Glycosyl transferase activity of the Escherichia coli penicillin-binding protein 1b: specificity profile for the substrate

The glycosyl transferase of the Escherichia coli bifunctional penicillin-binding protein (PBP) 1b catalyzes the assembly of lipid-transported N-acetylglucosaminyl-beta-1,4-N-acetylmuramoyl-L-Ala-gamma-D-Glu-meso-A2pm-D-Ala-D-Ala units (lipid II) into linear peptidoglycan chains. These units are linked, at C1 of N-acetylmuramic acid (MurNAc), to a C55 undecaprenyl pyrophosphate. In an in vitro assay, lipid II functions both as a glycosyl donor and as a glycosyl acceptor substrate. Using substrate analogues, it is suggested that the specificity of the enzyme for the glycosyl donor substrate differs from that for the acceptor. The donor substrate requires the presence of both N-acetylglucosamine (GlcNAc) and MurNAc and a reactive group on C1 of the MurNAc and does not absolutely require the lipid chain which can be replaced by uridine. The enzyme appears to prefer an acceptor substrate containing a polyprenyl pyrophosphate on C1 of the MurNAc sugar. The problem of glycan chain elongation that presumably proceeds by the repetitive addition of disaccharide peptide units at their reducing end is discussed.     

High affinity binding of an N-terminal myristoylated p60src peptide

N-Myristoyl and non-myristoyl peptides corresponding to the N terminus of p60src were used to examine whether N-myristoylation facilitates the binding of p60src to specific protein sites at the plasma membrane. We discovered high affinity protein acceptor sites (Kd = 2.7 nM) to a 15-amino acid N-myristoylated N-terminal p60src peptide in red cell membrane vesicles. Binding was not competed by the non-myristoylated analog of the peptide nor by shorter N-myristoyl src peptides and peptides homologous to the N terminus of other N-myristoylated proteins. Binding was not evident after treatment of vesicles with proteolytic enzymes. Raising the salt concentration of the buffer to 50 mM NaCl caused an apparent inhibition of binding. However, no significant effect of salt was observed on the off-rate of bound ligand under these conditions. The results indicate the existence of N-myristoyl-dependent p60src protein acceptor sites at or near the plasma membrane/skeleton interface of red cells which could be responsible for the localization of p60src to this region and may represent new regulatory components for p60src-mediated tyrosine kinase activity.     

Specific lipids enhance the activity of UDP-GlcNAc: dolichol phosphate GlcNAc-1-phosphate transferase in rat liver endoplasmic reticulum membrane vesicles.

The rate of the reaction catalyzed by UDP-N-acetylglucosamine (GlcNAc):dolichol phosphate GlcNAc-1-phosphate transferase in rat liver endoplasmic reticulum vesicles was shown to be influenced by particular lipids. Utilizing in vitro assay conditions where the membrane vesicles retained latency of glucose-6-phosphatase activity, the addition of phosphatidylethanolamine, cardiolipin, or monogalactosyldiglyceride resulted in severalfold increases in the rate of dolichol pyrophosphate N-acetylglucosamine synthesis. Other phospholipids were not stimulatory. These rates were dependent on the concentrations of the exogenous lipids and of the substrate dolichol phosphate. In the presence of cardiolipin, the membrane-bound enzyme became more susceptible to inactivation by protease K and to inhibition by tunicamycin. Titration of cardiolipin-containing endoplasmic reticulum vesicles with adriamycin indicated that the majority of the cardiolipin was exposed on the outer surface. These results suggest that the particular lipids altered membrane structure in a way that allowed further access of the enzyme to substrate, inhibitor, and other molecules. Lipids observed in these studies to be stimulatory are known to exist in the macromolecular hexagonal phase and may therefore be affecting the GlcNAc-1-phosphate transferase by locally disrupting the bilayer structure of the membrane. As other dolichol-utilizing enzymes have been previously observed by other investigators to be similarly influenced by such lipids, the effects may be common to enzymes of the dolichol cycle.     

Structural Determinants Allowing Transferase Activity in SENSITIVE TO FREEZING 2, Classified as a Family I Glycosyl Hydrolase

SENSITIVE TO FREEZING 2 (SFR2) is classified as a family I glycosyl hydrolase but has recently been shown to have galactosyltransferase activity in Arabidopsis thaliana. Natural occurrences of apparent glycosyl hydrolases acting as transferases are interesting from a biocatalysis standpoint, and knowledge about the interconversion can assist in engineering SFR2 in crop plants to resist freezing. To understand how SFR2 evolved into a transferase, the relationship between its structure and function are investigated by activity assay, molecular modeling, and site-directed mutagenesis. SFR2 has no detectable hydrolase activity, although its catalytic site is highly conserved with that of family 1 glycosyl hydrolases. Three regions disparate from glycosyl hydrolases are identified as required for transferase activity as follows: a loop insertion, the C-terminal peptide, and a hydrophobic patch adjacent to the catalytic site. Rationales for the effects of these regions on the SFR2 mechanism are discussed.     

The location of redox-sensitive groups in the carrier protein of proline at the outer and inner surface of the membrane in Escherichia coli

Evidence is presented in this report for the presence of two sets of dithiols associated with proline transport activity in Escherichia coli. One set is located at the outer surface, the other at the inner surface of the cytoplasmic membrane. Treatment of right-side-out membrane vesicles from E. coli ML 308-225 with the membrane-impermeable oxidant ferricyanide resulted in inhibition of L-proline uptake without having significant effect on the magnitude of the delta approximately mu H+. Subsequent addition of reducing agents restored proline transport activity. The membrane-impermeable SH-reagent glutathione hexane maleimide inhibited proline transport in right-side-out membrane vesicles irreversibly. Pretreatment of the vesicles with ferricyanide protected the carrier against inactivation by glutathione hexane maleimide. Electron transfer in the respiratory chain of right-side-out vesicles led to the generation of a delta approximately mu H+, interior negative and alkaline, and the conversion of a disulphide to a dithiol in the proline carrier as is shown by the increased inhibition of proline transport by the membrane impermeable dithiol reagent 4-(2-arsonophenyl)azo-3-hydroxy-2,7-naphthalene disulphonic acid (thorin). The inhibition exerted by thorin was completely reversed by dithiothreitol. Pretreatment of the vesicles with thorin protected against glutathione hexane maleimide inhibition, indicating that both reagents react with the same group. Treatment of inside-out membrane vesicles with ferricyanide inactivated the proline transport system reversibly. The oxidizing effect of ferricyanide in inside-out vesicles resulted in protection against inhibition by glutathione hexane maleimide. Imposition in these vesicles of a delta approximately mu H+, interior positive and acid, also protected the proline carrier against glutathione hexane maleimide inactivation, indicating that a dithiol is converted to a disulphide upon energization.     

Evaluation of deoxygenated oligosaccharide acceptor analogs as specific inhibitors of glycosyltransferases

The glycosyltransferases controlling the biosynthesis of cell-surface complex carbohydrates transfer glycosyl residues from sugar nucleotides to specific hydroxyl groups of acceptor oligosaccharides. These enzymes represent prime targets for the design of glycosylation inhibitors with the potential to specifically alter the structures of cell-surface glycoconjugates. With the aim of producing such inhibitors, synthetic oligosaccharide substrates were prepared for eight different glycosyltransferases. The enzymes investigated were: A, alpha(1----2, porcine submaxillary gland); B, alpha(1----3/4, Lewis); C, alpha(1----4, mung bean); D, alpha(1----3, Lex)-fucosyltransferases; E, beta(1----4)-galactosyltransferase; F, beta(1----6)-N-acetylglucosaminyltransferase V; G, beta(1----6)-mucin-N-acetylglucosaminyltransferase ("core-2" transferase); and H, alpha(2----3)-sialyltransferase from rat liver. These enzymes all transfer sugar residues from their respective sugar nucleotides (GDP-Fuc, UDP-Gal, UDP-GlcNAc, and CMP-sialic acid) with inversion of configuration at their anomeric centers. The Km values for their synthetic oligosaccharide acceptors were in the range of 0.036-1.3 mM. For each of these eight enzymes, acceptor analogs were next prepared where the hydroxyl group undergoing glycosylation was chemically removed and replaced by hydrogen. The resulting deoxygenated acceptor analogs can no longer be substrates for the corresponding glycosyltransferases and, if still bound by the enzymes, should act as competitive inhibitors. In only four of the eight cases examined (enzymes A, C, F, and G) did the deoxygenated acceptor analogs inhibit their target enzymes, and their Ki values (all competitive) remained in the general range of the corresponding acceptor Km values. No inhibition was observed for the remaining four enzymes even at high concentrations of deoxygenated acceptor analog. For these latter enzymes it is suggested that the reactive acceptor hydroxyl groups are involved in a critical hydrogen bond donor interaction with a basic group on the enzyme which removes the developing proton during the glycosyl transfer reaction. Such groups are proposed to represent logical targets for irreversible covalent inactivation of this class of enzyme.     

Human erythrocyte galactosyltransferase. Characterization, membrane association and sidedness of active site

Human erythrocyte UDPgalactose : 2-acetamido-2-deoxy-alpha-D-galactopyranosylpeptide galactose beta(1 lead to 3) transferase (Galactosyltransferase) has been characterized in terms of detergent and metal ion requirements. Michaelis constants for donor and acceptor substrates, inhibition constant for N-acetylgalactosamine, pH optimum and ionic strength effects. The assay thus optimized permits initial velocity measurements. Galactosyltransferase was shown to be membrane-bound by demonstrating its association with erythrocyte ghosts after high and low ionic strength treatments to remove weakly-associated proteins. In the absence of detergents, no activity was detectable in sealed ghosts and inside-out vesicles derived from erythrocyte membranes. Enzyme activation by detergents paralleled solubilization of membrane proteins. Both latency and solubilization studies indicated a substrate inaccessible active site for the enzyme in situ in the membrane. Galactosyltransferase activity in resealed ghosts, leaky ghosts and inside-out vesicles was resistant to the action of trypsin, chymotrypsin or pronase applied as single agents. A mixture of these proteases, however, strongly reduced the enzyme activity in inside-out vesicles and leaky ghosts, indicating a cytosolic orientation for the active site of the galactosyltransferase.     

Effect of S-(2-chloroethyl)-DL-cysteine on the transport of p-aminohippurate ion in renal plasma membrane vesicles

The effects of S-(2-chloroethyl)-DL-cysteine (CEC) (a potent nephrotoxin) on the transport of p-aminohippurate ion (PAH) in renal plasma membrane vesicles isolated from rat renal cortex were studied in vitro. The uptake of PAH was significantly reduced in a dose-dependent manner in both the brush border membrane (BBM) and basolateral membrane (BLM) vesicles. These results demonstrate that CEC is capable of interfering with the accumulation of PAH (a model organic anion for renal tubular transport system) by both energy-independent and energy-dependent carrier-mediated transport processes. Probenecid, a typical inhibitor of the organic anion transport system, showed the highest inhibition of PAH uptake in both the membranes vesicles. These data indirectly suggest that transport by renal tubular cells may result in the accumulation of CEC in renal cellular organelles eventually in toxic concentrations. Thus, CEC showed both dose- and time-dependent inhibition of the activities of gamma-glutamyl transferase (a BBM marker enzyme) and Na+, K(+)-ATPase (a BLM marker enzyme), while no such inhibition was noticed with probenecid. Pretreatment with probenecid prevented the inhibition of the gamma-glutamyl transferase activity due to CEC in BBM, but failed to do so for the Na+,K(+)-ATPase activity in BLM vesicles. Thus, the data suggest that the inhibition of the activities of these membrane-specific enzymes by CEC could lead to the initial development of its nephrotoxicity.     

An in vitro ESR study of uncatalyzed rat liver protein-catalyzed spin-labeled phosphatidylcholine exchange

ESR spectrometry has been used to study fatty acid spin-labeled phosphatidylcholine exchange from single bilayer donor vesicles to various acceptor systems, such as intact or differently treated mitochondria, phospholipid multilamellar vesicles or single bilayer vesicles. This exchange is catalyzed by soluble non-specific rat liver protein, first investigated by Bloj and Zilversmit in 1977 (J. Biol. Chem. 252, 1613--1619). Non-catalyzed phosphatidylcholine exchange has also been studied. Full inhibition of both mechanisms occurs with lipid-depleted acceptor mitochondria, while N-ethylmaleimide-treated mitochondria behave as good acceptors during catalyzed exchange but are in no way effective during spontaneous exchange. Non-catalyzed exchange does not take place with phospholipase D-treated mitochondria as acceptors, while the pure catalyzed mechanism is inhibited by 28%. Neither multilamellar nor single bilayer phospholipid vesicles exchange spin-labeled phosphatidylcholine in the absence of protein, the former being a poorer acceptor system than the latter during catalyzed exchange, when this activity is 31 and 80%, respectively, of that of intact mitochondria. The hypothesis is made that the spontaneous mechanism is active among intact natural membranes and could be of some importance in vivo. Furthermore, the biomembrane protein moiety is assumed to be involved in the catalyzed exchange more as a phospholipid spacer than as a binder between the exchange protein and the membrane involved. Phospholipids, on the contrary, appear to be important for both functions.     

Human erythrocyte galactosyltransferase. Characterization, membrane association and sidedness of active site

Human erythrocyte UDPgalactose : 2-acetamido-2-deoxy-α-d-galactopyranosylpeptide galactose transferase (Galactosyltransferase) has been characterized in terms of detergent and metal ion requirements, Michaelis constants for donor and acceptor substrates, inhibition constant for N-acetylgalactosamine, pH optimum and ionic strength effects. The assay thus optimized permits initial velocity measurements. Galactosyltransferase was shown to be membrane-bound by demonstrating its association with erythrocyte ghosts after high and low ionic strength treatments to remove weakly-associated proteins. In the absence of detergents, no activity was detectable in sealed ghosts and inside-out vesicles derived from erythrocyte membranes. Enzyme activation by detergents paralleled solubilization of membrane proteins. Both latency and solubilization studies indicated a substrate-inaccessible active site for the enzyme in situ in the membrane. Galactosyltransferase activity in resealed ghosts, leaky ghosts and inside-out vesicles was resistant to the action of trypsin, chymotrypsin or pronase applied as single agents. A mixture of these proteases, however, strongly reduced the enzyme activity in inside-out vesicles and leaky ghosts, indicating a cytosolic orientation for the active site of the galactosyltransferase.     

Peptide transport in rabbit kidney. Studies with l-carnosine

l-Carnosine was shown to be transported into rabbit renal brush-border membrane vesicles by an Na⁺ - independent mechanism. The transport was competitively inhibited by glycyl-l-proline. Various di- and tripeptides inhibited l-carnosine transport, whereas free amino acids did not. Inhibition studies showed that blocking the free amino and carboxyl groups of the peptide reduced its affinity for the transport carrier. Under the conditions in which there was no detectable hydrolysis of l-carnosine in the medium, intravesicular contents showed a 30% hydrolysis of the peptide within the vesicles. Disruption of membrane vesicles with deoxycholate resulted in a 3-fold increase in l-carnosine hydrolyzing activity over untreated intact vesicles. Based on these observations, a model for peptide transport is proposed in which transport of the intact peptide across the membrane is followed by its partial or complete hydrolysis by a membrane peptidase whose active site is on the cytoplasmic side of the membrane.     

Inhibition of glutathione transferase pi from human placenta by 1-chloro-2,4-dinitrobenzene occurs because of covalent reaction with cysteine 47.

Human placenta glutathione transferase pi is irreversibly inhibited when incubated with 1-chloro-2,4-dinitrobenzene (CDNB) in the absence of the cosubstrate glutathione. The enzyme is protected against CDNB inactivation by the presence of S-methylglutathione and glutathione. The kinetics of inactivation is pseudo-first-order with k(obs) = 0.04 min-1 when 44 microM enzyme is incubated in presence of 1 mM CDNB at pH 6.5. The inhibition is saturable with respect to the CDNB concentration and the enzyme-CDNB complex shows a K(i) = 2.7 mM. Concomitant to the inhibition process is formation of an absorption band at 340 nm. After trypsin digestion and HPLC analysis, the CDNB-reacted enzyme gives a single peptide absorbing at 340 nm. Automated Edman degradation of this peptide indicates cysteine 47 to be the residue alkylated by CDNB.     

The role of acetyl coenzyme A: butyrate coenzyme A in the transferase uptake of butyrate by isolated membrane vesicles of Escherichia coli

The acetyl CoA:butyrate CoA transferase catalyzes the translocation of butyrate in membrane vesicles prepared from a strain of Escherichia coli which is depressed for the acetoacetate degradation operon. Butyrate accumulated in the membranes as butyryl CoA. The role of the transferase in uptake is supported by the following observations: (i) uptake is stimulated by acetyl CoA; (ii) the solubilized CoA transferase and uptake exhibit K_mS for butyrate, pH optima and levels inhibition by N-ethylmaleimide that are virtually identical; (iii) significant amounts of the CoA transferase are found associated with the membranes and uptake is rapidly inhibited by butyryl CoA and acetate, the products of the CoA transferase-catalyzed reaction. The fact that butyrate uptake did not exhibit saturation kinetics with increasing concentrations of acetyl CoA suggested that the transferase is not localized on the outer surface of the membrane. The level of free butyrate in the vesicles, the fact that butyrate uptake exhibited saturation kinetics with increasing concentrations of butyrate, and the observation that radioactivity was not rapidly lost from the vesicles following addition of butyryl CoA or acetate to incubation mixtures indicated that butyrate is translocated rather than trapped by the CoA transferase.     

Substrate specificity of N-acetylglucosaminyl(diphosphodolichol) N-acetylglucosaminyl transferase, a key enzyme in the dolichol pathway

N-Acetylglucosaminyl(diphosphodolichol) N-acetylglucosaminyl transferase, also known as Enzyme II, is the second enzyme in the dolichol pathway. This pathway is responsible for the assembly of the tetradecasaccharide pyrophosphate dolichol, which is the substrate for oligosaccharyl transferase. In order to study the specificity of Enzyme II, four unnatural dolichol diphosphate monosaccharides were synthesized, with the C-2 acetamido group in the natural substrate Dol-PP-GlcNAc 1a replaced by fluoro, ethoxy, trifluoroacetamido, and amino functionalities. These analogues 1b-e were evaluated as glycosyl acceptors for Enzyme II, which catalyzes the formation of dolichol diphosphate chitobiose (Dol-PP-GlcNAc(2)) from UDP-GlcNAc and Dol-PP-GlcNAc. Enzyme II from pig liver was found to be highly specific for its glycosyl acceptor and the acetamido group shown to be a key functional determinant for this glycosylation reaction.     

An in vitro ESR study of uncatalyzed and rat liver protein-catalyzed spin-labeled phosphatidylcholine exchange

ESR spectrometry has been used to study fatty acid spin-labeled phosphatidylcholine exchange from single bilayer donor vesicles to various acceptor systems, such as intact or differently treated mitochondria, phospholipid multilamellar vesicles or single bilayer vesicles. This exchange is catalyzed by soluble non-specific rat liver protein, first investigated by Bloj and Zilversmit in 1977 (J. Biol. Chem. 252, 1613–1619). Non-catalyzed phosphatidylcholine exchange has also been studied. Full inhibition of both mechanisms occurs with lipid-depleted acceptor mitochondria, while $\text{N-}\text{ethylmaleimide-treated}$ mitochondria behave as good acceptors during catalyzed exchange but are in no way effective during spontaneous exchange. Non-catalyzed exchange does not take place with phospholipase D-treated mitochondria as acceptors, while the pure catalyzed mechanism is inhibited by 28%. Neither multilamellar nor single bilayer phospholipid vesicles exchange spin-labeled phosphatidylcholine in the absence of protein, the former being a poorer acceptor system than the latter during catalyzed exchange, when this activity is 31 and 80%, respectively, of that of intact mitochondria. The hypothesis is made that the spontaneous mechanism is active among intact natural membranes and could be of some importance in vivo. Furthermore, the biomembrane protein moiety is assumed to be involved in the catalyzed exchange more as a phospholipid spacer than as a binder between the exchange protein and the membrane involved. Phospholipids, on the contrary, appear to be important for both functions.     

Glycosyl transferases of baby-hamster-kidney (BHK) cells and ricin-resistant mutants. N-glycan biosynthesis

Five cell lines of ricin-resistant BHK cells have been assayed for gross carbohydrate analysis of cellular glycoproteins, for the activities of several glycosidases and of specific glycosyl transferases active in assembly of N-glycans of glycoproteins. The latter enzymes include sialyl transferase using asialofetuin as glycosyl acceptor, fucosyl transferases using asialofetuin and asialoagalactofetuin acceptors, galactosyl transferases using ovalbumin, ovomucoid and N-acetylglucosamine as acceptors and N-acetylglucosaminyl transferases using ovalbumin and glycopeptides as acceptors. Cell line RicR14, binding less ricin than normal BHK cells, contains reduced amounts of sialic acid, galactose and N-acetylglucosamine in cellular glycoproteins and lacks almost completely N-acetylglucosamine transferase I, an essential enzyme in assembly of ricin-binding carbohydrate sequences of N-glycans. These cells also contain reduced levels of N-acetylglucosamine transferase II active on a product of N-acetylglucosamine transferase I action. Sialyl transferase activity is severely depressed while fucose-(alpha 1 leads to 6)-N-acetylglucosamine fucosyl transferase activity is increased. Cell lines RicR15, 17, 19 and 21 showed partial deficiencies in galactosyl and N-acetylglucosaminyl transferases. A hypothesis is put forward to account for the different carbohydrate compositions and ricin binding properties of glycoproteins synthesised by these cells in terms of the determined enzyme defects, the normal level of sialyl transferases detected in RicR15 and RicR21 cells and the elevated levels of sialyl and fucosyl transferases detected in RicR17 and 19 cells. None of the above changes in glycosyl transfer reactions in the RicR cell lines are due to enhanced glycosidase or sugar nucleotidase activities in the mutant cells.     

Intrinsic tyrosine fluorescence as a tool to study the interaction of the shaker B "ball" peptide with anionic membranes

Steady-state and time-resolved fluorescence from the single tyrosine in the inactivating peptide of the Shaker B potassium channel (ShB peptide) and in a noninactivating peptide mutant, ShB-L7E, has been used to characterize their interaction with anionic phospholipid membranes, a model target mimicking features of the inactivation site on the channel protein. Partition coefficients derived from steady-state anisotropy indicate that both peptides show a high affinity for anionic vesicles, being higher in ShB than in ShB-L7E. Moreover, differential quenching by lipophilic spin-labeled probes and fluorescence energy transfer using trans-parinaric acid as the acceptor confirm that the ShB peptide inserts deep into the membrane, while the ShB-L7E peptide remains near the membrane surface. The rotational mobility of tyrosine in membrane-embedded ShB, examined from the decay of fluorescence anisotropy, can be described by two different rotational correlation times and a residual constant value. The short correlation time corresponds to fast rotation reporting on local tyrosine mobility. The long rotational correlation time and the high residual anisotropy suggest that the ShB peptide diffuses in a viscous and anisotropic medium compatible with the aliphatic region of a lipid bilayer and support the hypothesis that the peptide inserts into it as a monomer, to configure an intramolecular beta-hairpin structure. Assuming that this hairpin structure behaves like a rigid body, we have estimated its dimensions and rotational dynamics, and a model for the peptide inserted into the bilayer has been proposed.     

Inhibition of PhoE translocation across Escherichia coli inner-membrane vesicles by synthetic signal peptides suggests an important role of acidic phospholipids in protein translocation

To obtain insight into the mechanism of precursor protein translocation across membranes, the effect of synthetic signal peptides and other relevant (poly)peptides on in vitro PhoE translocation was studied. The PhoE signal peptide, associated with inner membrane vesicles, caused a concentration-dependent inhibition of PhoE translocation, as a result of a specific interaction with the membrane. Using a PhoE signal peptide analog and PhoE signal peptide fragments, it was demonstrated that the hydrophobic part of the peptide caused the inhibitory effect, while the basic amino terminus is most likely important for an optimal interaction with the membrane. A quantitative analysis of our data and the known preferential interaction of synthetic signal peptides with acidic phospholipids in model membranes strongly suggest the involvement of negatively charged phospholipids in the inhibitory interaction of the synthetic PhoE signal peptide with the inner membrane. The important role of acidic phospholipids in protein translocation was further confirmed by the observation that other (poly)peptides, known to have both a high affinity for acidic lipids and hydrophobic interactions with model membranes, also caused strong inhibition of PhoE translocation. The implication of these results with respect to the role of signal peptides in protein translocation is indicated.     

Control of N-linked carbohydrate unit synthesis in thyroid endoplasmic reticulum by membrane organization and dolichyl phosphate availability

Thyroid rough endoplasmic reticulum (ER) has been shown to contain a highly organized multienzyme system capable of carrying out the N-glycosylation of newly synthesized proteins. These reactions were studied in isolated ER vesicles and found to be controlled to a large extent by the availability of a key substrate, dolichyl phosphate (Dol-P), as well as by the amount of endogenous polypeptide acceptor present. Although in intact vesicles UDP-Glc was utilized in an efficient manner to form Dol-P-Glc and glucosylated oligosaccharide-lipid, after disruption of vesicle integrity, even with low concentrations of Triton X-100, the coupling of Dol-P-Glc formation to lipid-linked oligosaccharide assembly and subsequent N-glycosylation was substantially impaired. Increased incubation temperatures also resulted in a decreased effectiveness of glucose transfer from Dol-P-Glc to lipid-oligosaccharide, presumably because of a decline in the extent of structural organization of the ER membranes. The limited availability of endogenous Dol-P was demonstrated by the pronounced stimulation in Dol-P-Glc formation resulting from the addition of this lipid acceptor to Triton-disrupted ER membranes as well as by its generation in intact vesicles. The latter was accomplished by stimulating recycling of endogenous Dol-P through the addition of a peptide (Tyr-Asn-Leu-Thr-Ser-Val) which is an N-glycosylation substrate. The inhibition of Dol-P-Glc synthesis from UDP-Glc observed in the presence of elevated levels of GDP-Man which could be relieved in Triton-disrupted or intact ER vesicles by the addition or generation, respectively, of Dol-P, is considered to be the result of a competing requirement for Dol-P by the mannosyltransferase. Moreover GTP, by selectively inhibiting the mannosyltransferase, prevented the decrease of Dol-P-Glc formation caused by GDP-Man. Since addition of the acceptor peptide to intact vesicles stimulated Dol-P-P-GlcNAc as well as Dol-P-Glc and Dol-P-Man synthesis it would appear that a pool of Dol-P available in common to all three enzymes responsible for dolichol-linked monosaccharide synthesis exists in the ER membranes.     

Cloning and characterization of two genes from Streptomyces lividans that confer inducible resistance to lincomycin and macrolide antibiotics.

Inducible resistance to lincomycin and macrolides in Streptomyces lividans TK21 results from expression of two linked genes: lrm, encoding a ribosomal RNA methyltransferase that confers high-level resistance to lincomycin with lower levels of resistance to macrolides, and mgt, encoding a glycosyl transferase that specifically inactivates macrolides using UDP-glucose as cofactor. The lrm and mgt genes have been cloned and sequenced. The deduced lrm product is a 26-kDa protein with much similarity to other ribosomal RNA methyltransferases, such as the carB, tlrA and ermE products, whereas the mgt product (predicted to be 42 kDa) resembles a eukaryotic glycosyl transferase. Macrolides that induce the lrm-mgt gene pair are substrates for inactivation by the mgt product, and the lrm product confers ribosomal resistance to such inducers.