Threonine Locus of Escherichia coli K-12: Genetic Structure and Evidence for an Operon

Three genes, thrA, thrB, and thrC, were previously defined and localized in the threonine locus of Escherichia coli K-12. thrA, thrB, and thrC specify the enzymes aspartokinase I-homoserine dehydrogenase I, homoserine kinase, and threonine synthetase, respectively. A complementation analysis of the threonine cluster using derivatives of a lambda phage carrying the threonine genes (lambdadthr(c)) demonstrates that: (i) thrB and thrC each consist of a single cistron; and (ii) thrA is composed of two cistrons, thrA(1) and thrA(2), although it specifies a single polypeptide chain. thrA(1) and thrA(2) correspond to aspartokinase I and homoserine dehydrogenase I, respectively. Their relative order is established. The demonstration of polar effects of mutations (nonsense or induced by phage Mu) in thrA and thrB is taken as evidence for the existence of a thrA thrB thrC operon, transcribed in this order.     

Transductional construction of a threonine-hyperproducing strain of Serratia marcescens: lack of feedback controls of three aspartokinases and two homoserine dehydrogenases

To construct a threonine-hyperproducing strain of Serratia marcescens Sr41, the six regulatory mutations for three aspartokinases and two homoserine dehydrogenases were combined in a single strain by three transductional crosses. The constructed strain, T-1026, carried the lysC1 mutation leading to lack of feedback inhibition and repression of aspartokinase III, the thrA1(1) mutation desensitizing aspartokinase I to feedback inhibition, the thrA2(1) mutation releasing feedback inhibition of homoserine dehydrogenase I, the two hnr mutations derepressing aspartokinase I and homoserine dehydrogenase I, and the etr-1 mutation derepressing aspartokinase II and homoserine dehydrogenase II. The strain produced ca. 40 mg of threonine per ml of medium containing sucrose and urea. Furthermore, the productivity of strain T-1026 was compared with those of strains devoid of more than one of the six regulatory mutations.     

Transductional construction of a threonine-hyperproducing strain of Serratia marcescens: lack of feedback controls of three aspartokinases and two homoserine dehydrogenases.

To construct a threonine-hyperproducing strain of Serratia marcescens Sr41, the six regulatory mutations for three aspartokinases and two homoserine dehydrogenases were combined in a single strain by three transductional crosses. The constructed strain, T-1026, carried the lysC1 mutation leading to lack of feedback inhibition and repression of aspartokinase III, the thrA1(1) mutation desensitizing aspartokinase I to feedback inhibition, the thrA2(1) mutation releasing feedback inhibition of homoserine dehydrogenase I, the two hnr mutations derepressing aspartokinase I and homoserine dehydrogenase I, and the etr-1 mutation derepressing aspartokinase II and homoserine dehydrogenase II. The strain produced ca. 40 mg of threonine per ml of medium containing sucrose and urea. Furthermore, the productivity of strain T-1026 was compared with those of strains devoid of more than one of the six regulatory mutations.     

Nucleotide sequence of the Serratia marcescens threonine operon and analysis of the threonine operon mutations which alter feedback inhibition of both aspartokinase I and homoserine dehydrogenase I.

The nucleotide sequence of the Serratia marcescens threonine operon (thrA1A2BC) was determined. Three long open reading frames were identified; these open reading frames code for aspartokinase I (AKI)-homoserine dehydrogenase I (HDI), homoserine kinase, and threonine synthase, in that order. The predicted amino acid sequences of these enzymes were similar to the amino acid sequences of the corresponding enzymes in Escherichia coli. The AKI-HDI protein is apparently a tetramer composed of monomer polypeptides that are 819 amino acids long. A deletion analysis revealed that the central and C-terminal region was responsible for threonine-resistant HDI activity, a monomeric fragment extending from the N terminus to residue 306 was responsible for threonine-resistant AKI activity, and an N-terminal portion containing 468 residues was responsible for threonine-sensitive AKI activity. The thrA(1)1A(2)1 and thrA(1)5A(2)5 mutations of threonine-excreting strains HNr21 and TLr156, which result in the loss of threonine-mediated feedback inhibition of both AKI activity and HDI activity, cause single amino acid substitutions (Gly to Asp at position 330 and Ser to Phe at position 352, respectively) in the central region of the AKI-HDI protein. The thrA1+A(2)2 mutation of strain HNr59, which results in a threonine-sensitive AKI and a threonine-resistant HDI, also causes a single amino acid substitution (Ala to Thr at position 479).     

含苏氨酸操纵子重组质粒的构建及其对大肠杆菌L-苏氨酸积累的影响

摘要：【目的】通过分子生物学手段构建重组质粒,将其转入野生型大肠杆菌W3110,分析含苏氨酸操纵子基因的质粒及质粒定点突变解除反馈抑制时,对L-苏氨酸积累的影响。【方法】以W3110染色体DNA为模板,PCR扩增苏氨酸操纵子基因,即启动子THrLp、编码前导肽基因thrL以及thrA、thrB、thrC基因,通过重叠延伸PCR的方法对thrA基因定点突变,解除苏氨酸对它的反馈抑制,构建出重组表达质粒WYE112和WYE134,5 L发酵实验测定L-苏氨酸的产量。【结果】经5 L发酵罐发酵产酸实验,W3110的L-苏氨酸产量为0.036 ± 0.004 g/L,携带含苏氨酸操纵子质粒的W3110菌株L-苏氨酸产量为2.590 ± 0.115 g/L,质粒上thrA解除反馈抑制后,L-苏氨酸的产量增加到9.223 ± 1.279 g/L。【结论】过表达苏氨酸操纵子基因可以使L-苏氨酸积累,进一步解除thrA基因的反馈抑制,可以增强L-苏氨酸积累的效果,为L-苏氨酸工程菌改造的进一步研究奠定了基础。     

Construction of a threonine-hyperproducing strain of Serratia marcescens by amplifying the phosphoenolpyruvate carboxylase gene

Summary The phosphoenolpyruvate carboxylase gene (ppc) of Escherichia coli K-12 was cloned on the multi-copy plasmid pLG339. Plasmid pST101, which carried a 4.3-kb SalI fragment, was introduced into Serratia marcescens T-1165, which carried the seven regulatory mutations for three aspartokinases and two homoserine dehydrogenases. Strain T-1165[pST101] produced phosphoenolpyruvate carboxylase at a rate 26 times higher than the control strain T-1165[pLG339]. While T-1165[pST101] produced 63 mg/ml l-threonine in a medium containing sucrose and urea, whereas T-1165 only produced 52 mg/ml.     

Synthesis of 2-(d-Arabino-tetra-hydroxybutyl)pyrazine-5-sulfonic Acid

An efficient method for the isolation of dihydrodipicolinate synthase (DPS)-defective threonine producers from a Br evibacterium strain with feedback-sensitive aspartokinase (AK, Ak^s) was established. After mutagenesis of a strain with AK, No. 70, mutants resistant to α-amino-β- hydroxyvaleric acid were isolated and then selected as to threonine productivity in the presence of diaminopimelic acid. DPS activity in the strains in which the threonine production was inhibited by lysine was found to be absent or reduced to less than 10 % of the level in the parent. On the other hand, the strains in which the production was not inhibited by lysine were conventional threonine producers with feedback-resistant homoserine dehydrogenases (HDs and HD^Rs) and wild type DPS. The HD activities of most of the threonine mutants were also markedly reduced. However, only one mutant lacking DPS, DK330, exhibited an HD level comparable to that in the parent and produced the largest amount of threonine among the threonine producers obtained. The formation of HD and HK in strain DK330 was hardly repressed by the addition of methionine. Under the optimum conditions, strain DK330 produced 12.4 g/1 of threonine, while a typical HD type threonine producer, BK29, produced 9.9 g/1.     

Mapping of the structural genes of the three aspartokinases and of the two homoserine dehydrogenases of Escherichia coli K-12

Mutants requiring threonine plus methionine (or homoserine), or threonine plus methionine plus diaminopimelate (or homoserine plus diaminopimelate) have been isolated from strains possessing only one of the three isofunctional aspartokinases. They have been classified in several groups according to their enzymatic defects. Their mapping is described. Several regions of the chromosome are concerned: thrA (aspartokinase I-homoserine dehydrogenase I) is mapped in the same region as thrB and thrC (0 min). lysC (aspartokinase III) is mapped at 80 min, far from the other genes coding for diaminopimelate synthesis. metLM (aspartokinase II-homoserine dehydrogenase II) lies at 78 min closely linked to metB, metJ, and metF.     

Role of serine 352 in the allosteric response of Serratia marcescens aspartokinase I-homoserine dehydrogenase I analyzed by using site-directed mutagenesis.

Aspartokinase I and homoserine dehydrogenase I (AKI-HDI) from Serratia marcescens Sr41 are encoded by the thrA gene as a single polypeptide chain. Previously, a single amino acid substitution of Ser-352 with Phe was shown to produce an AKI-HDI enzyme that is not subject to threonine-mediated feedback inhibition. To determine the role of Ser-352 in the allosteric response, the thrA gene was modified by using site-directed mutagenesis so that Ser-352 of the wild-type AKI-HDI was replaced by Ala, Arg, Asn, Gln, Glu, His, Leu, Met, Pro, Thr, Trp, Tyr, or Val. The Thr-352 and Pro-352 replacements rendered AKIs sensitive to threonine. The Tyr-352 and Asn-352 substitutions led to activation, rather than inhibition, of AKI by threonine. The other replacements conferred threonine insensitivity on AKI. The threonine sensitivity of HDI was also changed by the amino acid substitutions at Ser-352. The HDI carried by the Tyr-352 mutant AKI-HDI was activated by threonine. Single amino acid replacements at Ser-352 by Ala, Asn, Gln, His, Phe, Pro, Thr, or Tyr were introduced into truncated AKI-HDIs containing the AKI and the central regions. The AKI activity of the truncated AKI-HDI containing the first 468 amino acid residues was sensitive to threonine, and introduction of the amino acid replacements did not alter the threonine sensitivity of the AKI. Another truncated AKI-HDI containing the first 462 amino acid residues possessed threonine-resistant AKI, whereas the substitutions of Ser-352 with Ala and Pro rendered AKI sensitive to threonine. The replacement of GIn-351 with Phe activated AK1 of the truncated AKI-HDI in the presence of L-threonine. These findings suggest that Ser-352 of the central region of AKI-HDI is possibly a key residue involved with the allosteric regulation of both AKI and HDI activities.     

Cloning and nucleotide sequences of the homoserine dehydrogenase genes (hom) and the threonine synthase genes (thrC) of the gram-negative obligate methylotroph Methylobacillus glycogenes.

We have cloned the homoserine dehydrogenase genes (hom) from the gram-negative obligate methylotrophs Methylobacillus glycogenes ATCC 21276 and ATCC 21371 by complementation of an Escherichia coli homoserine dehydrogenase-deficient mutant. The 4.15-kb DNA fragment cloned from M. glycogenes ATCC 21371 also complemented an E. coli threonine synthase-deficient mutant, suggesting the DNA fragment contained the thrC gene in addition to the hom gene. The homoserine dehydrogenases expressed in the E. coli recombinants were hardly inhibited by L-threonine, L-phenylalanine, or L-methionine. However, they became sensitive to the amino acids after storage at 4 degrees C for 4 days as in M. glycogenes. The structures of the homoserine dehydrogenases overexpressed in E. coli were thought to be different from those in M. glycogenes, probably in subunit numbers of the enzyme, and were thought to have converted to the correct structures during the storage. The nucleotide sequences of the hom and thrC genes were determined. The hom genes of M. glycogenes ATCC 21276 and ATCC 21371 encode peptides with M(r)s of 48,225 and 44,815, respectively. The thrC genes were located 50 bp downstream of the hom genes. The thrC gene of ATCC 21371 encodes a peptide with an M(r) of 52,111, and the gene product of ATCC 21276 was truncated. Northern (RNA) blot analysis suggests that the hom and thrC genes are organized in an operon. Significant homology between the predicted amino acid sequences of the hom and thrC genes and those from other microorganisms was found.     

A probabilistic measure for alignment-free sequence comparison

MOTIVATION: Alignment-free sequence comparison methods are still in the early stages of development compared to those of alignment-based sequence analysis. In this paper, we introduce a probabilistic measure of similarity between two biological sequences without alignment. The method is based on the concept of comparing the similarity/dissimilarity between two constructed Markov models. RESULTS: The method was tested against six DNA sequences, which are the thrA, thrB and thrC genes of the threonine operons from Escherichia coli K-12 and from Shigella flexneri; and one random sequence having the same base composition as thrA from E.coli. These results were compared with those obtained from CLUSTAL W algorithm (alignment-based) and the chaos game representation (alignment-free). The method was further tested against a more complex set of 40 DNA sequences and compared with other existing sequence similarity measures (alignment-free). AVAILABILITY: All datasets and computer codes written in MATLAB are available upon request from the first author.     

Nucleotide sequence of the thrB gene of E. coli, and its two adjacent regions; the thrAB and thrBC junctions.

We have sequenced a DNA fragment containing the Escherichia coli thrA-thrB junction, the complete thrB gene and the thrB-thrC junction. The intergenic sequence thrA and thrB is only one base pair. The coding region for homoserine kinase is 927 base pairs long. It is followed by 114 base pair segment in an open reading frame predicting that thrC begins just after non-sense codon of thrB. The presence at the end of thrA and of thrB of sequences that can pair with the 3' end of the 16 S ribosomal RNA suggests that reinitiation of translation occurs at the end of the two genes. The deduced aminoacid sequence for homoserine kinase shows no striking homology with aspartokinase I homoserine dehydrogenase I.     

Versatile low-copy-number plasmid vectors for cloning in Escherichia coli

Small low-copy-number plasmid vectors were constructed by in vitro and in vivo recombinant DNA techniques. pLG338 and pLG339 are derived from pSC105, have a copy number of six to eight per chromosome, and carry genes conferring resistance to tetracycline and kanamycin. pLG338 (7.3 kb) has unique restriction endonuclease sites for BamHI, SalI, HincII, SmaI, XhoI, EcoRI and KpnI, the first five lying within a drug resistance gene. pLG339 (6.2 kb) lacks the KpnI site, but has unique SphI and PvuII sites. These versatile vectors should be useful for cloning many genes coding for membrane and regulatory proteins which cannot be cloned into high-copy-number plasmids.     

Genetic analysis of thr mutations in Salmonella typhimurium

Previous workers divided threonine-requiring (Thr(-)) strains of Salmonella into three phenotypes with mutations in four complementation groups. The mutations were deemed to define four genes in the order thrD-C-A-B at minute zero on the Salmonella linkage map. In the present study 12 of these mutants were reexamined together with eight new Thr(-) strains. The three phenotypes were: homoserine-requiring (Hom(-)); Thr(-), feeders of Hom(-) strains; Thr(-), nonfeeders. Exact correlation between these phenotypic groups and three complementation groups was confirmed by abortive transduction. No evidence was found for intergenic complementation between mutations in Hom(-) strains. It is proposed that thr mutations define three genes rather than four and that these be renamed thrA (Hom(-)), thrB (Thr(-) feeders), and thrC (Thr(-) nonfeeders) to correspond with the sequence of reactions in threonine biosynthesis. Double mutant trpRthr strains were used in reciprocal three-point transduction tests to establish the order of thr mutation sites. Although revisions were made in the classification or location of several mutations, there was an overall correlation of complementation group, phenotype, and map position. The present data provide a basis for further correlation of threonine genes and biosynthetic enzymes, and analysis of cross regulation in aspartate amino acid biosynthesis in Salmonella.     

Genetic instability in Streptomyces niveus plasmid pSN2: in vivo formation of deletion derivatives

A plasmid designated pSN2 (molecular size 32.0 kb) was isolated from the wild type of Streptomyces niveus ATCC 19793. To permit phenotypic identification of pSN2 the 1.9 kb BclI fragment was replaced in vitro by the 1.1 kb BclI fragment of pIJ702 carrying the thiostrepton resistance (tsr) gene to form the plasmid pSN3. pSN3 transforms S. lividans to thiostrepton resistance at high frequency and is stably maintained. However, when used to transform S. niveus pSN3 was unstable and produced a 5.5 kb thiostrepton resistant deletion derivative pLG5. pLG5 is also stable and expresses thiostrepton resistance in S. lividans but on transformation of S. niveus was unstable and produced a further thiostrepton resistant derivative, pLG10, of 6.5 kb. pLG5 and pLG10 like pSN3 transform S. lividans at high frequency and produce pocks. DNA hybridizations with a probe derived from pLG5 confirm that pLG5 is derived from DNA sequences present on pSN2 and pSN3.Abbreviations SDS sodium dodecyl sulphate - PEG polyethylene glycol     

Design of a gene coding encoding a polypeptide, mixing the enzyme activity of Escherichia coli homoserine kinase and threonine synthetase]

The functioning of Escherichia coli threonine operon isolated genes thrB and thrC was studied by using the genetic complementation and enzymatic activity determination techniques. A new gene thrBC was obtained by the genes merging. The genes thrB and thrC were shown to function in Escherichia coli cells independent of the operon and the polipeptide encoded by the thrBC gene combined the functions to express the products of both genes in bacterial cell. At the same time the enzyme coded for by the merged genes demonstrates the level of activity compared with the ones of the isolated genes.     

Cloning and expression of an Arabidopsis thaliana cDNA encoding a monofunctional aspartate kinase homologous to the lysine-sensitive enzyme of Escherichia coli

As in many bacterial species, the first enzymatic reaction of the aspartate-family pathway in plants is mediated by several isozymes of aspartate kinase (AK) that are subject to feedback inhibition by the end-product amino acids lysine or threonine. So far, only cDNAs and genes encoding threonine-sensitive AKs have been cloned from plants. These were all shown to encode polypeptides containing two linked activities, namely AK and homoserine dehydrogenase (HSD), similar to the Escherichia coli thrA gene encoding a threonine-sensitive bifunctional AK/HSD isozyme. In the present report, we describe the cloning of a new Arabidopsis thaliana cDNA that is relatively highly homologous to the E. coli lysC gene encoding the lysine-sensitive AK isozyme. Moreover, similar to the bacterial lysine-sensitive AK, the polypeptide encoded by the present cDNA is monofunctional and does not contain an HSD domain. These observations imply that our cloned cDNA encodes a lysine-sensitive AK. Southern blot hybridization detected a single gene highly homologous to the present cDNA, plus an additional much less homologous gene. This was confirmed by the independent cloning of an additional Arabidopsis cDNA encoding a lysine-sensitive AK (see accompanying paper). Northern blot analysis suggested that the gene encoding this monofunctional AK cDNA is abundantly expressed in most if not all tissues of Arabidopsis.