Aggregation of microtubule initiation sites preceding neurite outgrowth in mouse neuroblastoma cells.

By examining microtubule regrowth using immunofluorescence with antibody to tubulin, we have studied the structure and intracellular localization of microtubule initiation sites in undifferentiated and differentiated mouse neuroblastoma cells. The undifferentiated cells are round and lack cell processes. They contain an average of 12 initiation sites per cell. Each of these sites, which are located near the cell nucleus, initiates the growth of several microtubules in a radial formation. In contrast to the undifferentiated cells, neuroblastoma cells stimulated to differentiate by serum deprivation are asymmetrical, containing one or two very long neurites. These cells have a single, large microtubule initiation center which can be visualized not only by immunofluorescence but by phase-contrast and differential interference microscopy as well. The initiation site measures 3-4 mu in diameter and is located in the cell body along a line defined by the neurite. During cell differentiation, the large initiation, the large initiation center seems to be formed by the aggregation of many smaller sites. This process procedes neurite extension by about 24 hr. The growth of microtubules from this center appears to be highly oriented, since most microtubules initially grow into the neurite processes rather than into the cell interior. Thus major changes in the structure and location of microtubule initiation sites occur during the differentiation of neuroblastoma cells. Similar changes are likely to be involved in alterations in the morphology of other cell types.     

Influence of ganglion age,nonneuronal cells and substratum on neurite outgrowth in culture

This study characterizes the outgrowth patterns of superior cervical ganglia (SCG) obtained from embryonic (E15), perinatal (E20–21), and adult (P35) rats when placed in culture on various substrata. Outgrowth morphology, degree of fasciculation, and outgrowth length were examined on collagen (COL), polyornithine (PO), polylysine (PL), fibronectin (FN), and nonneuronal cells (NNCs) from the ganglion. COL and FN supported extensive neuritic outgrowth; PO and PL provided poor support. Outgrowth pattern, degree of fasciculation, neurite growth rate, and the number of NNCs in the outgrowth varied considerably depending upon the COL configuration. When undiluted COL (～5 mg/ml) was air dried, a three-dimensional loose fibrillar network was formed. Upon COL dilution or gelling undiluted COL by ammoniation, an essentially two-dimensional layer was formed. On two-dimensional COL, NNCs were able to proliferate and migrate extensively from ganglia of all ages; their presence influenced the form and extent of neurite growth. E15, E20, and P35 neurites responded differently to their endogenous NNCs. E15 neurites extended in relation to NNC surfaces and were predominantly nonfasciculated. E20 neurites became more fasciculated in the presence of NNCs that exhibited morphological and behavioral differences from those migrating from E15 ganglia. E20 neurite bundles became defasciculated when they extended into E15 outgrowth. Far fewer neurites grew from P35 explants in the presence of their NNCs. Three-dimensional COL greatly slowed NNC migration and thus allowed investigation of neurite outgrowth from ganglia of differing age in the absence of NNCs. We conclude that neuritic outgrowth patterns on varying substrata reflect not only neurite differences depending upon ganglion age but also variation in the behavior of accompanying NNCs.     

Nerve growth factor-mediated induction of tyrosine hydroxylase and of neurite outgrowth in cultures of bovine adrenal chromaffin cells: dependence on developmental stage

Adrenal medullary cells were cultured in a serum-free medium from fetal, neonatal (calves), and adult bovine animals. Neurite outgrowth in response to nerve growth factor (NGF) was observed in cells obtained from fetuses up to a gestational age of 3 months but not in cultures from older animals. The tyrosine hydroxylase (TH) specific activity was found to depend on the cell density and corresponded, at a density of 2 × 10⁵ cells/cm², to the specific activity found in vivo. The TH specific activity increased about sevenfold from fetuses to adult animals. Administration of NGF in vitro caused an increase of the TH specific activity in fetal cells by up to 140% and in calf cells typically by 70–100%. Cultures from adult animals showed no significant TH increase in response to NGF. Scatchard analysis and kinetic studies of the NGF binding at 0°C to intact adrenal medullary cells cultured from calves or from adult bovine animals revealed the presence of only one class of receptors, having a dissociation constant (K_D) of 1 × 10 ⁹, M. There are 16,000 binding sites per cell. The affinity of the reeptors in vivo (determined in crude membrane preparations) did not alter during development, whereas the receptor density decreased with increasing fetal age, but was the same for calves and adults. Whereas the loss of NGF-mediated fiber outgrowth during development might be related to the reduction of receptor density, the disappearance of the NGF-mediated TH induction does not correlate with changes in the binding characteristics of NGF to the adrenal chromaffin cells.     

Regulation of fibronectin biosynthesis by glucocorticoids in human fibrosarcoma cells and normal fibroblasts

When treated with the synthetic glucocorticoid dexamethasone, HT1080 human fibrosarcoma cells show changes in morphology, adhesion, and the extracellular matrix. Dexamethasone treatment results in a tenfold increase in the rate of fibronectin biosynthesis in HT1080 cells and a twofold increase in untransformed, normal human fibroblasts. Maximal induction levels are attained within one cell generation, while decay of the response requires several cell cycles. Pulse-chase studies showed that most of the newly synthesized fibronectin is secreted into the medium. The glucocorticoid antagonist, RU-486, blocks the dexamethasone-induced changes but does not alter the basal rate of fibronectin production. Therefore, fibronectin biosynthesis appears to be controlled by two distinct mechanisms--one, regulating basal rates of fibronectin production, which is transformation-sensitive and glucocorticoid-independent; and another, which is mediated by the glucocorticoid receptor, resulting in elevated rates of fibronectin biosynthesis upon dexamethasone treatment both in normal fibroblasts and in HT1080 cells.     

Fluid-phase interaction between human plasma fibronectin and gelatin determined by fluorescence polarization assay

Previous studies of the binding properties of fibronectin (Fn) have utilized methods whereby one or the other macromolecule was immobilized on a solid phase. In order to examine the interaction between human plasma Fn and gelatin in solution, the latter was labeled with fluorescein isothiocyanate (FITC) whose fluorescence polarization (P) served as a sensitive indicator of the formation of soluble complexes. Changes in P were detectable at Fn concentrations below 10(-9) M and continued up to concentrations above 10(-6) M at pH 7.3 and 25 degrees C. Fractionation of FITC-gelatin by exclusion chromatography and titration of selected fractions revealed a trend towards higher affinity with increasing size. A high-molecular-weight fraction comprised of beta and gamma components and a low-molecular-weight fraction comprised primarily of alpha chains exhibited sigmoidal increases in P (apparent positive cooperativity) with 50% saturation near 10(-9) and 10(-8) M Fn, respectively. By contrast, a 42-kDa chymotrypsin-generated Fn fragment which retains the ability to adhere to gelatin-Sepharose exhibited normal (noncooperative) binding to both gelatin fractions with Kd = 7 X 10(-7) M. In all cases, the increase in P could be reversed by addition of excess unlabeled gelatin or urea. The interaction of FN with FITC-gelatin provides the basis for a fast and sensitive determination of Fn levels in plasma and other fluids. Interference caused by other proteins such as albumin, which has an affinity for the fluorescein moiety, could be minimized by addition of 1.0 M NaCl which had no effect on the interaction between Fn and gelatin.     

DNA-binding domains of fibronectin probed using Western blots

Human plasma fibronectin was subjected to limited proteolysis, and its DNA-reactive polypeptides were distinguished using the protein blot technique. The polypeptides were separated electrophoretically by SDS gel electrophoresis, transferred to nitrocellulose and probed with radiolabeled human lymphocyte DNA. The major DNA-binding domains identified by the protein blots were comparable to the polypeptides identified using affinity chromatography on DNA-cellulose.     

Reversibility of monensin inhibition of oligosaccharide processing of human fibronectin

Monensin impairs oligosaccharide processing in fibronectin primarily by inhibiting the conversion of oligosaccharides from the high mannose type to the complex type. The separate effects of monensin and cations on alpha-mannosidase activity in fibroblasts were examined using an in vitro assay system. The results indicated that monensin did not directly inhibit alpha-mannosidase activity in vitro, although prior treatment of fibroblasts with monensin caused an irreversible suppression of enzyme activity. The reversibility of monensin action on oligosaccharide processing was also examined. Analyses using concanavalin A (ConA) Sepharose affinity chromatography showed that the inhibitory action of monensin on oligosaccharide processing was biologically reversible. A progressive return to complex type oligosaccharides began about 11 h after the removal of the monensin. These composite results indicate that the reversibility of monensin action on oligosaccharide processing in fibronectin may be attributed to the restoration of enzyme activity, although the mechanism by which restoration occurs remains to be deciphered.     

Electron spin resonance spin label studies of plasma fibronectin: effect of temperature

Plasma fibronectin was chemically modified by 4-maleimido-2,2,6,6-tetramethylpiperidinooxyl (maleimide spin label). Only the free sulfhydryl groups of plasma fibronectin were modified by the label under the experimental conditions. The ESR spectrum of spin-labeled fibronectin showed that the sites of labeling were highly immobilized, suggesting that the sulfhydryl groups of the protein are in small, confined environments. The conversion of the strongly immobilized ESR spectrum into a weakly immobilized one was observed when the spin-labeled protein was heated from 30 to 60 degrees C, indicating the thermal unfolding of the protein molecules. The midpoint temperature for the thermal unfolding of plasma fibronectin is about 50 degrees C. The results suggest that plasma fibronectin is stable to about 40 degrees C and starts unfolding above this temperature. The rotational correlation time estimated from the ESR spectrum of spin-labeled fibronectin at 21 degrees C was about 2.0 X 10(-8) s. The rotational correlation time calculated from the Stokes-Einstein equation, assuming a rigid globular configuration for fibronectin with a Stokes radius of 10 nm, was about 7.8 X 10(-7) s. The differences in rotational correlation time by a factor of 39 between experimental and calculated values do not support a globular configuration for plasma fibronectin.     

Oriented axon outgrowth from avian embryonic retinae in culture

The neural retina of avian embryos was spread on a membrane filter and cut in any desired orientation. Strips cut across the retina of 4- to 7-day chick or 3- to 6-day quail embryos were explanted onto collagen gels. Vigorous neurite outgrowth was seen for about 3 days, by which time many neurites were 3 mm long. Horseradish peroxidase (HRP) labeling showed that the cells producing the neurites were large and formed a layer near the inner limiting membrane, indicating that the neurites in vitro were axons of retinal ganglion cells. The size of the neurite population and the regions from which neurites emerged vaired with the donor age, while most neurites sprouted from the side of the explant formerly closest to the optic fissure. This pattern closely resembled that of axon growth in the normal retina, as revealed by SEM, silver staining, and HRP labeling. Mitotic inhibitors (Ara-C and FUdR) did not alter the neurite outgrowth. Pretreatment of retinae with trypsin or collagenase did not disorganize axons at the time of explantation, but tended to equalize neurite emergence on each side of the retinal strips. We suggest that microenvironmental factors, especially the enzyme-labile inner limiting membrane, are important for axon guidance in the retina.     

Cholera toxin does not prevent neurite outgrowth from adult human chromaffin cells in culture

Adult human adrenal medullary cells were dissociated and cultured for 14 days in the presence or absence of cholera toxin (CT), an activator of adenyl     

Structural alterations in fibronectin correlated with morphological changes in smooth muscle cells

Nontransformed cultures of vascular smooth muscle cells proliferate until they form a confluent sheet of cells. Subsequently, the cells become reorganized to form multicellular nodules that are loosely attached to the substrate. The formation of nodules is facilitated by the addition of medium conditioned by nodular cultures. Nodulation is inhibited by the addition of fibronectin. Fibronectins derived from monolayer culture conditioned medium or from plasma are maximally effective while fibronectin isolated from nodular cell conditioned medium is inactive. Analysis by NaDodSO4-polyacrylamide gel electrophoresis reveals that the nodular cell fibronectin has a molecular weight that is about 20-30 kd less than that of monolayer cell fibronectin. Further, nodular cell conditioned medium contains an activity that can convert both plasma fibronectin and monolayer cell fibronectin to the lower molecular weight correlated with the loss of biological activity.     

Cross-linking of fibronectin to sulfated proteoglycans at the cell surface.

Fibronectin is a major surface protein of normal animal cells but is absent from many transformed cells. Addition of fibronectin to transformed cells causes increased cell substrate adhesion and changes in the morphology and cytoskeleton of the cells. We have coupled fibronectin to photoactivable chemical cross-linkers and have added it to cells to identify those molecules to which it binds. In this way, fibronectin can be cross-linked to sulfated proteoglycans at the cell surface. The cross-linking is specific for fibronectin. The fibronectin-proteoglycan complex is sensitive to chondroitinase ABC and AC and to trypsin. Addition of fibronectin also affects binding of hyaluronic acid to the cells. These results suggest that fibronectin interacts with proteoglycans at the cell surface. The existence of such interactions may have implications for the role of fibronectin and proteoglycans in cell adhesion.     

Actions of guanidinoethane sulfonate on taurine concentration,retinal morphology and seizure threshold in the neonatal rat

Administration of the taurine transport inhibitor, guanidinoethane sulfonate (GES) to pregnant rats depleted taurine concentrations to approximately one-half of normal values in the newborn progeny. By 5 days of age taurine concentrations had returned to normal in all organs tested with the exception of the lungs. Longer postnatal exposure to GES significantly depressed tissue taurine levels. Prenatal exposure to GES had no effect on fetal development or the capability of the newborn rat to biosynthesize or transport taurine. Pre- and postnatal exposure to GES produced a degeneration of the photoreceptor layer of the retina similar to that observed in cats fed a taurine deficient diet. The pentylene tetrazole chemoshock threshold in GES-treated pups was greater than that in control pups. These results indicate that prenatal exposure to GES deplete taurine concentrations in the newborn rat. Morphological changes are thereby produced in the retina of rat that are similar to those observed in animals having limited ability to synthesize taurine which are maintained on a taurine-free diet.     

Effects of cultured astroglia on the survival of neonatal rat retinal ganglion cells in vitro

Retinal ganglion cells (RGC), as identified by retrograde horseradish peroxidase (HRP) labeling technique, were cultured in a minimal medium; only 20% of them survived after 16 hr in vitro. However, superior colliculus-conditioned medium was capable of supporting 100% of RGC over this assay time; enhanced neurite expression also was evident. It was decided to investigate whether glial cells within the superior colliculus may provide a soluble factor capable of supporting RGC. Glial-conditioned medium prepared over monolayers of either predominantly flat astrocytes (relatively immature) or predominantly process-bearing (mature) astrocytes failed to maintain RGC. The possibility that astrocytes may provide support for RGC via membrane contact was then investigated. Dissociated retinae were grown on monolayers consisting primarily of either flat or process-bearing astrocytes. Cultures rich in flat astrocytes maintained over 70% of RGC originally present, and many of them exhibited extensive neurite outgrowth and elongation. Process-bearing astrocytes were unable to support RGC survival. Immature astroglial cells may therefore support RGC via glial-neuronal interaction.     

Regulation of glutamate dehydrogenase by palmitoyl-coenzyme A

Glutamate dehydrogenase is inhibited more by palmitoyl-CoA when the reduced form of triphosphopyridine nucleotide instead of the reduced form of diphosphopyridine nucleotide is the coenzyme. Inhibition is further enhanced by α-ketoglutarate and malate. Thus, for example, in the presence of TPNH plus malate, the amount of palmitoyl-CoA required for 50% inhibition is 10-fold lower (0.03 μm) than previously reported values obtained with reduced diphosphopyridine nucleotide as a coenzyme. Allosteric modifiers such as ATP, GTP, and leucine decrease inhibition of glutamate dehydrogenase by palmitoyl-CoA. Palmitoyl-CoA and ADP are competitive. Thus, the palmitoyl-CoA binding site is apparently in the vicinity of the site of these allosteric modifiers and is probably at the ADP site. The fact that ADP (which has only one site per polypeptide chain) can completely prevent inhibition by palmitoyl-CoA suggests that there is only one kinetically significant palmitoyl-CoA binding site per polypeptide chain. This is consistent with the fact that adding one equivalent of palmitoyl-CoA per polypeptide chain inhibits about 80%. The high affinity of glutamate dehydrogenase for palmitoyl-CoA enables it to successfully compete with other mitochondrial proteins for palmitoyl-CoA.     

Mechanism of tyrosine hydroxylase activation by phosphorylation

It was found that the fluorescence of 1,N⁶-ethenoadenosine triphosphate (ε-ATP) bound to myosin subfragment-1 (S-1) is resistant to quenching by acrylamide, while free ε-ATP is effectively quenched. Thus in the presence of acrylamide the bound ε-ATP is still highly fluorescent, while free ε-ATP is much less fluorescent. The Stern-Volmer constants of bound and free ε-ATP are 6.83 and 57.86 M^?1, respectively. Therefore it is easy to distinguish spectro-scopically the nucleotide-ligated S-1 from nucleotide-free S-1. Moreover acrylamide does not alter the S-1-Mg²⁺-ε-ATPase behavior.     

Analysis of self-association of bovine neurophysins by gel chromatography

Analytical gel chromatography has been used to examine self-association of bovine neurophysins I and II under several sets of conditions. The data provide no evidence for associated species larger than the dimer. Association constants and Stokes radii of both monomer and dimer are very similar for both proteins in both 0.1 M KOAc, 0.16 M KCl and 0.1 M KPO4, 0.16 M KCl at pH 5.6 and 25 degrees C. The average values derived for the Stokes radii of the monomer and dimer under these conditions are 14.5 +/- 0.7 and 23.0 +/- 0.4 A, respectively. These results confirm the conclusion of Rholam and Nicolas [(1981) Biochemistry 20, 5837-5843] that the monomer and, to a lesser extent, the dimer are highly assymmetric. The Stokes radius of the monomer calculated by Rholam and Nicolas (op cit.) is approximately 30% larger than the value derived here. This discrepancy is probably the result of end-on penetration of the gel by elongated molecules [Y. Nozaki, N. M. Schechter, J. A. Reynolds, and C. Tanford (1976) Biochemistry 15, 3884-3890]. In contrast to Tellam and Winzor [(1980) Arch. Biochem. Biophys. 201, 20-24], it was found that neurophysin II does not exist solely as the dimer in 0.1 M KPO4, pH 5.6, although substitution of 0.1 M KPO4 for 0.1 M KOAc does increase the association constant by a factor of seven. Addition of 1.4 M LiCl at pH 8.1 also increases the association constant sevenfold, as well as increasing the Stokes radius of the monomer approximately 20%. The effects of ionic strength are consistent with the conclusion of Nicolas et al. [(1978) J. Biol. Chem 253, 2633-2639] that formation of the dimer depends upon hydrophobic bonding.     

Inactivation of mitochondrial ATPase by ultraviolet light

The present work describes experiments that show that far-ultraviolet irradiation induce the inhibition of ATPase activity in both membrane-bound and soluble F1. It was also found that ultraviolet light promotes the release of tightly bound adenine nucleotides from F1-ATPase. Experiments carried out with submitochondrial particles indicate that succinate partially protects against these effects of ultraviolet light. Titration of sulfhydryl groups in both irradiated submitochondrial particles and soluble F1-ATPase indicates that a conformational change induced by photochemical modifications of amino acid residues appears involved in the inactivation of the enzyme. Finally, experiments are described which show that the tyrosine residue located in the active site of F1-ATPase is modified by ultraviolet irradiation.     

Colorimetric determination of agarose-immobilized proteins by formation of copper-protein complexes

A simple, reliable, and sensitive colorimetric procedure for the determination of proteins bound to agarose is described. The procedure utilizes the capacity of diethyldithiocarbamate to react with cupric ions resulting in a complex of dark yellow color. The extent of reduction in the color, due to chelation of Cu2+ by the immobilized proteins, indicates the amount of protein. The optimum conditions for the determination of immobilized proteins are investigated. The formation of Cu2+-protein complex proceeds stepwise until enough excess of Cu2+ is present to form the final complex. The reliability of the procedure requires that all the protein species, samples and standards, are in the final Cu2+-protein complex form. A comparative study on the determination of different proteins bound to agarose using this method as well as other methods, such as protein balance, modified Lowry reaction, and direct ultraviolet spectrophotometry, is described. The method is substantially more reliable, accurate, and simple than previously described methods.