IlvHI locus of Salmonella typhimurium

Crystallographic Structures of IlvN·Val/Ile Complexes: Conformational Selectivity for Feedback Inhibition of Aceto Hydroxy Acid Synthases

Conformational factors that predicate selectivity for valine or isoleucine binding to IlvN leading to the regulation of aceto hydroxy acid synthase I (AHAS I) of Escherichia coli have been determined for the first time from high-resolution (1.9-2.43 Å) crystal structures of IlvN·Val and IlvN·Ile complexes. The valine and isoleucine ligand binding pockets are located at the dimer interface. In the IlvN·Ile complex, among residues in the binding pocket, the side chain of Cys43 is 2-fold disordered (χ1 angles of gauche- and trans). Only one conformation can be observed for the identical residue in the IlvN·Val complexes. In a reversal, the side chain of His53, located at the surface of the protein, exhibits two conformations in the IlvN·Val complex. The concerted conformational switch in the side chains of Cys43 and His53 may play an important role in the regulation of the AHAS I holoenzyme activity. A significant result is the establishment of the subunit composition in the AHAS I holoenzyme by analytical ultracentrifugation. Solution nuclear magnetic resonance and analytical ultracentrifugation experiments have also provided important insights into the hydrodynamic properties of IlvN in the ligand-free and -bound states. The structural and biophysical data unequivocally establish the molecular basis for differential binding of the ligands to IlvN and a rationale for the resistance of IlvM to feedback inhibition by the branched-chain amino acids.

Biosynthesis and Regulation of the Branched-Chain Amino Acids†

This review focuses on more recent studies concerning the systems biology of branched-chain amino acid biosynthesis, that is, the pathway-specific and global metabolic and genetic regulatory networks that enable the cell to adjust branched-chain amino acid synthesis rates to changing nutritional and environmental conditions. It begins with an overview of the enzymatic steps and metabolic regulatory mechanisms of the pathways and descriptions of the genetic regulatory mechanisms of the individual operons of the isoleucine-leucine-valine (ilv) regulon. This is followed by more-detailed discussions of recent evidence that global control mechanisms that coordinate the expression of the operons of this regulon with one another and the growth conditions of the cell are mediated by changes in DNA supercoiling that occur in response to changes in cellular energy charge levels that, in turn, are modulated by nutrient and environmental signals. Since the parallel pathways for isoleucine and valine biosynthesis are catalyzed by a single set of enzymes, and because the AHAS-catalyzed reaction is the first step specific for valine biosynthesis but the second step of isoleucine biosynthesis, valine inhibition of a single enzyme for this enzymatic step might compromise the cell for isoleucine or result in the accumulation of toxic intermediates. The operon-specific regulatory mechanisms of the operons of the ilv regulon are discussed in the review followed by a consideration and brief review of global regulatory proteins such as integration host factor (IHF), Lrp, and CAP (CRP) that affect the expression of these operons.

Interactions between large and small subunits of different acetohydroxyacid synthase isozymes of Escherichia coli

The large, catalytic subunits (LSUs; ilvB, ilvG and ilvI, respectively) of enterobacterial acetohydroxyacid synthases isozymes (AHAS I, II and III) have molecular weights approximately 60 kDa and are paralogous with a family of other thiamin diphosphate dependent enzymes. The small, regulatory subunits (SSUs) of AHAS I and AHAS III (ilvN and ilvH) are required for valine inhibition, but ilvN and ilvH can only confer valine sensitivity on their own LSUs. AHAS II is valine resistant. The LSUs have only approximately 15, <<1 and approximately 3%, respectively, of the activity of their respective holoenzymes, but the holoenzymes can be reconstituted with complete recovery of activity. We have examined the activation of each of the LSUs by SSUs from different isozymes and ask to what extent such activation is specific; that is, is effective nonspecific interaction possible between LSUs and SSUs of different isozymes? To our surprise, the AHAS II SSU ilvM is able to activate the LSUs of all three of the isozymes, and the truncated AHAS III SSUs ilvH-Delta80, ilvH-Delta86 and ilvH-Delta89 are able to activate the LSUs of both AHAS I and AHAS III. However, none of the heterologously activated enzymes have any feedback sensitivity. Our results imply the existence of a common region in all three LSUs to which regulatory subunits may bind, as well as a similarity between the surfaces of ilvM and the other SSUs. This surface must be included within the N-terminal betaalphabetabetaalphabeta-domain of the SSUs, probably on the helical face of this domain. We suggest hypotheses for the mechanism of valine inhibition, and reject one involving induced dissociation of subunits.

DNA supercoiling and transcription control: a model from the study of suppression of the leu-500 mutation in Salmonella typhimurium topA- strains

DNA supercoiling is known to modulate gene expression. The functional relationship between DNA supercoiling and transcription initiation has been established genetically and biochemically. The molecular mechanism whereby DNA supercoiling regulates gene expression remains unclear however. Quite commonly, the same gene responds to the same DNA supercoiling change differently when the gene is positioned at different locations. Such strong positional effects on gene expression suggest that rather than the overall DNA supercoiling change, the variation of DNA supercoiling at a local site might be important for transcription control. We have started to understand the local DNA supercoiling dynamic on the chromosome. As a primary source of local DNA supercoiling fluctuation, transcription-driven DNA supercoiling is important in determining the chromosome supercoiling dynamic and theoretically, therefore, for transcription control as well. Indeed, by studying the coordinated expression of genes in the ilvIH-leuO-leuABCD gene cluster, we found that transcription-driven DNA supercoiling governs the expression of a group of functionally related genes in a sequential manner. Based on the findings in this model system, we put forward the possible mechanisms whereby DNA supercoiling plays its role in transcription control.

ppGpp-dependent leuO expression in bacteria under stress

Despite the known potential transcription regulatory role of leuO gene product, LeuO, the condition when leuO expresses during bacterial growth cycle remains unclear. Mechanistically, leuO expression was shown to be part of promoter relay mechanism, however, the factor(s) responsible for the regulation of leuO expression is not known. Combining Northern and Western results, we demonstrate in the present communication that leuO expression is normally low and enhanced when bacteria are in transition from exponential growth to stationary phase. The stationary phase-associated leuO expression is ppGpp dependent and rpoS (sigma(s) factor) independent.

Activation and silencing of leu-500 promoter by transcription-induced DNA supercoiling in the Salmonella chromosome

The notion that transcription can generate supercoils in the DNA template largely stems from work with small circular plasmids. In the present work, we tested this model in the bacterial chromosome using a supercoiling-sensitive promoter as a functional sensor of superhelicity changes. The leu-500 promoter of Salmonella typhimurium is a mutant and inactive variant of the leucine operon promoter that regains activity if negative DNA supercoiling rises above normal levels, typically as a result of mutations affecting DNA topoisomerase I (topA mutants). Activation of the leu-500 promoter was analysed in topA mutant cells harbouring transcriptionally inducible tet or cat gene cassettes inserted in the region upstream from the leu operon. Some insertions inhibited leu-500 promoter activation in the absence of inducer. This effect is dramatic in the interval between 1.7 kb and 0.6 kb from the leu operon, suggesting that the insertions physically interfere with the mechanism responsible for activation. Superimposed on these effects, transcription of the inserted gene stimulated or inhibited leu-500 promoter activity depending on whether this gene was oriented divergently from the leu operon or in the same direction respectively. Interestingly, transcription-mediated inhibition of leu-500 promoter was observed with inserts as far as 5 kb from the leu operon, and it could be relieved by the introduction of a strong gyrase site between the inserted element and the leu-500 promoter. These results are consistent with the idea that transcriptionally generated positive and negative supercoils can diffuse along chromosomal DNA and, depending on their topological sign, elicit opposite responses from the leu-500 promoter.

Gene transfer between related bacteria by electrotransformation: mapping Salmonella typhi genes in Salmonella typhimurium

Transfer of newly isolated mutations into a fresh background is an essential step of genetic analysis and strain construction. Gene transfer is hampered in Salmonella typhi and in other pathogenic bacteria by the lack of a generalized transduction system. We show here that this problem can be partially circumvented by using electrotransformation as a means for delivering S. typhi DNA into suitable S. typhi or Salmonella typhimurium recipients. Transferred DNA can recombine with the homologous region in the host chromosome. In one application of the method, mutations isolated in S. typhi were genetically mapped in S. typhimurium.

Functional analysis of YCL09C: evidence for a role as the regulatory subunit of acetolactate synthase

We have analysed the function of the open reading frame (ORF) YCL09C. The deletion of this ORF from chromosome III does not affect the physiology of the corresponding yeast strain enough to give a distinct phenotype. Nevertheless a computational analysis reveals high homology between this ORF and the enterobacterial genes encoding the regulatory subunit of acetolactate synthase. We have therefore tested the possibility that yc109cp is the regulatory subunit of yeast acetolactate synthase by in vitro enzymatic analysis. The acetolactate synthase was previously shown to be retroinhibited by its final product valine. In Escherichia coli this retro-control is assured by the regulatory subunit. Using a yeast strain carrying a complete deletion of YCL09C, we have observed the loss of such retro-inhibition. These results together with the computational predictions show that YCL09C encodes the regulatory subunit of yeast acetolactate synthase.

Silent genes in bacteria: the previously designated 'cryptic' ilvHI locus of 'Salmonella typhimurium LT2' is active in natural isolates

Gene ilvG in Escherichia coli K-12 and ilvI in 'Salmonella typhimurium LT2' (S. enterica serotype Typhimurium, strain LT2) are inactive due to frameshift or nonsense mutations, respectively. These inactive genes have been suggested to be part of 'cryptic' genetic systems which are defined as being of long-term regulatory and evolutionary significance. We have shown that the nonsense mutation in ilvI is present only in derivatives of the laboratory strain 'S. typhimurium LT2'. All natural isolates of Salmonella examined have an arginine codon at the corresponding location of their ilvI sequences. Further, two randomly selected natural isolates of serotype Typhimurium are shown to each have an active ALS III isozyme. Our findings strongly suggest that the only Salmonella strains which lack a functional ilvHI locus are LT2 isolates. We suggest that the mutations leading to inactivation of both ilvI in 'S. typhimurium LT2' and ilvG in E. coli K-12 are more likely to have been acquired during laboratory storage and/or cultivation, rather than representing cryptic systems of gene regulation.

Long-range interaction between two promoters: activation of the leu-500 promoter by a distant upstream promoter

The leu-500 mutation can be suppressed in S. typhimurium topA. Previous studies have demonstrated that the plasmid-borne leu-500 minimal promoter cannot be activated in topA mutants unless adjacent (< 250 bp) transcription occurs away from the leu-500 promoter (short-range promoter interaction). To search for a potential upstream promoter responsible for activation of leu-500 in the chromosomal context, we have identified the ilvlH promoter, located 1.9 kb upstream of leu-500 (long-range promoter interaction). Different from short-range promoter interaction, which is abolished by DNA sequence insertions, the long-range promoter interaction is mediated by the intervening DNA sequence. These studies suggest that the long-range interaction between a pair of divergently arrayed promoters is probably mediated by a complex process involving relay of DNA supercoiling by the DNA sequence located between the two promoters.

The leucine-responsive regulatory protein, a global regulator of metabolism in Escherichia coli

The leucine-responsive regulatory protein (Lrp) regulates the expression of more than 40 genes and proteins in Escherichia coli. Among the operons that are positively regulated by Lrp are operons involved in amino acid biosynthesis (ilvIH, serA)), in the biosynthesis of pili (pap, fan, fim), and in the assimilation of ammonia (glnA, gltBD). Negatively regulated operons include operons involved in amino acid catabolism (sdaA, tdh) and peptide transport (opp) and the operon coding for Lrp itself (lrp). Detailed studies of a few members of the regulon have shown that Lrp can act directly to activate or repress transcription of target operons. A substantial fraction of operons regulated by Lrp are also regulated by leucine, and the effect of leucine on expression of these operons requires a functional Lrp protein. The patterns of regulation are surprising and interesting: in some cases activation or repression mediated by Lrp is antagonized by leucine, in other cases Lrp-mediated activation or repression is potentiated by leucine, and in still other cases leucine has no effect on Lrp-mediated regulation. Current research is just beginning to elucidate the detailed mechanisms by which Lrp can mediate such a broad spectrum of regulatory effects. Our view of the role of Lrp in metabolism may change as more members of the regulon are identified and their regulation characterized, but at this point Lrp seems to be important in regulating nitrogen metabolism and one-carbon metabolism, permitting adaptations to feast and to famine.

Purification and characterization of the valine sensitive acetolactate synthase from Serratia marcescens ATCC 25419

The valine sensitive acetolactate synthase (ALS) isozyme from Serratia marcescens ATCC 25419 was purified to homogeneity. Analysis of the native molecular weight of the purified enzyme by the native pore gradient polyacrylamide gel electrophoresis indicated the molecular weight of about 178,000 and sodium dodecyl sulfate-polyacrylamide gel electrophoresis showed the enzyme to be composed of two different types of subunits with molecular weights of 62,000 and 35,000. The molar ratio of the two polypeptides was estimated to be 1, suggesting that native enzyme is composed of two large subunits and two small subunits. The enzyme exhibits homotropic allosterism with pyruvate unlike other enteric ALS isozymes. The specificity ratio R (V[acetohydroxybutyrate]/V[acetolactate] = R.[alpha-ketobutyrate]/pyruvate]), of the enzyme was found to be 0 suggesting that the Serratia ALS has very high specificity for pyruvate. The pH optimum was around 7.5, and the enzyme was stable at 50 degrees C for 30 min. The pI value for the purified enzyme was 5.2. The concentration of branched chain amino acids for 50% inhibition of the enzyme was 0.1 mM for valine, and 1 mM for leucine and isoleucine, respectively.

Organization of Lrp-binding sites upstream of ilvIH in Salmonella typhimurium

Lrp, a major regulatory protein in Escherichia coli, controls the expression of numerous operons, including ilvIH. Lrp binds to six sites upstream of ilvIH, and Lrp binding is required for ilvIH expression. We show here that an Lrp-like protein is also present in Salmonella typhimurium. This protein can bind both E. coli and S. typhimurium ilvIH DNA, as can E. coli Lrp. Methidiumpropyl-EDTA footprinting studies were performed with purified E. coli Lrp and S. typhimurium ilvIH DNA. Six binding sites were defined, three of them being similar to corresponding sites in E. coli, and three being organized differently. A consensus derived from six S. typhimurium sites is compatible with that derived from a similar analysis of E. coli sequences.

Mutations affecting the ability of Escherichia coli Lrp to bind DNA, activate transcription, or respond to leucine

Lrp is a regulatory protein in Escherichia coli that increases expression of some operons and decreases expression of others. Mutations in Lrp were isolated on the basis of their effects on ilvIH, one of the operons regulated positively by Lrp. The ilvIH operon encodes an enzyme involved in the biosynthesis of leucine, valine, and isoleucine, and expression of this operon is repressed when cells are grown in the presence of leucine. Three groups of mutants were isolated. Mutant strains that were resistant to the repressive effects of leucine were termed leucine response mutants. These mutants had changes in the Lrp amino acid sequence between amino acid residues 108 and 149. Mutant strains having low expression of ilvIH in vivo were identified as colonies having reduced expression of a reporter gene. For some of these mutants, called DNA-binding mutants, binding to ilvIH DNA in vitro was markedly reduced. The mutations in these strains caused changes in Lrp between amino acids 16 and 70. Six of ten of these mutations were within a region having a putative helix-turn-helix motif. A third group of mutants had low ilvIH expression in vivo but apparently normal DNA binding in vitro. These mutants were called activation mutants since they affected the ability of Lrp to activate expression. Lrp from these strains had changes in amino acids between residues 76 and 125. This study suggests that Lrp has separate domains responsible for binding DNA, activating transcription, and responding to leucine.

Sequence and evolution of the FruR protein of Salmonella typhimurium: a pleiotropic transcriptional regulatory protein possessing both activator and repressor functions which is homologous to the periplasmic ribose-binding protein

The repressor of the fructose (fru) operon of Salmonella typhimurium (FruR) has been implicated in the transcriptional regulation of dozens of genes concerned with central metabolic pathways of carbon utilization. We here report the nucleotide sequence of the gene encoding FruR and analyse both its operator-promoter region and its deduced amino acyl sequence. The FruR protein was overexpressed and was shown to have a molecular weight of about 36 kDa in agreement with the molecular weight deduced from the gene sequence. Sequence analyses revealed that FruR is homologous to 9 distinct bacterial DNA-binding proteins, most of which recognize sugar inducers and all of which possess helix-turn-helix motifs within their N-terminal regions and exhibit sequence identity throughout most of their lengths. FruR is also homologous to the periplasmic ribose-binding protein which serves as a constituent of the ribose transport/chemoreception system. The ribose-binding protein is in turn homologous to binding proteins specific for arabinose and galactose. The periplasmic binding proteins, the structures of some of which have been elucidated in three dimensions, lack the N-terminal helix-turn-helix region, but instead possess N-terminal hydrophobic signal sequences which target them to the periplasm. A phylogenetic tree for the more closely related proteins of this superfamily was constructed, and a signature motif was identified which should facilitate future detection of additional transcriptional regulatory proteins belonging to this family.

Evidence for isoleucine as a positive effector of the ilvBN operon in Salmonella typhimurium

Concerted efforts were directed towards understanding the control of acetohydroxy acid synthase (AHAS) in the gyrB mutant hisU1820 of Salmonella typhimurium. A media shift from valine to valine plus isoleucine causes a dramatic 4 to 5 fold burst of AHAS valine sensitive activity which appears to be dependent on translation. DJ19, an isolated valine sensitive derivative of the gyrB mutant, maintains a dramatic increase in AHAS valine sensitive activity upon the addition of isoleucine to valine supplemented cultures, suggesting that the isoleucine effect is specific for valine sensitive AHAS. Evidence supports isoleucine as a positive effector on valine sensitive AHAS expression and that the gyrB mutation accentuates the isoleucine effect.

Absence of acetohydroxy acid synthase III in Salmonella typhimurium is due to early termination of translation within the ilvl gene

The cryptic ilvlH locus of Salmonella typhimurium has genetic information for two distinct subunits of acetohydroxy acid synthase III. We show that the ilvH-encoded subunit is normally translated and the lack of activity is due to early termination of translation within the promoter-proximal ilvl gene. Analysis of the 5' region of the operon led to identification of the promoter and the amino-terminal part of ilvl. Expression of this gene in a mutant producing acetohydroxy acid synthase is due to a transversion which creates a UUA (leucine) codon in the place of a UGA (stop) codon present in position 12 of the wild-type coding region.

Nucleotide sequence of the ilvH-fruR gene region of Escherichia coli K12 and Salmonella typhimurium LT2

We have sequenced the fruR gene and flanking DNA fragments from Escherichia coli K12 and Salmonella typhimurium LT2. The fruR gene codes for a protein that represses the fru operon and activates the pps gene for PEP synthase. The corresponding open reading frame (ORF) FruR consists of 334 amino acid residues. The ORF contains an amino-terminal helix-turn-helix motif, characteristic of DNA-binding proteins and has similarity to known repressor proteins. The sequence is identical to that of the E. coli shl gene (mnemonic for suppressor-H-linked phenotype). It is flanked upstream by the ilvIH genes and downstream by the pbpB gene in both organisms and by orfB, a gene possibly involved in the regulation of cell division.

Alkylation of acetohydroxyacid synthase I from Escherichia coli K-12 by 3-bromopyruvate: evidence for a single active site catalyzing acetolactate and acetohydroxybutyrate synthesis

Acetohydroxyacid synthase I (AHAS I) purified from Escherichia coli K-12 was irreversibly inactivated by incubation with 3-bromopyruvate. Inactivation was specific, insofar as bromoacetate and iodoacetate were much less effective than bromopyruvate. Inactivation was accompanied by incorporation of radioactivity from 3-bromo[2-14C]pyruvate into acid-insoluble material. More than 95% of the incorporated radioactivity coelectrophoresed with the 60-kilodalton IlvB subunit of the enzyme through a sodium dodecyl sulfate-polyacrylamide gel; less than 5% coelectrophoresed with the 11.2-kilodalton IlvN subunit. The stoichiometry of incorporation at nearly complete inactivation was 1 mol of 14C per mol of IlvB polypeptide. These data indicate that bromopyruvate inactivates AHAS I by alkylating an amino acid at or near a single active site located in the IlvB subunit of the enzyme. We confirmed that this alkylation inactivated both AHAS reactions normally catalyzed by AHAS I. These results provide the first direct evidence that AHAS I catalyzes both acetohydroxybutyrate and acetolactate synthesis from the same active site.

Acetohydroxy acid synthase I is required for isoleucine and valine biosynthesis by Salmonella typhimurium LT2 during growth on acetate or long-chain fatty acids

Salmonella typhimurium LT2 normally expresses two acetohydroxy acid synthases (AHAS I and AHAS II). The function of AHAS I in this organism was unclear, since AHAS I-deficient (ilvBN) mutants of LT2 grew well on glucose or succinate minimal media, whereas AHAS II-deficient (ilvGM) mutants requried isoleucine for normal growth on glucose minimal media. We report that AHAS I-deficient mutants of S. typhimurium required isoleucine and valine for growth on acetate or oleate minimal media, whereas AHAS II-deficient mutants were able to grow on these media without isoleucine supplementation.

Effects of deletion and insertion mutations in the ilvM gene of Escherichia coli

A plasmid was constructed that carried the ilvG and ilvM genes and the associated promoter and leader regions derived from the K-12 strain of Escherichia coli. The ilvG gene contained a + 1 frameshift mutation that enabled the plasmid to specify acetohydroxyacid synthase II. The plasmid was modified by deletions in the terminus of and within the ilvM gene and by insertions into the ilvM gene. The effects of these modifications on the phenotypes of the plasmids were examined in a host strain that lacked all three isozymes of acetohydroxyacid synthase. Most of the ilvM mutant plasmids so obtained permitted growth of the host strain in the absence of isoleucine but not in the absence of valine. Growth in the presence of valine, however, was very slow. No significant acetohydroxyacid synthase activity could be detected even when the cells were grown in a valine-supplemented minimal medium. It thus appears that, at most, only a very low level of acetohydroxyacid synthase activity occurred with ilvG in the absence of ilvM and that low activity was more effective for acetohydroxy butyrate formation than for acetolactate formation. The ilvM gene product could be formed under the control of the lac promoter in the presence of a plasmid that carried an in-frame gene fusion between lacZ and the downstream portion of ilvG. Extracts from the host strain that contained such an IlvG(-)-IlvM+ plasmid could be combined with extracts from cells that contained one of the IlvG+-IlvM- plasmids to yield acetohydroxyacid synthase activity. Thus, the ilvM and ilvG genes could be expressed independently of each other.

Relationship between pseudo-HPr and the PEP: fructose phosphotransferase system in Salmonella typhimurium and Escherichia coli

We have studied in Salmonella typhimurium and Escherichia coli the properties of pseudo-HPr suppressor mutations. These mutations suppressed the defects in a ptsH mutant which lacks HPr, one of the enzymes of the phosphoenolpyruvate: carbohydrate phosphotransferase system. The suppressor mutation was mapped in S. typhimurium at 3 min, closely linked to leu. The corresponding chromosomal fragment of 1.7 kb from S. typhimurium and E. coli (extending clockwise from ilvH) was cloned. In a maxicell system a protein with an approximate molecular weight of 36,000 was synthesized. Pseudo-HPr suppressor mutations (fruR) and a deletion extending clockwise from leu resulted in the constitutive expression of the fru operon containing the genes for IIFru (fruA), IIIFru (fruB), fructose 1-phosphate kinase (fruK) and pseudo-HPr (fruF). fruR probably codes for a repressor of the fru operon. Tn10 mutagenesis revealed the following order of genes in the fru operon: fruB-(fruK, fruF)-fruA. Pseudo-HPr activity could replace HPr in PEP-dependent phosphorylation of PTS carbohydrates. IIIFru could be phosphorylated both via HPr and pseudo-HPr, since mutants lacking pseudo-HPr activity were still able to phosphorylate fructose in the presence of added HPr. Both the pseudo-HPr suppressor mutations at 3 min and the deletion extending from leu had an additional phenotype. Introduction of these mutations or deletions was always accompanied by disappearance of PEP synthase activity. Complementation of such a mutant with the cloned fragments reversed both phenotypes at the same time. Possibly, the fruR gene product acts as an activator of the gene coding for PEP synthase.

Role of small subunit (IlvN polypeptide) of acetohydroxyacid synthase I from Escherichia coli K-12 in sensitivity of the enzyme to valine inhibition

Most of the coding sequence for the IlvN polypeptide subunit of acetohydroxyacid synthase I was deleted from the ilvB+ ilvN+ plasmid pTCN12 by in vitro methods. Several ilvB+ delta ilvN derivatives of pTCN12 were identified among transformants of a strain otherwise lacking any acetohydroxyacid synthase. Deletion derivatives produced an enzymatically active IlvB polypeptide, as shown by the Ilv+ phenotype of transformed cells and by immunologic and enzymatic assays. However, whereas the growth of pTCN12 transformants was sensitive to valine inhibition, growth of the ilvB+ delta ilvN transformants was relatively resistant. Moreover, in vitro analyses confirmed that both acetolactate and acetohydroxybutyrate synthesis in extracts of the ilvB+ delta ilvN transformants was resistant to valine inhibition, in comparison with that in extracts of pTCN12 transformants or with that catalyzed by purified acetohydroxyacid synthase I. The IlvN polypeptide had a minimal effect, if any, on IlvB polypeptide accumulation as measured by immunoprecipitation, but its absence resulted in a greater than 10-fold reduction in enzyme specific activity.

Acetohydroxy acid synthase I, a required enzyme for isoleucine and valine biosynthesis in Escherichia coli K-12 during growth on acetate as the sole carbon source

Escherichia coli K-12 has two acetohydroxy acid synthase (AHAS) isozymes (AHAS I and AHAS III). Both of these isozymes catalyze the synthesis of alpha-aceto-alpha-hydroxybutyrate and alpha-acetolactate, which are key intermediates of the isoleucine-valine biosynthetic pathway. Strains lacking either isozyme but not both activities have been previously shown to grow well in minimal media in the absence of isoleucine and valine on any of several commonly used carbon sources (e.g., glucose or succinate). We report the characterization of mutants that were unable to grow on either acetate or oleate as a sole carbon source due to a defect in isoleucine-valine biosynthesis. The defect in isoleucine-valine biosynthesis was expressed only on these carbon sources and was due to the loss of AHAS I activity, resulting from lesions in the ilvBN operon. Previously identified ilvBN mutant strains also failed to grow on acetate or oleate minimal media. Our results indicated that AHAS I is an essential enzyme for isoleucine and valine biosynthesis when E. coli K-12 is grown on acetate or oleate as the sole carbon source. AHAS III was expressed during growth on acetate or oleate but was somehow unable to produce sufficient amounts of alpha-aceto-alpha-hydroxybutyrate and alpha-acetolactate to allow growth.

Purification and properties of Salmonella typhimurium acetolactate synthase isozyme II from Escherichia coli HB101/pDU9

A facile purification has been devised for recombinantly produced Salmonella typhimurium acetolactate synthase isozyme II. Purification of the enzyme was made possible by determining the complex set of factors that lead to loss of enzymic activity with this rather labile enzyme. When complexed with thiamin pyrophosphate, FAD, and magnesium, acetolactate synthase is subject to oxygen-dependent inactivation, a property not shared by the enzyme-FAD complex. When divorced from all of its tightly bound cofactors, losses of the enzymic activity are encountered at low ionic strength, especially at low protein concentrations. If purified and stored as the enzyme-FAD complex, acetolactate synthase is quite stable. The enzyme is composed of two types of subunits, a result that was not anticipated from previous studies of ilvG (the gene that codes for the large subunit of acetolactate synthase). These subunits were determined to be in equal molar ratio in the purified enzyme from the distribution of radioactivity between the two subunits after carboxymethylation with iodo[14C]acetate and their respective amino acid compositions. Besides the expected ilvG gene product (59.3 kDa), purified acetolactate synthase contained a smaller subunit (9.7 kDa; designated here as the ilvM gene product). On the basis of sequence homology of the small subunit with that coded for by the corresponding Escherichia coli gene sequence [Lawther, R. P., Calhoun, D. H., Adams, C. W., Hauser, C. A., Gray, J., & Hatfield, G. W. (1981) Proc. Natl. Acad. Sci. U.S.A. 78, 922-925], it is encoded by the region between ilvG and ilvE, beginning at base-pair (bp) 1914 (relative to the point of transcription initiation).(ABSTRACT TRUNCATED AT 250 WORDS)

The ilvB locus of Escherichia coli K-12 is an operon encoding both subunits of acetohydroxyacid synthase I

The ilvB locus of Escherichia coli K-12 encloses two open reading frames defining polypeptides of 60,000 and 11,200 molecular weight. The entire locus, about 2.3 kb, is co-transcribed as an operon. The molecular weights and amino acid compositions of the presumptive operon polypeptides agree with those of the large and small subunit polypeptides of acetohydroxyacid synthase (AHAS) I, for which ilvB is the structural locus. We reserve the designation ilvB for the promoter proximal (longer) cistron and designate the promoter distal cistron ilvN. The molecular weight and amino acid sequence of the ilvB polypeptide are strikingly similar to those of the I1vI (larger subunit of AHAS III) and I1vG (larger subunit of AHAS II) polypeptides. There is less size uniformity among the I1vN, I1vH (smaller subunit of AHAS III), and I1vM (smaller subunit of AHAS II) polypeptides. Nevertheless, there is significant amino acid sequence homology among the three small subunit polypeptides. Thus, all three AHAS isozymes of E. coli K-12 probably have a common evolutionary origin.

Characterization of the 3' end of the leucine operon of Salmonella typhimurium

The nucleotide sequence of the leuD gene of Salmonella typhimurium and of the downstream flanking region are presented. S1 mapping experiments identified 3' endpoints of leu mRNA 140 and 285 nucleotides downstream of the UAA stop codon of leuD mRNA. Experiments employing pulse-labeled RNA suggest that these endpoints result from transcription termination rather than RNA processing. Our results indicate that the organization of the 3' non-translated region of the leu operon from S. typhimurium resembles that of the trp operon of Escherichia coli. Further, our results suggest that the leu operon of S. typhimurium does not contain structural genes other than those identified by genetic experiments, i.e. leu, A,B,C and D.

The ilvIH operon of Escherichia coli K-12. Identification of the gene products and recognition of the translational start by polypeptide microsequencing

The ilvI and ilvH gene products were identified physically by electrophoretic analysis of in vivo-labelled polypeptides produced in minicells from plasmids carrying the wild-type ilvIH operon of Escherichia coli K-12 and derivatives of it. An analysis of the distribution of methionine residues in the amino-terminal portion of micro-quantities of the ilvI product eluted from gel showed that the translational start of the ilvI gene is the promoter-proximal one of three putative methionine codons predicted from the DNA sequence.

Purification and subunit composition of acetohydroxyacid synthase I from Escherichia coli K-12

Acetohydroxyacid synthase I from Escherichia coli K-12 has been purified to near homogeneity. Analysis of the purified enzyme by sodium dodecyl sulfate-polyacrylamide gel electrophoresis showed the presence of two polypeptides, one with a molecular weight of 60,000 and one with a molecular weight of 9,500. These two polypeptides were present in constant proportion to each other and to enzyme activity. The molar ratio of the two polypeptides (Mr 9,500:60,000), estimated from stained polyacrylamide gels, was 1. Antisera raised against the 60,000 Mr polypeptide precipitated both the 60,000 and the 9,500 Mr polypeptides from extracts of cells labeled with [35S]methionine. The addition of sodium dodecyl sulfate before immunoprecipitation eliminated the smaller polypeptide, and only the larger one was recovered. The hydrodynamic properties of the native enzyme confirmed a previous report that the largest enzymatically active species has a molecular weight of about 200,000; this species contains both the 60,000- and 9,500-molecular-weight polypeptides.