Production of threonine byBrevibacterium flavum containing threonine biosynthesis genes fromEscherichia coli

Genes of the threonine operon ofEscherichia coli were used for the construction of aBrevibacterium flavum strain excreting threonine. Using the shuttle vector pCEM300 and a newly constructed shuttle vector pEC71 (7.1 kb, Km^r/Nm^r), various plasmids carryingE. coli thr genes were prepared. Mutants resistant to the threonine analog 2-amino-3-hydroxyvaleric acid (AHV) were isolated after the ethyl methanesulfonate treatment ofB. flavum carrying these recombinant plasmids. A mutant ofB. flavum CCM 351 carrying the cloned genesthrA andthrB accumulated 12 g/L of threonine after 48 h of cultivation.     

Cloning and expression in Escherichia coli of the homoserine kinase (thrB) gene from Brevibacterium lactofermentum

Summary Five DNA fragments carrying the thrB gene (homoserine kinase E.C. 2.7.1.39) of Brevibacterium lactofermentum were cloned by complementation of Escherichia coli thrB mutants using pBR322 as vector. All the cloned fragments contained a common 3.1 kb DNA sequence. The cloned fragments hybridized among themselves and with a 9 kb BamHI fragment of the chromosomal DNA of B. lactofermentum but not with the DNA of E. coli. None of the cloned fragments were able to complement thrA and thrC mutations of E. coli. Plasmids pULTH2, pULTH8 and pULTH11 had the cloned DNA fragments in the same orientation and were very stable. On the contrary, plasmid pULTH18 was very unstable and showed the DNA inserted in the opposite direction. E. coli minicells transformed with plasmids pULTH8 or pULTH11 (both carrying the common 3.1 kb fragment) synthesize a protein with an M _r of 30,000 that is similar in size to the homoserine kinase of E. coli.Abbreviations SSC 0.15 M NaCl, 0.015 M sodium citrate - SDS sodium dodecyl sulphate - TSB tripticase soy broth - m-DAP meso-diaminopimelic acid - Sm^r, Cp^r, Km^r, Am^r, Ap^r, Tc^r, MA15^r resistance to streptomycin, cephalotin, kanamycin, amykacin, ampicillin, tetracycline and microcin A 15, respectively     

Fine structure analysis of the threonine operon in Escherichia coli K-12.

Summary A fine structure analysis of the threonine operon in Escherichia coli K-12 was performed by deletion mapping. Lambda transducing bacteriophages carrying various parts of the threonine operon were isolated from strains in which the lacZ gene was fused to a thr gene. We tested for recombination between deletions of the threonine promotor extending into the threonine operon, carried by the phage, and bacterial thr auxotrophs. The relative order of thrO (operator) mutations was established. We propose that an operator region is located between a promoter region and the structural genes. Mutations leading to the desensitization of the aspartokinase I-homoserine dehydrogenase I towards threonine were localized in two different regions of the thrA gene.     

Construction and expression of a hybrid plasmid containing the Escherichia coli thrA and thrB genes.

Summary In vitro recombination techniques were used to clone the Escherichia coli thrA and thrB structural genes in the plasmid vector pBR322. The chimeric plasmid was analyzed and characterized genetically, by restriction mapping and DNA sequencing. The limited expression of the threonine biosynthetic enzymes in the strain carrying the recombinant plasmid is discussed.     

Expression of the threonine operon fromEscherichia coli inBrevibacterium flavum andCorynebacterium glutamicum

Summary The threonine operon fromEscherichia coli was cloned in plasmid pBR322, subcloned into the shuttle vector pCEM300 and the resulting recombinant plasmid was transferred intoBrevibacterium flavum andCorynebacterium glutamicum. The expression ofE. coli threonine genes in these coryneform bacteria was demonstrated by complementing thethrA andthrB mutations and by assaying homoserine dehydrogenase activity.     

Amino-acid Sequence of λ Phage Endolysin

WE wish to present a preliminary report of the amino-acid sequence of λ endolysin. This protein is a lytic enzyme¹ and its structural gene, R, maps toward the right end of λ DNA². Conditional mutants as well as frame-shift mutants (R. Thomas, personal communication) have been isolated and analysed³. Hogness et al.⁴ developed a technique to assay the gene activity of the fragmented λ DNA, which suggested that it might be possible to isolate a small segment of DNA containing the endolysin gene. Purification, immunological properties and end group analysis of λ endolysin were studied by Black and Hogness^5–7.     

Assembly of bacteriophage lambda heads: Protein processing and its genetic control in petit λ assembly

Petit bacteriophage λ is a hollow λ head precursor which is found in λ-infected lysates, including lysates of phage λ carrying mutations in head genes. Wild-type petit λ has a protein composition similar to heads, except that it is missing pD ⁴, a major component of heads. About 95% of the mass of petit λ is pE, the major structural protein of heads, and in addition it has proteins pB, h3, X1, and X2. Tryptic fingerprint analysis shows that h3 is a proteolytic cleavage product of pB, and previous experiments have shown that X1 and X2 are protein fusion products, closely related to each other and containing amino acid sequences of both pC and pE. Petit lambdas derived from infection by phages defective in genes A or D are indistinguishable from wild-type petit λ. B⁻, C⁻, or groE⁻ defective petit lambdas show differences from wild-type in protein composition and in extent of protein processing. On the basis of the properties of mutant petit lambdas it is concluded that: (1) the protein processing reactions (cleavage of pB; fusion of pC with pE) occur on the petit λ structure; (2) cleavage of pB requires the functioning of genes C and groE but not A or D; (3) fusion of pC and pE requires gene groE but not A, B or D; (4) pNu3 participates directly in petit λ assembly but is lost from the structure by the time assembly is complete.Physical studies of petit λ show that wild-type, A⁻, B⁻ and D⁻ petit lambdas sediment at 150 S, while C⁻ and groE⁻ petit lambdas sediment at 190 S. Purified petit λ of either class has an ultraviolet absorption spectrum characteristic of pure protein.     

int-h: An int mutation of phage lambda that enhances site-specific recombination

The mutation int-h3 maps in the int gene of coliphage λ and results in the synthesis of an integrase with enhanced activity, which is manifested by an ability to support λ site-specific recombination relatively efficiently under conditions where the wild-type integrase functions inefficiently. The level of site-specific recombination seen in the presence of the int⁺ integrase in himA^? hosts is greatly reduced, as measured by lysogen formation, intramolecular site-specific integration and excision, and excision of a cryptic λ prophage. In contrast, the int-h3 integrase shows relatively high levels of activities under these conditions. Int-h3 is also more active in other host mutants (himB and hip) that reduce λ site-specific recombination. In the absence of the normal attB site, the frequency of lysogen formation (at secondary sites) by λ int⁺ is reduced 200 fold. Although λ int-h3 will integrate preferentially at the attB site if it is present, the mutant phage forms lysogens at a high frequency in attB-deleted hosts. λ int-h3 requires himA function for integration at secondary sites. The fact that the int-h3 integrase uses the same att sites as well as the same host functions as the int⁺ integrase suggests that the mutation results in a quantitative rather than a qualitative change in integrase activity; that is, the int-h3 integrase is more active. The mutant integrase supports site-specific recombination with att sites that carry the att24 mutation. We propose that the int-h3 integrase is endowed with an enhanced ability to recognize att sequences, including some that are not effectively recognized by wild-type integrase.     

Development of a population for substantial new type Brassica napus diversified at both A/C genomes

Intersubgenomic heterosis in rapeseed has been revealed in previous studies by using traditional Brassica napus (AⁿAⁿCⁿCⁿ) to cross partial new type B. napus with A^r/C^c introgression from the genomes of B. rapa and B. carinata, respectively. To further enlarge the genetic basis of B. napus and to facilitate a sustained heterosis breeding in rapeseed, it is crucial to create a population for substantial new type B. napus diversified at both A/C genomes. In this experiment, hundreds of artificial hexaploid plants (A^rA^rB^cB^cC^cC^c) involving hundreds of B. carinata/B. rapa combinations were first crossed with elite lines of partial new type B. napus. The pentaploid plants (AABCC) were open-pollinated in isolated conditions, and their offspring were successively self-pollinated and intensively selected for two generations. Thereafter, a population of substantial new type B. napus mainly with a genomic composition of A^rA^rC^cC^c harbouring genetic diversity from 25 original cultivars of B. rapa and 72 accessions of B. carinata was constructed. The population was cytologically verified to have the correct chromosome constitution of AACC and differed genetically from traditional B. napus, in terms of the genome components of A^r/C^c and B^c as well as the novel genetic variations induced by the interspecific hybridisation process. Synchronously, rich phenotypic variation with plenty of novel valuable traits was observed in the population. The origin of the novel variations and the value of the population are discussed.     

Identity of a Chi site of Escherichia coli and Chi recombinational hotspots of bacteriophage λ

Chi sites in bacteriophage λ stimulate recombination promoted by the RecBC pathway of Escherichia coli. We have located a Chi site within the E. coli lacZ gene by deletion mapping and have isolated a mutation inactivating this Chi. Sequence analysis showed that the mutation arose by a single base-pair transition $\text{G}\text{C}\text{?}\text{→}\text{A}\text{T}\text{?}$ within an eight base-pair sequence (5′ G-C-T-G-G-T-G-G 3′) identical to that found at Chi sites in λ and in plasmid pBR322.     

Host participation in bacteriophage lambda head assembly

Mutants of Escherichia coli, called groE, specifically block assembly of bacteriophage λ heads. When groE bacteria are infected by wild type λ, phage adsorption, DNA injection and replication, tail assembly, and cell lysis are all normal. No active heads are formed, however, and head related “monsters” are seen in lysates. These monsters are similar to the structures seen on infection of wild-type cells by phage defective in genes B or C.We have isolated mutants of λ which can overcome the block in groE hosts and have mapped these mutants. All groE mutations can be compensated for by mutation of phage gene E (hence the name groE). Gene E codes for the major structural subunit of the phage head. Some groE mutants, called groEB, can be compensated by mutation in either gene E or in gene B. Gene B is another head gene.During normal head assembly the protein encoded by phage head gene B or C appears to be converted to a lower molecular weight form, h3, which is found in phage. The appearance of h3 protein in fast sedimenting head related structures requires the host groE function.We suggest that the proteins encoded by phage genes E, B and C, and the bacterial component defined by groE mutations act together at an early stage in head assembly.     

Host Specificity of Salmonella typhimurium Deoxyribonucleic Acid Restriction and Modification

The restriction and modification genes of Salmonella typhimurium which lie near the thr locus were transferred to a restrictionless mutant of Escherichia coli. These genes were found to be allelic to the E. coli K, B, and A restriction and modification genes. E. coli recombinants with the restriction and modification host specificity of S. typhimurium restricted phage λ that had been modified by each of the seven known host specificities of E. coli at efficiency of plating levels of about 10⁻². Phage λ modified with the S. typhimurium host specificity was restricted by six of the seven E. coli host specificities but not by the RII (fi⁻ R-factor controlled) host specificity. It is proposed that the restriction and modification enzymes of this S. typhimurium host specificity have two substrates, one of which is a substrate for the RII host specificity enzymes.     

Isolation and characterization of Hfr males in Citrobacter freundii

Citrobacter freundii Hfr donor strains were isolated from a C. freundii strain harbouring a temperature-sensitive factor F ts 114 lac ⁺, by selecting for integrative suppression of the ts 114 mutation. Three Hfr strains were characterized, which transfer their chromosomes in a linear and oriented order. The first strain transfers: O-aro ⁺-ilv ⁺-pur ⁺-thr ⁺-leu ⁺-pro ⁺, the second: O-ilv ⁺-pur ⁺-thr ⁺-leu ⁺-pro ⁺ and the third: O-ilv ⁺-aro ⁺-nad ⁺-his ⁺-pro ⁺. The whole chromosome is transferred into the recipient cell within about 145 minutes. From these results we concluded that the linkage map of C. freundii is circular. Mating-pair formation on a membrane filter resulted in more recombinants being formed as compared with mating-pair formation in liquid medium. Furthermore the mating-pairs formed on a membrane were more stable. From one Hfr strain heterogenic F-prime factors could be isolated bearing the F ts 114 lac ⁺ genes from Escherichia coli and the pur ⁺ and/or ilv ⁺ genes from C. freundii. Preliminary mapping by interrupted mating indicated that the linkage map of C. freundii is in general very similar to those of E. coli, Salmonella typhimurium and Klebsiella aerogenes.     

Regulatory mechanism of the tryptophan operon in Escherichia coli: possible interaction between trpR and trpS gene products

Summary The trpS5 mutation (a mutation in the structural gene for tryptophanyl-tRNA synthetase (TRSase) in E. coli), when present in the genetic background of strain KY913 (HfrH), results in the failure to grow at high temperature (42° C) in a complete medium. The rel (RC relaxed) marker present in this strain was found to be partly responsible for this temperature sensitivity. TRSase in such a strain was rapidly inactivated during growth at 42° C in rich media, but not in minimal media or in the presence of chloramphenicol. A partial derepression of anthranilate synthetase formation took place in the presence of excess tryptophan at growth-restricting temperatures. When some of the trpR mutations (including amber mutations) were combined with trpS5, the resulting double mutants (trpR trpS5) were temperature-insensitive, and TRSase was not inactivated at high temperature, in contrast to the trpR ⁺trpS5 strain. This effect of trpR mutations on temperature sensivity was shown not to be a secondary consequence of the constitutive expression of the trp operon. These findings suggest that the trpR ⁺ product interacts with the TRSase of the trpS5 mutant so as to bring about the growth-dependent inactivation of the enzyme. Furthermore, a special class of trpR mutants was obtained whose constitutivity with respect to the trp operon is manifested only in strains carrying trpS5 (but not trpS ⁺) grown at high temperatures. It is proposed that TRSase participates in repression trrough direct interaction with the product of the trpR gene.     

Characterization of Fructose 1,6-Bisphosphatase and Sedoheptulose 1,7-Bisphosphatase from the Facultative Ribulose Monophosphate Cycle Methylotroph Bacillus methanolicus

The genome of the facultative ribulose monophosphate (RuMP) cycle methylotroph Bacillus methanolicus encodes two bisphosphatases (GlpX), one on the chromosome (GlpX^C) and one on plasmid pBM19 (GlpX^P), which is required for methylotrophy. Both enzymes were purified from recombinant Escherichia coli and were shown to be active as fructose 1,6-bisphosphatases (FBPases). The FBPase-negative Corynebacterium glutamicum Δfbp mutant could be phenotypically complemented with glpX^C and glpX^P from B. methanolicus. GlpX^P and GlpX^C share similar functional properties, as they were found here to be active as homotetramers in vitro, activated by Mn²⁺ ions and inhibited by Li⁺, but differed in terms of the kinetic parameters. GlpX^C showed a much higher catalytic efficiency and a lower K_m for fructose 1,6-bisphosphate (86.3 s⁻¹ mM⁻¹ and 14 ± 0.5 μM, respectively) than GlpX^P (8.8 s⁻¹ mM⁻¹ and 440 ± 7.6 μM, respectively), indicating that GlpX^C is the major FBPase of B. methanolicus. Both enzymes were tested for activity as sedoheptulose 1,7-bisphosphatase (SBPase), since a SBPase variant of the ribulose monophosphate cycle has been proposed for B. methanolicus. The substrate for the SBPase reaction, sedoheptulose 1,7-bisphosphate, could be synthesized in vitro by using both fructose 1,6-bisphosphate aldolase proteins from B. methanolicus. Evidence for activity as an SBPase could be obtained for GlpX^P but not for GlpX^C. Based on these in vitro data, GlpX^P is a promiscuous SBPase/FBPase and might function in the RuMP cycle of B. methanolicus.     

Three homologous genes encoding functional ∆8-sphingolipid desaturase in Populus tomentosa

?⁸-sphingolipid desaturase is characterized by its ability to catalyze desaturation at the C8 position of the long-chain base of sphingolipids in plants. No previous studies have been conducted on genes encoding Δ⁸-sphingolipid desaturases in the woody plant Populus tomentosa. In this study, three genes that encode Δ⁸-sphingolipid desaturase were isolated from P. tomentosa. Among these genes, PtD8A and PtD8B showed high sequence similarity; whereas PtD8C exhibited large sequence divergence. RT-PCR results showed that PtD8A and PtD8B were expressed in all tissues detected, whereas PtD8C was not expressed in roots. Heterologous expression in yeast revealed that PtD8A/B/C were functional Δ⁸-sphingolipid desaturases, and can catalyze the C18-phytosphingenine desaturation to produce 8(Z)- and 8(E)-C18-phytosphingenine. However, the conversion rate and ratios of the two products differed. Compared with control cells, transgenic yeasts expressing PtD8A/B/C exhibited enhanced aluminum tolerance. Our findings further elucidated the biochemical functions and evolutionary history of Δ⁸-sphingolipid desaturases in plants. Candidate genes for breeding new poplar germplasm resources with enhanced tolerance ability to aluminium were also provided.     

Direct identification of the amino acid changes in two mutant lac repressors.

Deletions extending into the trp operon at one terminus and the lacI control region at the other terminus have been examined. One of these, B116, ends within the trp leader sequence and eliminates the trp attenuator site, placing the synthesis of lac repressor under trp control. We have isolated and characterized the B116 repressor. The protein sequence of the aminoterminus of B116 shows that an additional 16 residues are added to the amino-terminal end of wild-type repressor. Moreover, a valine residue appears in place of methionine at position 17 (the original amino-terminal residue of the wild-type repressor). A comparison of the messenger RNA sequence of the trp leader region and of the I leader region demonstrates that the translation of the B116 repressor is initiated at an AUG codon within the trp leader sequence. The GUG initiation codon at the start point for translation of wild-type repressor is now read as valine, since it appears at an internal position (residue 17 of the altered repressor). The B116 repressor accumulates at levels as high as 1% of the soluble cell protein in trpR^? strains. The efficiency of the trp leader initiation codon in translation suggests that in wild-type strains this AUG is also active in directing protein synthesis, which would result in a polypeptide consisting of 14 amino acids. We have examined the physical properties of the B116 repressor, which shows a marked tendency to form higher aggregates. Other characteristics of B116 are also described.     

Cloning the trpR gene.

Summary In Escherichia coli, the structural gene for purine nucleoside phosphorylase, deoD, is subject to insertional inactivation by prophage . From one such secondary site lysogen, strain SP265, one may isolate deletions that remove all or part of the trpR gene and other genes in the deo-thr sector of the E. coli chromosome. Specialized transducing phages harboring serB ⁺ and trpR ⁺ were liberated following induction of SP265. All such phages were N-defective, bio-type pseudolysogens whose DNA persisted in the form of plasmids. A collection of transducing phages, differing in their complement of bacterial DNA, was used to locate cleavage sites for bamHI, SalI, and PvuI within the deoD-trpR region of the E. coli genome. The trpR gene lies within a specific 950 base pair BamHI-PvuI segment.A 1250 base pair BamHI fragment carrying a functional trpR gene was cloned into the amplifiable plasmid pBR322. A single SalI site in this fragment was shown to lie within the trpR gene.In two situations where increased gene dosage might generate elevated amounts of Trp repressor (N-defective trpR ⁺ pseudolysogens and strains harboring pBR322 trpR ⁺ plasmids) neither tryptophan auxotrophy, enhanced sensitivity to DL-5-methyltryptophan, nor super repression of the tryptophan biosynthetic enzymes was observed.Journal Paper No. 7426 of the Purdue University Agricultural Experiment Station     

Degree of C(4) Photosynthesis in C(4) and C(3)-C(4)Flaveria Species and Their Hybrids : I. CO(2) Assimilation and Metabolism and Activities of Phosphoenolpyruvate Carboxylase and NADP-Malic Enzyme

The degree of C₄ photosynthesis was assessed in four hybrids among C₄, C₄-like, and C₃-C₄ species in the genus Flaveria using ¹⁴C labeling, CO₂ exchange, ¹³C discrimination, and C₄ enzyme activities. The hybrids incorporated from 57 to 88% of the ¹⁴C assimilated in a 10-s exposure into C₄ acids compared with 26% for the C₃-C₄ species Flaveria linearis, 91% for the C₄ species Flaveria trinervia, and 87% for the C₄-like Flaveria brownii. Those plants with high percentages of ¹⁴C initially fixed into C₄ acids also metabolized the C₄ acids quickly, and the percentage of ¹⁴C in 3-phosphoglyceric acid plus sugar phosphates increased for at least a 30-s exposure to ¹²CO₂. This indicated a high degree of coordination between the carbon accumulation and reduction phases of the C₄ and C₃ cycles. Synthesis and metabolism of C₄ acids by the species and their hybrids were highly and linearly correlated with discrimination against ¹³C. The relationship of ¹³C discrimination or ¹⁴C metabolism to O₂ inhibition of photosynthesis was curvilinear, changing more rapidly at C₄-like values of ¹⁴C metabolism and ¹³C discrimination. Incorporation of initial ¹⁴C into C₄ acids showed a biphasic increase with increased activities of phosphoenolpyruvate carboxylase and NADP-malic enzyme (steep at low activities), but turnover of C₄ acids was linearly related to NADP-malic enzyme activity. Several other traits were closely related to the in vitro activity of NADP-malic enzyme but not phosphoenolpyruvate carboxylase. The data indicate that the hybrids have variable degrees of C₄ photosynthesis but that the carbon accumulation and reduction portions of the C₄ and C₃ cycles are well coordinated.