residual, biologically active, mucopolysaccharide produced by the primary postconfluent SMCs from which the exponentially growing SMCs were derived. These studies suggest that bovine aortic SMCs are capable of controlling their own growth by the synthesis of a specific form of heparan sulfate with antiproliferative potency.     

Interferon treatment reduced adherence, invasiveness and intracellular multiplication of Shigella flexneri in coxsackie B1 virus-infected cells.

The effect of interferon treatment on interaction of Shigella flexneri with in vitro cultured cells was investigated. Pretreatment of HEp-2 cells with human interferons had no effect on the susceptibility of cells to S. flexneri, measured by invasiveness and adhesiveness. Human leukocyte interferon and human recombinant interferon-alpha-A reduced adhesiveness, intracellular multiplication and invasiveness of S. flexneri in HEp-2 cells preinfected with coxsackie B1 virus. Also non-receptor mediated-phagocytosis was reduced by interferon treatment in virus infected cells. The interferon effects were dependent on continuous protein synthesis, because they were not expressed when cycloheximide or abrin was added to the virus infected cell cultures. No effect of interferon was detected on intracellular content of Na+ or K+, Na(+)-K+ activated ATPase activity or cytoplasma membrane polarity, in virus infected or control cell cultures. The interferon effect on bacterial invasiveness seems to be dependent on an interferon receptor interaction on cytoplasma membrane level because directly microinjected interferon showed no effect.     

Impaired cell motility in chronic myeloid leukemic granulocytes related to altered cytoskeletal pattern

The bactericidal activity of polymorphonuclear leucocyte (PMNL) against infection stimulates cytoskeletal changes accompanied with alteration in adhesion and locomotion. Microfilaments, the motile apparatus is known to regulate these changes by polymerization of monomeric G-actin to fibrous F-actin. PMNL from chronic myeloid leukemia (CML) patients have been reported to be defective in locomotion in response to synthetic peptide, n-formyl-methionyl-leucyl-phenylalanine (fMLP) but the mechanism leading to defective locomotion and their spatial reorganization remains unclear. Therefore, in order to study the cause of defective motility of PMNL from CML patients the spatial distribution and reorganization of microfilaments and microtubules in response to fMLP have been examined by transmission electron (TEM) and scanning electron microscopy (SEM). Under SEM, the PMNL-CML surface appeared smoother with reduced ruffling resulting in rounding off cells with lesser polarized morphology. Unstimulated PMNL from normal as well as CML subjects showed shorter and fewer microtubules and evenly distributed microfilaments as compared to fMLP stimulated PMNL. It is proposed that the cause of defective locomotion was due to reduced surface activity as a consequence of altered cytoskeletal configuration. This phenomenon seems to be related to impaired functional appendages and as a whole led to the defective cell motility and hence reduced chemotaxis in PMNL from CML patients.     

Regulation of cell contraction and membrane ruffling by distinct signals in migratory cells.

Cell migration and wound contraction requires assembly of actin into a functional myosin motor unit capable of generating force. However, cell migration also involves formation of actin-containing membrane ruffles. Evidence is provided that actin-myosin assembly and membrane ruffling are regulated by distinct signaling pathways in the migratory cell. Interaction of cells with extracellular matrix proteins or cytokines promote cell migration through activation of the MAP kinases ERK1 and ERK2 as well as the molecular coupling of the adaptor proteins p130CAS and c-CrkII. ERK signaling is independent of CAS/Crk coupling and regulates myosin light chain phosphorylation leading to actin-myosin assembly during cell migration and cell-mediated contraction of a collagen matrix. In contrast, membrane ruffling, but not cell contraction, requires Rac GTPase activity and the formation of a CAS/Crk complex that functions in the context of the Rac activating protein DOCK180. Thus, during cell migration ERK and CAS/Crk coupling operate as components of distinct signaling pathways that control actin assembly into myosin motors and membrane ruffles, respectively.     

Disappearance of acid mucopolysaccharides from the cell coats in mitosis-induced mouse liver

Summary The cell coat acid mucopolysaccharide detected by the Mowry's staining was found to disappear temporarily in the liver of mice which were treated with i.p. injection of papain to induce the active mitosis. Similar phenomenon was also observed for the regenerating liver after partial hepatectomy. ³H-Glucosamine which had been incorporated into the liver cell coats was found to disappear after i.p. injection of papain (autoradiography). Acid mucopolysaccharide isolated from the liver plasma membranes was found preliminarily to be more closely related to heparitin sulfate than other reference acid mucopolysaccharides.