Effect of tunicamycin on the glycosylation of rhodopsin

The incorporation of [³H]glucosamine, [³H]mannose, and [³⁵S]methionine into rhodopsin was investigated in retinas which had been incubated in the presence and absence of the antibiotic, tunicamycin. In its presence, the incorporation of glucosamine was inhibited 70% and mannose, 96% compared to controls. In the presence of tunicamycin the attachment of glucosamine to core-region sites was virtually eliminated. The formation of unglycosylated rhodopsin was also indicated by sodium dodecyl sulfate-polyacrylamide gel electrophoresis and concanavalin A-Sepharose chromatography. These findings are consistent with the participation of the lipid-linked pathway in the glycosylation of this well-characterized intrinsic glycoprotein of the membranes of the disk of the rod outer segment. As indicated by the incorporation of [³⁵S]methionine, the synthesis of rhodopsin apoprotein was inhibited by a much lesser amount. This suggests that the glycosylation of rhodopsin is not required for its insertion into the disk membrane.     

The effect of castanospermine on the synthesis of synaptic glycoproteins by rat brain slices

Slices were prepared from rat forebrains and the incorporation of [³H]mannose and [³⁵S]methionine into proteins and glycoproteins determined. The incorporation of methionine continued to increase for up to 8 hours whereas mannose incorporation was maximal between 2 and 4 hours and declined thereafter. Glycopeptides prepared by pronase digestion of [³H]mannose-labeled glycoproteins were digested with endoglucosaminidase H (endo H) and analysed by gel filtration. The major endo H-sensitive oligosaccharide eluted in a position similar to standard Man₈GlcNAc. In the presence of castanospermine, which inhibits glucosidase I, the first enzymatic step in the processing of N-linked oligosaccharides, a new endo H-sensitive glycan similar in size to standard Glc₃Man₉GlcNAc₂ accumulated. Synaptic membranes (SMs) were isolated from slices which had been incubated with either [³H]mannose or [³⁵S]methionine in the presence and absence of castanospermine. In the presence of inhibitor the relative incorporation of [³H]mannose into high-mannose glycans of synaptic glycoproteins was increased. The incorporation of newly synthesized, [³⁵S] methioninelabeled, Con A-binding glycoproteins into SMs was not affected by the addition of inhibitor. Many of the glycoproteins synthesized in the presence of castanospermine exhibited a decreased electrophoretic mobility indicative of the presence of altered oligosaccharide chains. The results indicate that changes in oligosaccharide composition produced by castanospermine had little effect on the subsequent transport and incorporation of glycoproteins into synaptic membranes.To whom to address reprint requests.     

Metabolism of [2-3H]- and [6-3H]-nicotinic acid in intact Nicotiana tabacum plants

Earlier observations of Dawson on the relative incorporation of [2-³H]- and [6-³H]-nicotinic acid into nicotine have been confirmed in intact Nicotiana tabacum plants. All the tritium in the nicotine derived from [2-³H]-nicotinic acid was located at C-2 of the pyridine ring. However the radioactive nicotine derived from [6-³H]-nicotinic acid was not labelled specifically at C-6 with tritium. By carrying out feeding experiments with [6-¹⁴-C, 2-³H]- and [6-¹⁴C, ³H]-nicotinic acids, it was established that there was very little loss of tritium from C-2 and C-6 of nicotinic acid during 5 days of metabolism in the tobacco plant.     

The effect of tunicamycin on development of the mammalian embryonic pancreas

The role of cell-surface glycoproteins in histogenesis of the embryonic rat pancreas was investigated by studying the effect of tunicamycin (TM) on in vitro development. TM has been shown to block glycosylation of asparagine residues in glycoproteins by inhibiting formation of dolichol oligosaccharide intermediates. Exposure of Day 15 pancreatic rudiments to 1.0 μg TM/ml for 15 or 24 hr inhibited [³H]mannose, [³H]glucosamine, and [³H]fucose incorporation by 95, 85, and 90%, respectively, while [³H]leucine incorporation was reduced by 35%. Similar results were obtained with Day 17 rudiments. These trends were confirmed using sodium dodecyl sulfate-polyacrylamide slab gel electrophoresis and fluorography. Inhibition of [³H]monosaccharide incorporation correlated with reduced binding of RCA I-ferritin conjugates to the cell surface and both effects of TM were reversed by reculturing rudiments in medium lacking the antibiotic. Morphologically, TM treatment resulted in a delay in pancreatic histogenesis and this delay correlated with an inhibition of the normal increase in specific activity of amylase, an acinar cell secretory protein. These effects were not mimicked by treatment with cycloheximide at a concentration which inhibited [³H]leucine incorporation to the same degree observed with TM. The percentage of delayed rudiments decreased as reculturing in the absence of TM was extended.     

The fermentation of xylose: studies by carbon-13 nuclear magnetic resonance spectroscopy

Summary The fermentation ofd-xylose byPachysolen tannophilus, Candida shehatae, andPichia stipitis has been investigated by¹³C-nuclear magnetic resonance spectroscopy of both whole cells and extracts. The spectra of whole cells metabolizingd-xylose with natural isotopic abundance had significant resonance signals corresponding only to xylitol, ethanol and xylose. The spectra of whole cells in the presence of [1-¹³C]xylose or [2-¹³C]xylose had resonance signals corresponding to the C-1 or C-2, respectively, of xylose, the C-1 or C-2, respectively, of xylitol, and the C-2 or C-1, respectively, of ethanol. Xylitol was metabolized only in the presence of an electron acceptor (acetone) and the only identifiable product was ethanol. The fact that the amount of ethanol was insufficient to account for the xylitol metabolized indicates that an additional fate of xylitol carbon must exist, probably carbon dioxide. The rapid metabolism of xylulose to ethanol, xylitol and arabinitol indicates that xylulose is a true intermediate and that xylitol dehydrogenase catalyzes the reduction (or oxidation) with different stereochemical specificity from that which interconverts xylitol andd-xylulose. The amino acidl-alanine was identified by the resonance position of the C-3 carbon and by enzymatic analysis of incubation mixtures containing yeast and [1-¹³C]xylose or [1-¹³C]glucose. The position of the label from both substrates and the identification of isotope also in C-1 of alamine indicates flux through the transketolase/transaldolase pathway in the metabolism. The identification of a resonance signal corresponding to the C-1 of ethanol in spectra of yeast in the presence of [1-¹³C]xylose and fluoroacetate (but not arsenite) indicates the existence of equilibration of some precursor of ethanol (e.g. pyruvate) with a symmetric intermediate (e.g. fumarate or succinate) under these conditions.     

Effects of ADP, ethanol and acetaldehyde on the relaxing complex of human muscle and its adsorption by polystyrene particles.

Protoplasts of Saccharomyces strain 1016 took up [³H]glucosamine in the presence of an energy source; mannose was chosen to minimize randomization. It accumulated in the soluble intracellular pool primarily as UDP-N-acetyl[³H]glucosamine along with a small amount of [³H]glucosamine 6-phosphate. The antibiotic tunicamycin (TM) at 10 μg/ml did not affect the levels of these metabolites or inhibit the formation of the Nacetylglucosamine polymer, chitin, but did prevent the incorporation of [³H]glucosamine into mannan peptides and the synthesis of invertase. In vitro incorporation of [¹⁴C]mannose from GDP-[¹⁴C]mannose into mannan in a membrane preparation was not sensitive to 100 μg of TM/ml. TM appears to inhibit an N-acetylglucosaminyl transferase essential for glycoprotein biosynthesis. Binding of [³H]TM reflects its association with the plasma membrane fraction. This material could be recovered in an unaltered form by extraction with chloroform/methanol. If 0.2% phosphatidyl choline or phosphatidyl serine was added simultaneously with the [³H]TM, the binding of [³H]TM was greatly reduced, and the inhibitory effects of TM on protoplasts were prevented; however, addition of phospholipid 20 min later did not eliminate the inhibition, although about 80% of the bound [³H]TM was removed. TM interacts with lipophilic membrane components as well as inhibiting glycoprotein synthesis.     

The hormonal control of protein N-glycosylation in the developing rabbit mammary gland and its effect upon transferrin synthesis and secretion

Pregnant rabbit mammary gland explants cultured with insulin, prolactin and cortisol, synthesise and secrete transferrin radiolabelled with [³H]leucine or [³H]mannose. Omission of prolactin from the culture medium inhibited the incorporation of [³H]leucine into casein but not transferrin. Total transferrin secreted under these conditions was approx. 75% of the control (+ prolactin) value measured by rocket immunoelectrophoresis. Little incorporation of [³H]mannose into transferrin was seen in the absence of prolactin suggesting a lack of glycosylation of the protein. Dual label experiments with [³H]mannose and [¹⁴C]leucine confirmed this. The decreased incorporation of [³H]mannose into dolichol linked intermediates suggests a general effect on protein N-glycosylation in the absence of prolactin. Thus, while the synthesis of the polypeptide backbone of transferrin does not require prolactin its glycosylation does.     

Enzymatic transfer of mannose from guanosine diphosphate mannose to yeast mannan-protein complexes

The radioactive products derived from transfer of [¹⁴C]mannose residues from GDP-[¹⁴C]mannose to endogenous acceptors of a Hansenula holstii particulate enzyme preparation have been solubilized by Pronase digestion. From this soluble mixture, glycopeptides containing [¹⁴C]mannose have been purified and have been shown by β-elimination-reduction experiments to contain radioactive mannose and oligosaccharides of mannose linked to serine and threonine residues. Radioactive macromolecular complexes of mannan-protein were extracted from the particulate enzyme fraction with hot, neutral citrate buffer. These components contained variable quantities of protein, mannose, and phosphate. The more neutral components were reduced in size by Pronase digestion and yielded glycopeptides similar to those obtained by direct Pronase digestion of the particulate fraction.     

Effect of divalent metal ions on the synthesis of oligosaccharide side chains of Neurospora crassa glycoproteins

Neurospora crassa membrane preparations incorporated mannose from GDP-mannose-[¹⁴C] in the presence of Mg²⁺ into a polyprenol lipid and side chains of protein acceptor(s), which are labile on hydrolysis in weak base. The addition of Mn²⁺ to the reaction mixtures does not affect mannosyl lipid synthesis but it stimulates the transfer of mannose to larger oligosaccharide chains resistant to β-elimination and the transfer of a second mannosyl unit to form an O-glycosidically linked mannobiosyl side chain. Incubation of particulate preparations with polyprenol-mannose-[¹⁴C] in the presence of Mg²⁺ and Mn²⁺ also results in the transfer of a single mannose to the protein. When non-radioactive GDP-mannose is added to this reaction mixture, however, β-elimination yields mannobiose. The mannobiose is labeled in the reducing sugar only. These results indicate that the first mannose of this mannobiosyl side chain is transferred via a lipid intermediate, but the second mannose is transferred directly from GDP-mannose. In the presence of Mg²⁺ and Mn²⁺, mannose apparently is also transferred from polyprenol-mannose-[¹⁴C] to side chains which are resistant to hydrolysis.     

Polyprenol phosphates and mannosyl transferases in Phaseolus aureus

The transfer of mannose from GDP[¹⁴C]mannose to lipid and to insoluble polymer by a particulate preparation of Phaseolus aureus has been investigated. The evidence favours the lipid being a prenol phosphate mannose. Of a range of prenol phosphates tried, betulaprenol phosphate was the most effective exogenous acceptor of mannose. Most of the insoluble [¹⁴C]polymer formed was glycoprotein in nature although small quantities of ¹⁴C were associated with glucomannan and galactoglucomannan fractions. Time studies failed to reveal a typical precursor-product relationship between the lipid and polymer fractions but on incubation of [¹⁴C]mannolipid with the particulate fraction a small transfer (0·5–0·7%) of [¹⁴C] to polymer was detected. p-Hydroxymercuribenzoate inhibited (by 90%) the transfer of [¹⁴C] from GDP[¹⁴C]-mannoseto polymer and simultaneously increased (3-fold) the [¹⁴C] recovered in the lipid fraction. The effect was nullified by mercaptoethanol. Attempts to solubilize the transfer system were only partially successful. The formation of a chromatographically identical mannolipid was demonstrated in particulate fractions of Codium fragile and tomato roots.     

The high mannose oligosaccharide of phytohemagglutinin is attached to asparagine 12 and the modified oligosaccharide to asparagine 60

Phytohemagglutinin, the lectin of the common bean Phaseolus vulgaris, has a high mannose and a modified (fucosylated) oligosaccharide on each polypeptide. Fractionation by high performance liquid chromatography of tryptic digests of [³H]fucose or [³H]glucosamine labeled phytohemagglutinin, followed by amino acid sequencing of the isolated glycopeptides, shows that the high mannose oligosaccharide is attached to Asn¹² and the modified oligosaccharide to Asn⁶⁰ of the protein. In animal glycoproteins, high mannose chains are rarely found at the N-terminal side of complex chains.     

Biosynthesis and characterization of large dolichyl diphosphate-linked oligosaccharides in Sacchromyces cerevisiae

Yeast membranes incorporate radioactivity from GDP[¹⁴C]mannose into various glycolipids. These can be separated by thin layer chromatography into at least seven components.The major component has been identified previously as dolichyl monophosphate mannose. Only one additional component is not sensitive to mild alkaline saponification, but is hydrolyzed instead under mild acidic conditios. This latter glycolipid has all the characteristics of a polyprenyl diphosphate oligosaccharide with a sugar moiety of more than 12 hexose units. It runs like dolichyl diphosphate derivatives on a DEAE column and evidence is presented that the lipid moiety is a polyprenol.When radioactive Dol-PP-di-N-acetylchitobiose is incubated with yeast membranes in the presence of non-radioactive GDPmannose a small amount of a larger lipid oligosaccharide is formed besides the previously-described Dol-PP-(GlcNAc₂ mannose. This oligosaccharide has all the properties of the glycolipid described above. Its formation is greatly increased when Triton is omitted from the incubation. Radioactivity of the polyprenyl diphosphate [¹⁴C]oligosaccharide is transferred to ethanol-insoluble material, most likely endogenous membrane glycoproteins.     

Glycosylation of nascent polypeptide chains in Aspergillus niger

Polysomes were isolated from Aspergillus niger and were characterized on sucrose gradients in several ways. First, they were found to be susceptible to degradation by treatment with RNase or EDTA. Second, they were labeled after treating mycelia with short pulses of [³H]uridine or [³H]leucine prior to polysome isolation. Third, they were capable of stimulating incorporation of [³H]leucine into trichloroacetic acid-precipitable material in a chick reticulocyte cell-free protein-synthesizing system. When isolated [³H]leucine pulse-labeled polysomes were treated with either EDTA-RNase or puromycin, 80–90% of the radioactivity was released, indicating that only the nascent polypeptide chains were labeled. After exposing mycelia for 1 min to [¹⁴C]mannose, the polysomes were exclusively labeled, indicating that initial glycosylation takes place on nascent polypeptide chains. Preincubation of mycelia with 2-deoxyglucose followed by pulse-labeling with [³H]leucine and [¹⁴C]mannose showed that 2-deoxy-d-glucose inhibits both protein synthesis and glycosylation. However, similar preincubation with tunicamycin caused an 80% drop in [¹⁴C]mannose label in the polysomes, but only a 10–20% drop of [³H]leucine label, suggesting that glycosylation of nascent chains in A. niger involves an oligosaccharide-lipid intermediate, since it has been shown that tunicamycin inhibits the synthesis of such an intermediate. When isolated polysomes were placed into an in vitro glycosylating mixture containing Mn²⁺, GDP-[¹⁴C]mannose, and smooth membranes from A. niger nascent chains were labeled. This reaction was shown to be dependent on addition of polysomes to the mixture and was not inhibited by 2-deoxy-d-glucose or tunicamycin. Both in vivo and in vitro glycosylated nascent chains were found to have about the same size range, and so it is suggested that in vitro no new oligosaccharide chains were synthesized, but preexisting chains were extended.     

Modification of oligosaccharide-lipid synthesis and protein glycosylation in glucose-deprived cells

Incubation of vesicular stomatitis virus-infected glucose-starved baby hamster kidney cells with [³⁵S]methionine results in the synthesis of all viral proteins. However, as judged by sodium dodecyl sulfate-polyacrylamide gel electrophoresis and tryptic peptide mapping, the G protein is abnormally glycosylated. Metabolic labeling of the oligosaccharide-lipid precursors with [³H]mannose for 15 min, followed by Chromatographic and enzymatic analysis, indicates that the radiolabeled lipid-linked oligosaccharides are devoid of glucose in contrast to the glucosylated oligosaccharide-lipids synthesized by cells grown in the presence of glucose. Also, in contrast to control cells, examination of the glycopeptide fraction reveals the presence of [³H]mannose-labeled glycopeptides which are resistant to erado-β-N-acetylglucos-aminidase H and are smaller in size than glycopeptides from mature vesicular stomatitis virus. In order to observe these effects, a minimum time of 5 h of glucose deprivation is necessary and the addition of 55 μm glucose or mannose to the medium reverses these effects. These results indicate that vesicular stomatitis virus-infected BHK cells deprived of glucose are unable to glucosylate the oligosaccharide-lipid intermediates and, consequently, are unable to glycosylate the G protein normally.     

The secretion of parathormone and glycosylated proteins by parathyroid cells in culture

The secretion of radioactive peptides by dispersed porcine parathyroid cells incubated with [³H]- or [¹⁴C]amino acids, [³H]glucosamine and [³H]mannose was analyzed. After incubation, the culture medium contained radioactive parathormone, as expected, and two radioactive glycopeptides: SP I and SP II. SP I appears to be identical with $\text{parathyroid}\text{secretory}\text{protein}$, heretofore not recognized as a glycoprotein. SP II has not been previously identified. SP I, but not SP II or parathormone, was adsorbed by Concanavalin A possibly reflecting a high mannose content of this molecule. Raising the concentration of calcium in the medium suppressed the secretion of radioactive parathormone and SP I in a similar fashion but did not affect the secretion of SP II. Our results suggest that SP I may play a fundamental role in parathyroid synthetic or secretory processes.     

Lipid-mediated glycosylation of a white matter membrane glycoprotein with an apparent molecular weight of 24,000.

White matter membrane preparations from pig brain catalyze the transfer of [¹⁴C]mannose from exogenous [¹⁴C]mannosylphosphoryldolichol into an endogenous oligosaccharide lipid. Under the same incubation conditions label is also incorporated into endogenous membrane glycoproteins. The enzymatic labeling of both classes of endogenous acceptors is stimulated by the addition of Ca²⁺. Several enzymatic properties of the mannosyltransferase activity responsible for the transfer of mannose from mannosylphosphoryldolichol into the oligosaccharide lipid intermediate have been examined. The [Man-¹⁴C] oligosaccharide lipid synthesized by this in vitro system has the solubility, hydrolytic and chromatographic characteristics of a pyrophosphate-linked oligosaccharide derivative of dolichol. The free [Man-¹⁴C]oligosaccharide liberated from the carrier lipid by mild acid treatment is estimated to contain 8 glycose units. All of the [¹⁴C]mannosyl units in the [Man-¹⁴C]oligosaccharide derived from exogenous [¹⁴C]mannosylphosphoryldolichol are released as free [¹⁴C]mannose by an α-mannosi-dase. No [¹⁴C]mannose is released during incubation with a β-mannosidase. The presence of an N,N′-diacetylchitobiose unit at the reducing end of the lipid-bound [Man-¹⁴C]oligosaccharide is indicated by its susceptibility to digestion by endo-β-N-acetylglucosaminidase H. Pronase digestion of the enzymatically labeled [Man-¹⁴C]glycoprotein yields a single [Man-¹⁴C]gly-copeptide fraction on Bio-Gel P-6 that appears to be slightly larger than the free [Man-¹⁴C]oligosac-charide released from the carrier lipid by mild acid hydrolysis. The [Man-¹⁴C]glycopeptide is cleaved by endo-β-N-acetylglucosaminidase H, and the neutral [Man-¹⁴C]oligosaccharide product appears to be identical to the product formed when the lipid-bound [Man-¹⁴C]oligosaccharide is degraded by the endoglycosidase. The glycopeptide linkage in the [Man-¹⁴C]glycoprotein is stable to mild alkali treatment. These results are consistent with the dolichol-linked [Man-¹⁴C]oligosaccharide, mannosy-lated via exogenous [¹⁴C]mannosylphosphoryldoiichol, being subsequently transferred en bloc from dolichyl pyrophosphate to asparagine residues in endogenous membrane polypeptide acceptors. SDS-polyacrylamide gel electrophoresis of the [Man-¹⁴C]glycoprotein, labeled when white matter membranes are incubated with [¹⁴C]mannosylphosphoryldolichol. revealed a major labeled polypeptide with an apparent mol wt of 24,000. A minor labeled membrane glycoprotein is also seen, having an apparent mol wt of 105,000.     

Synthesis of the mannosyl-O-serine (threonine) linkage of glycoproteins from polyisoprenylphosphate mannose in yeast (Hansenula holstii)

The mannolipid synthesized from GDP-mannose and lipid acceptors in a particulate enzyme preparation from the yeast Hansenula holstii (R. K. Bretthauer, S. Wu, and W. E. Irwin, (1973) Biochim. Biophys. Acta, 304, 736–747) has the properties of dolicholmonophosphate mannose. Transfer of [¹⁴C]mannose from exogenously supplied, purified mannolipid to endogenous protein acceptors of the particulate enzyme fraction has now been demonstrated. The synthesis of radioactive products which are insoluble in chloroform-methanol and water is dependent upon time and concentrations of substrate, particulate fraction protein, and detergent. Addition of MgCl₂ or MnCl₂ to incubation mixtures prepared in the absence of these ions had only small stimulatory effects (20–25%), suggesting that the reaction is not dependent upon metal ions. Relatively high concentrations (0.005 m-0.05 m) of EDTA did partially inhibit the reaction, but this is considered to be due to secondary effects.Seventy percent of the radioactivity in the chloroform-methanol insoluble residue was solubilized with hot, neutral citrate buffer. The Chromatographic properties of this material on Sephadex gels and on DEAE-Sephadex were very similar to the properties of glycoprotein products derived from GDP-[¹⁴C]mannose. The chloroform-methanol insoluble products were also solubilized with Pronase which subsequently resulted in the isolation of a radioactive glycopeptide that contained 25% of the radioactivity transferred from mannolipid. The radioactive component of this glycopeptide was shown by β-elmination experiments and by amino acid analyses to be [¹⁴C]mannose residues linked O-glycosidically to serine and threonine residues. It was concluded, therefore, that one function of the mannolipid is to serve as mannosyl donor in the synthesis of the mannosyl-O-serine (threonine) linkage region of glycoproteins which may be part of the cell wall mannan-protein complex. Other mannose-containing products may also be synthesized from the mannolipid, as β-elimination of the chloroform-methanol insoluble fraction or of the Pronase soluble fraction did not result in recovery of all of the radioactivity as [¹⁴C]mannose.     

An intramolecular C-2 → C-1 hydrogen transfer during the acid-catalyzed conversion of d-xylose to d-threo-pentulose (d-xylulose)

Aldose-ketose isomerases are known to catalyze a partial and sometimes complete intramolecular hydrogen transfer between C-1 of the ketose and C-2 of the aldose. It was recently shown (Feather, M. S., and Harris, D. W. (1975) J. Amer. Chem. Soc.97, 178–181) that the same type of transfer occurs during the acid-catalyzed interconversion of d-fructose, d-glucose, and d-mannose. A similar transfer is demonstrated herein for the conversion of d-xylose to d-xylulose in acid solution. d-[2-³H]xylose was isomerized in aqueous sulfuric acid and the resulting d-[³H]xylulose was isolated in 6% yield. The ketose had 18.3% the activity of the starting aldose. Chemical degradation showed that all the carbon-bound tritium of the d-[³H]xylulose was located at C-1, thus indicating a C-2 → C-1 intramolecular hydrogen transfer. During the reaction, less than 1.2% of the total radiochemical activity was found in the solvent, and, the unreacted d-[2-³H]xylose was recovered, having an activity nearly the same as the starting material. The differences in activity, therefore, of the d-[2-³H]xylose and the d-[1-³H]xylulose are due to an isotope effect ($\text{K}{}_{\mathrm{<mtext>H</mtext>}}\text{K}{}_{\mathrm{<mtext>T</mtext>}}$) which is indicated to be 5.4. The data are discussed in terms of currently accepted models for isomerase mechanisms.     

Inhibition of cell differentiation and cell cohesion by tunicamycin in Dictyostelium discoideum

The effects of tunicamycin on protein glycosylation and cell differentiation were examined during early development of Dictyostelium discoideum. Tunicamycin inhibited cell growth reversibly in liquid medium. At a concentration of 3 μg/ml, tunicamycin completely inhibited morphogenesis and cell differentiation in developing cells. These cells remained as a smooth lawn and failed to undergo chemotactic migration. The expression of EDTA-resistant contact sites was also inhibited. The inhibition by tunicamycin was reversible if cells were washed free of the drug within the first 10 hr of incubation. After 12 hr of development, cells were protected from the drug by the sheath. When cells were treated with tunicamycin during the first 10 hr of development, incorporation of [³H]mannose and [³H] fucose was inhibited by approximately 75% within 45 min while no significant inhibition of [³H]leucine incorporation was observed during the initial 3 hr of drug treatment. The inhibition of protein glycosylation was further evidenced by the reduction in number of glycoproteins “stained” with ¹²⁵I-labelled con A. A number of developmentally regulated high-molecular-weight glycoproteins, including the contact site A glycoprotein (gp80), were undetectable when cells were labelled with [³H]fucose in the presence of tunicamycin. It is therefore evident that glycoproteins with N-glycosidically linked carbohydrate moieties may play a crucial role in intercellular cohesiveness and early development of D. discoideum.     

(3H)anisomycin binding to eukaryotic ribosomes

Anisomycin, a well-known inhibitor of eukaryotic ribosomes' peptidyl-transferase activity, specifically binds to the 60 S ribosome subunit. Quantitative studies on [³H]anisomycin binding to yeast and human tonsil ribosomes have shown that a maximum of one molecule of the antibiotic is bound per ribosome in both cases. There is a single type of binding to 60 S subunits but ribosomes themselves are not homogeneous with respect to [³H]anisomycin binding, since the interaction between antibiotic and ribosome occurs with two different affinities. Only ribosomes having the higher type of affinity for [³H]anisomycin are active in catalysing peptide bond formation, as tested in both the puromycin and the fragment reaction assays. Affinity of [³H]anisomycin for ribosomes is higher at 0 °C than at 30 °C. Affinity is decreased in the presence of ethanol.The acetate group in the 3′ position of the pyrrolidine ring of anisomycin is important for the anisomycin—ribosome interaction since deacetylanisomycin appears to have a mode of action similar to anisomycin but has an affinity for the ribosome that is 350 times smaller.The effect of certain peptidyl-transferase inhibitors has been tested on [³H]anisomycin binding to ribosomes. Using either yeast or human tonsil ribosomes a number of sesquiterpene antibiotics of the trichodermin group (trichodermin, trichodennol, fusarenon X and trichothecin) totally block [³H]anisomycin binding whereas puromycin and verrucarin A only partially inhibit the [³H]anisomycin interaction with ribosomes. Gougerotin, blasticidin S and actinobolin have no effect. Tenuazonic acid and sparsomycin inhibit [³H]anisomycin binding to ribosomes but the degree of inhibition differs between yeast and human tonsil ribosomes.