Initial membrane reaction in peptidoglycan synthesis. Interaction of lipid with phospho-N-acetylmuramyl-pentapeptide translocase.

The initial membrane reaction in the biosynthesis of peptidoglycan is catalyzed by phospho-N-acetylmuramyl (MurN Ac)-pentapeptide translocase (UDP-MurNAc-Ala-gamma DGlu-Lys-DAla-DAla undecaprenyl phosphate phospho-MurNAc-pentapeptide transferase). In addition to the transfer reaction, the enzyme catalyzes the exchange of [3H]uridine monophosphate with the uridine monophosphate moiety of UDP-MurN Ac-pentapeptide. Two distinct discontinuities are observed in the slopes of the Arrhenius plots of the exchange and transfer activities at 22 and 30 degrees C for the enzyme from Staphylococcus aureus Copenhagen. Anisotropy measurements of perylene fluorescence and electron spin resonance measurements of N-oxyl-4',4'-dimethyloxazolidine derivatives of 12- and 16-ketostearic acid intercalated into membranes from this organism define the lower (T1 = 16--22 degrees C) and upper (Th = 30 degrees C) boundaries of a phase transition. These values correlate with the discontinuities observed for the activity measurements. Thus, it is proposed that the physical state of the lipid micro-environment of phospho-MurNAc-penetapeptide translocase has a significant effect on the catalytic activity of this enzyme.

Initial membrane reaction in peptidoglycan synthesis: perturbation of lipid-phospho-N-acetylmuramyl-pentapeptide translocase interactions by n-butanol.

Phospho-N-acetylmuramyl-pentapeptide translocase, the initial membrane enzyme in the biosynthesis of peptidoglycan, requires a lipid microenvironment for function. n-Butanol was reversibly intercalated into membranes to perturb the hydrophobic interactions in this microenvironment in order to define further the role of lipid. In the concentration range for maximal stimulation of enzymic activity (0.12-0.18 M), n-butanol causes a 40% decrease in the fluorescence emission of the dansylated product, undecaprenyl diphosphate-(N epsilon-dansyl)pentapeptide. Since no change in emission maximum occurs below 22 degrees C in the presence of 0.12 M n-butanol, it is concluded that intercalation of this alkanol causes an increase in fluidity. Above 22 degrees C this concentration of n-butanol causes both a decrease in the fluorescence emission and a red shift in the emission maximum. It is concluded that a polarity change as well as fluidity change occurs above 22 degrees C. n-Butanol also causes a significant change in the phase transition experienced by the dansylated lipid product. Thus, it is possible with n-alkanols, e.g. n-butanol, to perturb lipid-translocase interactions resulting in an increase in fluidity in the microenvironment of the enzyme. This change in fluidity correlates with a stimulation of enzymic activity.

The dlt operon in the biosynthesis of D-alanyl-lipoteichoic acid in Lactobacillus casei.

The D-alanine incorporation system allows Lactobacillus casei to modulate the chemical properties of lipoteichoic acid (LTA) and hence control its proposed functions, i.e., regulation of autolysin action, metal ion binding, and the electromechanical properties of the cell wall. The system requires the D-alanine-D-alanyl carrier protein ligase (Dcl) and the D-alanyl carrier protein (Dcp). Our results indicate that the genes for these proteins are encoded in the dlt operon and that this operon contains at least 2 other genes, dltB and dltD. The aim of this paper is to describe the genetic organization of the operon, the role of the D-alanyl carrier protein, and the function of the putative protein encoded by dltB in the intramembranal translocation of the activated D-alanine.

Biosynthesis of D-alanyl-lipoteichoic acid: cloning, nucleotide sequence, and expression of the Lactobacillus casei gene for the D-alanine-activating enzyme.

The D-alanine-activating enzyme (Dae; EC 6.3.2.4) encoded by the dae gene from Lactobacillus casei ATCC 7469 is a cytosolic protein essential for the formation of the D-alanyl esters of membrane-bound lipoteichoic acid. The gene has been cloned, sequenced, and expressed in Escherichia coli, an organism which does not possess Dae activity. The open reading frame is 1,518 nucleotides and codes for a protein of 55.867 kDa, a value in agreement with the 56 kDa obtained by electrophoresis. A putative promoter and ribosome-binding site immediately precede the dae gene. A second open reading frame contiguous with the dae gene has also been partially sequenced. The organization of these genetic elements suggests that more than one enzyme necessary for the biosynthesis of D-alanyl-lipoteichoic acid may be present in this operon. Analysis of the amino acid sequence deduced from the dae gene identified three regions with significant homology to proteins in the following groups of ATP-utilizing enzymes: (i) the acid-thiol ligases, (ii) the activating enzymes for the biosynthesis of enterobactin, and (iii) the synthetases for tyrocidine, gramicidin S, and penicillin. From these comparisons, a common motif (GXXGXPK) has been identified that is conserved in the 19 protein domains analyzed. This motif may represent the phosphate-binding loop of an ATP-binding site for this class of enzymes. A DNA fragment (1,568 nucleotides) containing the dae gene and its putative ribosome-binding site has been subcloned and expressed in E. coli. Approximately 0.5% of the total cell protein is active Dae, whereas 21% is in the form of inclusion bodies. The isolation of this minimal fragment without a native promoter sequence provides the basis for designing a genetic system for modulating the D-alanine ester content of lipoteichoic acid.

Initial membrane reaction in the biosynthesis of peptidoglycan. Spin-labeled intermediates as receptors for vancomycin and ristocetin.

Phospho-N-acetylmuramyl-pentapeptide translocase (UDP-MurNAc-Ala-DGlu-Lys-DAla-DAla:undecaprenyl phosphate, phospho-MurNAc-pentapeptide transferase) catalyzes the initial membrane reaction in the biosynthesis of peptidoglycan. The spin-labeled nucleotide, UDP-MurNAc-Ala-DGlu-Lys (Nepsilon-2,2,5,5-tetramethyl-N-oxyl-pyrroline-3-carbonyl)-DAla-DAla, was used as a substrate by this enzyme for the synthesis of membrane-associated undecaprenyl-diphosphate-MurNAc-Ala-DGlu-Lys(Nepsilon-Tempyo)-DAla-DAla. The spin-labeled substrate and product complex with the antibiotics vancomycin and ristocetin. The association constants for the spin-labeled nucleotide are 6.2 times 10(5) and 6.2 times 10(4) M-1 for vancomycin and ristocetin, respectively. The association constants for the spin-labeled lipid intermediate are 3.0 times 10(4) and 2.1 times 10(4) M-1 for vancomycin and ristocetin, respectively. These results indicate that the acyl-DAla termini of membranes-associated spin-labeled undecaprenyl-diphosphate-MurNAc-pentapeptide are accessible to vancomycin and ristocetin and that the association constants are smaller than those determined for the corresponding antibiotic spin-labeled UDP-MurNAc-pentapeptide complexes.

Biosynthesis of peptidoglycan in Staphylococcus aureus: incorporation of the Nepsilon-Ala-Lys moiety into the peptide subunit of nascent peptidoglycan.

UDP-MurNAc-Ala-DGlu-Lys(Nepsilon-Ala)-DAla-DAla was isolated from extracts of Staphylococcus aureus Copenhagen. This nucleotide accumulated in media deficient in glycine. To establish its role in peptidoglycan biosynthesis, the nucleotide-hexapeptide was compared with UDP-MurNAc-Ala-DGlu-Lys-DAla-DAla in the reaction catalyzed by phospho-MurNAc-pentapeptide translocase and in the membrane-catalyzed nascent peptidoglycan-synthetizing system. In the exchange reaction catalyzed by the translocase, the Rmax and Rmax/Km are 1.79 muM/min and 4.47 X 10(-2)/min, respectively, for UDP-MurNAc-pentapeptide and 1.81 muM/min and 4.46 X 10(-2)/min, respectively, for UDP-Mur-NAc-hexapeptide. In the synthesis of nascent peptidoglycan, the Vmax is 1.8 muM/min X 10(-2) for both the nucleotide-hexapeptide and -pentapeptide. The Vmax/Km is 5.6 X 10(-4) and 4.3 X 10(-4)/min for the nucleotide-pentapeptide and -hexapeptide, respectively. Schleifer, Hammes, and Kandler (Adv. Microb. Physiol. in press) observed that growth of S. aureus Copenhagen on a glycine-poor medium results in a peptidoglycan structure in which 20% of the lysine residues are substituted at the epsilon-amino group by L-alanine residues that do not participate in interpeptide bridge information. The in vitro studies demonstrate that UDP-MurNAc-Ala-DGlu-Lys(Nepsilon-Ala)-DAla-DAla is a possible precursor of the Nepsilon-Ala-Lys moiety.

Biosynthesis of spin-labeled peptidoglycan: spin-spin interactions.

Membrane preparations from Gaffkya homari catalyzed the in vitro biosynthesis of soluble uncross-linked spin-labeled peptidoglycan, a uniformly labeled polynitroxide, from the spin-labeled nucleotide UDP-MurNAc-Ala-DGlu-Lys(Nepsilon-2,2,5,5-tetramethyl-1-pyrrolin-1-oxyl-3-carbonyl)-DAla-DAla (I) and UDP-GlcNAc. Soluble spin-labeled peptidoglycan was separated from membrane fragments and its spin-labeled precursor by centrifugation and gel filtration. The molecular weight distribution of the polymer was examined by agarose gel filtration. Spin-labeled [14C]peptidoglycan was polydisperse with a peak of radioactivity corresponding to a molecular weight of 5.0 X 10(5). The electron spin resonance spectrum of spin-labeled peptidoglycan was extensively broadened by spin-spin exchange interactions. These interactions were modified by changes in temperature, reduction by ascorbate, hydrolysis by lysozyme, and complexation with the antibiotic, vancomycin. Spin-spin exchange was reduced or eliminated in spin-labeled peptidoglycan by the random reduction of free radicals by ascorbate. A rotational correlation time of 0.37 ns was calculated for the probe in partially reduced spin-labeled peptidoglycan. This compares to a correlation time of 0.13 ns for the substrate (I). Raising the temperature increases spin-spin exchange line broadening. No transition points were observed for spin-labeled peptidoglycan as measured by this method. Degradati on of spin-labeled peptidoglycan by lysozyme eliminated the observed spin-spin exchange and yielded products with a mobility similar to I. Complexation of spin-labeled peptidoglycan with vancomycin resulted in both pronounced free-radical immobilization and a decrease in spin-spin exchange. The exchange effects are consistent with distance measurements in molecular models for peptidoglycan.

Biosynthesis of peptidoglycan in Gaffkya homari: on the target(s) of benzylpenicillin.

The formation of acceptor for the N epsilon-(D-Ala)-acceptor transpeptidase is an essential feature of nascent peptidoglycan processing. In Gaffkya homari the synthesis of cross-bridges in peptidoglycan includes a variety of penicillin-sensitive enzymes, e.g., transpeptidase, DD-carboxypeptidase, and LD-carboxypeptidase. To determine the primary target, we grew cultures in the presence of the MICs of benzylpenicillin (0.2 microgram/ml), methicillin (10 micrograms/ml), cephalothin (5 micrograms/ml), and cefoxitin (25 micrograms/ml) and examined the monomer-dimer composition of each peptidoglycan by high-performance liquid chromatography after muramidase digestion. From these studies it was recognized that of all the dimers, the synthesis of the predominant cross-bridge, diamidated octapeptide (-Ala-iso-D-Gln-Lys-D-Ala -Ala-iso-D-Gln-Lys-D-Ala), is most sensitive to the action of the beta-lactam at its MIC. The enhanced deamidation of the acceptor tetrapeptide, one of the substrates for the transpeptidase, is correlated with the inhibition of this cross-bridge. For example, at the MIC of benzylpenicillin, the ratio of amidated tetrapeptide to nonamidated tetrapeptide decreased from 2.8 in the control to 1.0 in the treated culture. From these results it would appear that a decrease in preferred acceptor for the transpeptidase results in the inhibition of synthesis of this major cross-bridge. Thus, the metabolism of the amide function of the monomer peptides may represent an additional feature of processing in the assembly of cross-bridged dimers in the peptidoglycan of this organism that is sensitive to the action of beta-lactam.

Role of the D-alanyl carrier protein in the biosynthesis of D-alanyl-lipoteichoic acid.

D-Alanyl-lipoteichoic acid (D-alanyl-LTA) is a widespread macroamphiphile which plays a vital role in the growth and development of gram-positive organisms. The biosynthesis of this polymer requires the enzymic activation of D-alanine for its transfer to the membrane-associated LTA (mLTA). A small, heat-stable, and acidic protein that is required for this transfer was purified to greater than 98% homogeneity from Lactobacillus casei ATCC 7469. This protein, previously named the D-alanine-membrane acceptor ligase (V. M. Reusch, Jr., and F. C. Neuhaus, J. Biol. Chem. 246:6136-6143, 1971), functions as the D-alanyl carrier protein (Dcp). The amino acid composition, beta-alanine content, and N-terminal sequence of this protein are similar to those of the acyl carrier proteins (ACPs) of fatty acid biosynthesis. The isolation of Dcp and its derivative, D-alanyl approximately Dcp, has allowed the characterization of two novel reactions in the pathway for D-alanyl-mLTA biosynthesis: (i) the ligation of Dcp with D-alanine and (ii) the transfer of D-alanine from D-alanyl approximately Dcp to a membrane acceptor. It has not been established whether the membrane acceptor is mLTA or another intermediate in the pathway for D-alanyl-mLTA biosynthesis. Since the D-alanine-activating enzyme (EC 6.1.1.13) catalyzes the ligation reaction, this enzyme functions as the D-alanine-Dcp ligase (Dcl). Dcl also ligated the ACPs from Escherichia coli, Vibrio harveyi, and Saccharopolyspora erythraea with D-alanine. In contrast to the relaxed specificity of Dcl in the ligation reaction, the transfer of D-alanine to the membrane acceptor was highly specific for Dcp and did not occur with other ACPs. This transfer was observed by using only D-[14C]alanyl approximately Dcp and purified L. casei membranes. Thus, D-alanyl approximately Dcp is an essential intermediate in the transfer of D-alanine from Dcl to the membrane acceptor. The formation of D-alanine esters of mLTA provides a mechanism for modulating the net anionic charge in the cell wall.

Biosynthesis of peptidoglycan in Gaffkya homari: role of the peptide subunit of uridine diphosphate-N-acetylmuramyl-pentapeptide.

The incorporation of N-acetylmuramyl (MurNAc)-peptides from nucleotide-activated precursors (reference: uridine diphosphate [UDP]MurNAc-Ala(1)-dGlu(2)-Lys(3)- dAla(4)-dAla(5)) with incomplete or modified peptide subunits into peptidoglycan was studied with membrane preparations from Gaffkya homari. The effectiveness of their utilization at low and high concentrations was compared on the basis of the values of V(max)/K(m) and V(max), respectively. At low concentration, replacement of alanine by glycine in position 5 has a small effect on the activity of the peptidoglycan synthesizing system, whereas it has a significantly larger effect in positions 1 and 4. The importance of d-alanine in position 4 at low substrate concentrations is also observed with the incomplete UDP-MurNAc-peptides. For UDP-MurNAc-tripeptide and -tetrapeptide, V(max)/K(m) is 0.06 and 0.55, respectively, of the value for the -pentapeptide. At high substrate concentration, replacement of d-alanine by glycine in either position 1 or 5 decreases the activity to 0.37 of the value for the reference nucleotide, whereas replacement in position 4 has a smaller effect (0.74). The profiles established from V(max) and V(max)/K(m) with UDP-MurNAc-tripeptide, -tetrapeptide, and -pentapeptide show good correlation. At low concentration the specificity profiles of phospho-MurNAc-pentapeptide translocase, catalyzing the initial membrane reaction, are similar to those for the peptidoglycan synthesizing system; at high concentration, however, the profiles differ. The translocase appears to provide a primary specificity barrier at high substrate concentration for UDP-MurNAc-Ala-dGlu-Lys-dAla-dAla and UDP-MurNAc-Ala-dGlu-Lys-Gly-dAla, and at low concentration for UDP-MurNAc-Ala-dGlu-Lys and UDP-MurNAc-Ala-dGlu-Lys-Gly-dAla. Moreover, it is suggested that an additional specificity barrier exists in the peptidoglycan synthesizing system for certain nucleotides. Thus, the cytoplasmic enzymes and the membrane-associated enzyme(s) cooperate to insure the formation of functioning peptidoglycan in this organism.

On the mechanism of action of vancomycin: inhibition of peptidoglycan synthesis in Gaffkya homari.

Vancomycin inhibits the synthesis of peptidoglycan in membrane preparations from Gaffkya homari with uridine diphosphate-N-acetylmuramyl (UDP-Mur-NAc)-pentapeptide as substrate, but not with either UDP-MurNAc-tetrapeptide or UDP-MurNAc-tripeptide. These results are correlated with the specificity studies described by Perkins and Nieto for complex formation between the antibiotic and the peptide subunit. It is concluded that the formation of a complex between vancomycin and a postulated cell wall acceptor or between vancomycin and the enzymes involved in peptidoglycan synthesis does not contribute to the inhibitory action of this antibiotic. The mechanism of vancomycin action on peptidoglycan synthesis is clearly different from that of moenomycin and bacitracin. In the presence of these antibiotics, peptidoglycan synthesis is inhibited with both UDP-MurNAc-pentapeptide and -tetrapeptide as substrates. In addition, these results provide additional insight into the mechanism of phospho-MurNAc-pentapeptide translocase. For example, enhancement of the transfer of phospho-MurNAc-peptide from UDP-MurNAc-peptide to undecaprenyl-phosphate at low concentrations of vancomycin is observed with UDP-MurNAc-pentapeptide and not with -tetrapeptide. Complexation of vancomycin with undecaprenyl-diphosphate-MurNAc-pentapeptide, resulting in an ineffective intermediate, would increase the rate of transfer by preventing the reassociation of undecaprenyl-diphosphate-MurNAc-pentapeptide with the enzyme.

D-alanylation of lipoteichoic acid: role of the D-alanyl carrier protein in acylation.

The D-alanylation of membrane-associated lipoteichoic acid (LTA) in gram-positive organisms requires the D-alanine-D-alanyl carrier protein ligase (AMP) (Dcl) and the D-alanyl carrier protein (Dcp). The dlt operon encoding these proteins (dltA and dltC) also includes dltB and dltD. dltB encodes a putative transport system, while dltD encodes a protein which facilitates the binding of Dcp and Dcl for ligation with D-alanine and has thioesterase activity for mischarged D-alanyl-acyl carrier proteins (ACPs). In previous results it was shown that D-alanyl-Dcp donates its ester residue to membrane-associated LTA (M. P. Heaton and F. C. Neuhaus, J. Bacteriol. 176: 681-690, 1994). However, all efforts to identify an enzyme which catalyzes this D-alanylation process were unsuccessful. It was discovered that incubation of D-alanyl-Dcp in the presence of LTA resulted in the time-dependent hydrolysis of this D-alanyl thioester. D-Alanyl-ACP in the presence of LTA was not hydrolyzed. When Dcp was incubated with membrane-associated D-alanyl LTA, a time and concentration-dependent formation of D-alanyl-Dcp was found. The addition of NaCl to this reaction inhibited the formation of D-alanyl-Dcp and stimulated the hydrolysis of D-alanyl-Dcp. Since these reactions are specific for the carrier protein (Dcp), it is suggested that Dcp has a unique binding site which interacts with the poly(Gro-P) moiety of LTA. It is this specific interaction that provides the functional specificity for the D-alanylation process. The reversibility of this process provides a mechanism for the transacylation of the D-alanyl ester residues between LTA and wall teichoic acid.

Changes in wall teichoic acid during the rod-sphere transition of Bacillus subtilis 168.

Wall teichoic acid (WTA) is essential for the growth of Bacillus subtilis 168. To clarify the function of this polymer, the WTAs of strains 168, 104 rodB1, and 113 tagF1 (rodC1) grown at 32 and 42 degrees C were characterized. At the restrictive temperature, the rodB1 and tagF1 (rodC1) mutants undergo a rod-to-sphere transition that is correlated with changes in the WTA content of the cell wall. The amount of WTA decreased 33% in strain 104 rodB1 and 84% in strain 113 tagF1 (rodC1) when they were grown at the restrictive temperature. The extent of alpha-D-glucosylation (0.84) was not affected by growth at the higher temperature in these strains. The degree of D-alanylation decreased from 0.22 to 0.10 in the rodB1 mutant but remained constant (0.12) in the tagF1 (rodC1) mutant at both temperatures. Under these conditions, the degree of D-alanylation in the parent strain decreased from 0.27 to 0.21. The chain lengths of WTA in strains 168 and 104 rodB1 grown at both temperatures were approximately 53 residues, with a range of 45 to 60. In contrast, although the chain length of WTA from the tagF1 (rodC1) mutant at 32 degrees C was similar to that of strains 168 and 104 rodB1, it was approximately eight residues at the restrictive temperature. The results suggested that the rodB1 mutant is partially deficient in completed poly(glycerophosphate) chains. The precise biochemical defect in this mutant remains to be determined. The results for strain 113 tagF1(rodC1) are consistent with the temperature-sensitive defect in the CDP-glycerol:poly(glycerophosphate) glycerophosphotransferase (H. M. Pooley, F.-X. Abellan, and D. Karamata, J. Bacteriol. 174:646-649, 1992).

Fluorescent substrate for nascent peptidoglycan synthesis. Uridine diphosphate-N-acetylmuramyl-(Nepsilon-5-dimethylaminonaphthalene-1-sulfonyl)pentapeptide.

The synthesis of UDP-MurNAc-Ala-DGlu-Lys[Nepsilon-dimethylaminonaphthalene sulfonyl (Dns)]-DAla-DAla provides a method for the specific introduction of a fluorescent reporter group into the membrane environment of nascent peptidoglycan synthesis. To assess the degree of perturbation of this environment caused by the introduction of the dansyl substituent, this nucleotide was compared with UDP-MurNAc-Ala-DGlu-Lys-DAla-DAla in the reaction catalyzed by phospho-MurNAc-pentapeptide translocase (UDP-MurNAc-Ala-gammaDGlu-Lys-DAla-DAla:undecaprenyl phosphate phospho-MurNA-C-pentapeptide transferase) and in the membrane-associated synthesis of nascent peptidoglycan. Phospho-MurNAc-pentapeptide translocase in membrane fragments from Staphylococcus aureus Copenhagen catalyzed the transfer of phospho-MurNAc-Ala-DGlu-Lys(Nepsilon-Dns)-DAla-DAla to undecaprenyl phosphate with a Vmax/Km of 3.8 and a Vmax of 1.6 times the values for UDP-MurNAc-pentapeptide. In the exchange reaction catalyzed by the translocase, the Rmax/Km and Rmax for the dansylated substrate were 1.8 and 0.78 times the respective values for the reference nucleotide. The equilibrium constant for the transfer reaction utilizing UDP-MurNAc-(Nepsilon-Dns)pentapeptide was 5.9 +/- 0.13 compared to 1.1 +/- 0.02 for UDP-MurNAc-pentapeptide. With respect to the proposed reaction model (Pless, D. D., and Neuhaus, F. C. (1973) J. Biol. Chem. 248, 1568-1576), the increase in Keq is consistent with a decrease in the affinity of undecaprenyl diphosphate-MurNAc-Ala-DGlu-Lys(Nepsilon-Dns)-DAla-DAla for the translocase. The fluorescence emission maximum of the phospho-MurNAc-(Nepsilon-Dns)pentapeptide moiety of UDP-MurNAc-(Nepsilon-Dns)pentapeptide was blue-shifted from 525 to 495 nm upon transfer from UMP to undecaprenyl phosphate with a 6-fold increase in quantum yield. These spectral changes provided a sensitive and continuous assay for the formation of undecaprenyl diphosphate-MurNAc-Ala-DGlu-Lys(Nepsilon-Dans)-DAla-DAla. The nascent peptidoglycan synthesizing system from Gaffkya homari utilized the dansylated nucleotide with a Vmax/Km of 0.05 and a Vmax of 0.10 times the values for UDP-MurNAc-pentapeptide. These results demonstrate that phospho-MurNAc-Ala-DGlu-Lys(Nepsilon-Dns)-DAla-DAla linked to the undecaprenyl phosphate will serve as a precursor for the synthesis of nascent peptidoglycan and that the dansyl moiety will report on the membrane environment it experiences during this synthesis.

Mechanism of D-cycloserine action: alanine racemase from Escherichia coli W.

The antibiotic d-cycloserine is an effective inhibitor of alanine racemase. The lack of inhibition by l-cycloserine of alanine racemase from Staphylococcus aureus led Roze and Strominger to formulate the cycloserine hypothesis. This hypothesis states that d-cycloserine has the conformation required of the substrates on the enzyme surface and that l-cycloserine cannot have this conformation. Alanine racemase from Escherichia coli W has been examined to establish whether these observations are a general feature of all alanine racemases. The enzyme (molecular weight = 95,000) has Michaelis-Menten constants of 4.6 x 10(-4)m and 9.7 x 10(-4)m for d- and l-alanine, respectively. The ratio of V(max) in the d- to l-direction is 2.3. The equilibrium constant calculated from the Haldane relationship is 1.11 +/- 0.15. Both d- and l-cycloserine are competitive inhibitors with constants (K(i)) of 6.5 x 10(-4)m and 2.1 x 10(-3)m, respectively. The ratio of K(m)d-alanine to K(i)d-cycloserine is 0.71, and the ratio of K(m)l-alanine to K(i)l-cycloserine is 0.46. Since l-cycloserine is an effective inhibitor, it is concluded that the cycloserine hypothesis does not apply to the enzyme from E. coli W.

Factors affecting the level of alanine racemase in Escherichia coli.

Alanine racemase occupies a key position in the alanine branch of peptidoglycan biosynthesis. The level of this enzyme in Escherichia coli W is a function of the carbon source. For example, growth on l-alanine causes a 25-fold higher level of alanine racemase when compared with growth on glucose. When potential inducers of this enzyme are added to either a glucose or succinate medium, a low specificity is observed with those compounds that cause higher levels of enzyme. Growth of E. coli W on either pyruvate, d-alanine, or l-alanine resulted in lower levels of l- and d-alanine in the internal pool. With each of these carbon sources, the level of alanine racemase was markedly elevated when compared to glucose-grown cells; thus, with single carbon sources, the concentration of alanine in the pool is inversely related to the specific activity of alanine racemase. These observations support derepression as a possible mechanism that gives rise to higher levels of alanine racemase. Since multiple forms of the alanine racemase were not detected in extracts from E. coli W grown on various carbon sources, it would appear that this type of heterogeneity is not a consideration in interpreting the above results.

Biosynthesis of D-alanyl-lipoteichoic acid: characterization of ester-linked D-alanine in the in vitro-synthesized product.

d-Alanyl-lipoteichoic acid (d-alanyl-LTA) contains d-alanine ester residues which control the ability of this polyer to chelate Mg(2+). In Lactobacillus casei a two-step in vitro reaction sequence catalyzed by the d-alanine-activating enzyme and d-alanine:membrane acceptor ligase incorporates d-alanine into membrane acceptor. In this paper we provide additional evidence that the in vitro system catalyzes the covalent incorporation of d-[(14)C]alanine into membrane acceptor which is the poly([(3)H]glycerol phosphate) moiety of d-alanyl-LTA. This conclusion was supported by the observation that the d-[(14)C]alanine and [(3)H]glycerol labels of the partially purified product were co-precipitated by antiserum containing globulins specific for poly(glycerol phosphate). The isolation of d-[(14)C]alanyl-[(3)H]glycerol from d-[(14)C]alanine.[(3)H]glycerol-labeled d-alanyl-LTA synthesized in the in vitro system indicated that the d-alanine was linked to the poly(glycerol phosphate) chain of the LTA. A comparison of the reactivities of the d-alanine residues of d-alanyl-glycerol and d-alanyl-LTA supported the conclusion that the incorporated residue of d-alanine was attached by an ester linkage. Thus, the data indicated that the in vitro system catalyzes the incorporation of d-alanine covalently linked by ester linkages to the glycerol moieties of the poly(glycerol phosphate) chains of d-alanyl-LTA. New procedures are presented for the partial purification of d-alanyl-LTA with a high yield of ester-linked d-alanine and for the sequential degradation of the poly(glycerol phosphate) moiety substituted with d-alanine of d-alanyl-LTA with phosphodiesterase II/phosphatase from Aspergillus niger.