Genetic and biochemical characterization of the birA gene and its product: evidence for a direct role of biotin holoenzyme synthetase in repression of the biotin operon in Escherichia coli

Lesions at the birA locus of Escherichia coli produce, in varying degrees, derepression of the biotin operon and an increased minimum biotin growth requirement (Barker &; Campbell, 1980) as well as diminished biotin uptake and defective biotin holoenzyme synthetase activity (Campbell et al., 1972, 1980). In the accompanying paper, we showed that three birA mutants produce biotin holoenzyme synthetase with altered in vitro properties and that they carry lesions in the structural gene for this enzyme. The pleiotropic birA defect was attributed to structural interactions between a protein domain which includes the holoenzyme synthetase active site and a second protein domain, possibly part of the same polypeptide, which functions as the bio repressor.To determine if one or more genes reside at birA, we tested pairwise combinations of nine mutations with representative phenotypes for their ability to establish repression of bio expression. The mutations define a single complementation group. Instances of partial complementation appear to be intracistronic, suggesting that the birA product forms a multimer active as both biotin holoenzyme synthetase and repressor.DNA segments that include and express the birA gene have been cloned into multicopy plasmids. Plasmid-mediated expression of birA can produce a state of superrepression of the bio operon and a concomitant increase in holoenzyme synthetase specific activity. The complementation properties of derivative plasmids, with insertions of Tn5 or small deletions in the bacterial DNA segment, define a 1.6 × 10³ base region that includes the birA gene and a 0.9 × 10³ base segment essential to biotin holoenzyme synthetase and repressor function. The region is flanked by the thrT and tufB genes in a previously unassigned region of the bacterial DNA carried by λdrif^d18.A preparation of holoenzyme synthetase, purified nearly 10,000-fold, contains a protein that binds specifically to biotin operator DNA as determined by its ability to protect a TaqI endonuclease site that borders the imperfect inverted repeat where the bio repressor is presumed to bind. Biotinyl 5′-adenylate or biotin plus ATP are more effective corepressors than biotin alone, suggesting that biotinyl 5′-adenylate, a presumed intermediate in the holoenzyme synthetase reaction, is the true corepressor.     

Isolation and characterization of Escherichia coli birA intragenic suppressors

Summary The biotin (bio) operon in Escherichia coli is negatively regulated by BirA, a bifunctional protein with both repressor and biotin-activating functions. Twenty-five heatresistant revertants of three temperature-sensitive birA alleles (birA 85, bir A 104 and bir A 879) were isolated and categorized into five growth and six repression classes. The revertants appear to increase biotin activation by raising the specific activity of BirA and/or, increasing the number of enzyme molecules. The 19 bir A 85 revertants displayed a broad range of activity for both enzyme and repressor functions, and may represent intragenic second-site suppressor mutations. The bir A 85 revertants included a novel class of bio superrepressor mutations. Repressor titration experiments suggested that many of the bir A 85 revertants increase BirA concentrations above wild-type levels because the repressors were not competed from the chromosomal bio operator by multicopy bio operator plasmids. The majority of the bir A 104 revertants resulted in both wild-type repressor and enzyme activity; they are possibly true revertants in which the amino acid residue altered by the bir A 104 mutation has been substituted by the wild-type or a chemically similar amino acid.     

Overproduction and rapid purification of the biotin operon repressor from Escherichia coli

The Escherichia coli biotin operon repressor protein (BirA) has been overexpressed at the level of 0.5-1% of the total cellular protein from the plasmid pMBR10. Four lines of evidence demonstrated that authentic BirA protein was produced. First, birA plasmids complemented birA mutants for both the repressor and biotin holoenzyme synthetase activities of BirA. Second, biotin holoenzyme synthase activity was increased in strains containing the overproducing plasmids. Third, deletion of sequences flanking the birA gene did not alter production of the 35-kDa BirA protein, but insertion of oligonucleotide linkers within the birA coding region abolished it. Fourth, the 35-kDa protein copurified with the biotin binding activity normally associated with BirA. The birA protein has been purified to homogeneity in a three-step process involving chromatography on phosphocellulose and hydroxyapatite columns.     

The biotin protein MadF of the malonate decarboxylase from Malonomonas rubra

The gene for the biotin protein MadF of the Na⁺-pumping malonate decarboxylase from Malonomonas rubra was expressed in Escherichia coli together with the gene for the biotin ligase birA. MadF was partially purified from cell lysates by ammonium sulfate precipitation. Almost pure biotin protein was obtained by subsequent gel chromatography. With recombinant MadF, malonate decarboxylase activity of M. rubra cell extracts previously inactivated by avidin was recovered. Thus, the biological activity of recombinant MadF was proven. Despite the coexpression of birA, MadF was poorly biotinylated. This effect was not caused by an insufficient cofactor supply due to elevated protein levels at constant biotin uptake rates. Attempts to improve the cofactor incorporation were made by site-directed mutagenesis, by coexpression of madK, and by N-terminal elongation of MadF. These measures improved the fraction of MadF containing biotin to maximally 5%. These results might indicate the existence of a biotin ligase in M. rubra with an altered substrate specificity different from that of BirA. Received: 4 June 1998 / Accepted: 7 September 1998     

Genetic and Immunological Studies of Bacteriophage T4 Thymidylate Synthetase

Thymidylate synthetase, which appears after infection of Escherichia coli with bacteriophage T4, has been partially purified. The phage enzyme is immunologically distinct from the host enzyme and has a molecular weight of 50,000 in comparison to 68,000 for the host enzyme. A system has been developed to characterize T4 td mutants previously known to have impaired expression of phage thymidylate synthetase. For this system, an E. coli host lacking thymidylate synthetase was isolated. Known genetic suppressors were transduced into this host. The resulting isogenic hosts were infected with phage T4 td mutants. The specific activities and amounts of cross-reacting material induced by several different types of phage mutants under conditions of suppression or non-suppression have been examined. The results show that the phage carries the structural gene specifying the thymidylate synthetase which appears after phage infection, and that the combination of plaque morphology, enzyme activity assays, and an assay for immunologically cross-reacting material provides a means for identifying true amber mutants of the phage gene.     

Hotspots for generalized recombination in the Escherichia coli chromosome.

A naturally occurring hotspot for Rec recombination of Escherichia coli was located in the biotin operon. The phenotypes of the bio hotspot as observed in λbio transducing phage were identical to those of Chi mutations in phage λ. In addition to recA⁺ function, the site-specific stimulation of recombination required recB⁺ function. The stimulation took place when the hotspot was present in only one parent of the cross and even when present opposite a region of heterology.The demonstration of a Chi element in E. coli provoked us to measure the density of Chi elements on the chromosome. E. coli DNA sampled in λ transducing phage (either obtained by induction of secondary site lysogens or made in vitro from EcoRI cleavage fragments) showed one hotspot per 5 to 15 × 10³ bases. The high density and the fact that Chi stimulation of recombination can span the inter-Chi distance suggest that Chi might be important in Rec recombination in the absence of λ.     

Molecular cloning and amplification of the gene for thymidylate synthetase of E. coli

The thyA gene of Escherichia coli, which directs the synthesis of the enzyme thymidylate synthetase, has been subcloned from a recombinant λ phage (Hickson et al., 1982) into the multicopy plasmid pBR325 to give the plasmid pPE245. To identify the thyA gene product, the transposon Tn1000 was inserted into pPE245 and derivative plasmids isolated that were no longer able to complement thyA mutations. When proteins synthesised by these plasmids and by pPE245 were labelled and analysed on SDS-polyacrylamide gels a protein of 33000 M_r, presumably the thyA⁺ gene product was absent whenever the thyA gene was inactivated. On assaying cell extracts prepared from cells harbouring pPE245 for thymidylate synthetase, the level of this enzyme was found to be elevated by a factor of at least 25.     

Initiation of synthesis of the structural proteins of Semliki Forest virus.

Insertion of phage λ DNA into the normal attachment site of the DNA of the host Escherichia coli has been studied by ultracentrifugation analysis of the conversion of covalent circles of F′450 (F′gal att^λ bio) to F′450(λ) circles. We have found that integration proceeds at the normal rate if, in addition to the int gene product and a proper combination of phage and bacterial attachment sites, a large pool of λ DNA and some activity of the excision gene xis are present. In addition, turnoff of both phage DNA synthesis and xis gene activity are required.     

A versatile plasmid expression vector for the production of biotinylated proteins by site-specific,enzymatic modification in Escherichia coli

A versatile plasmid vector was designed to direct the synthesis of recombinant proteins in either one of two forms that will be biotinylated in Escherichia coli with high efficiency at a single, unique site. The protein of interest can be produced with a peptide substrate for E. coli biotin holoenzyme synthetase (BirA) joined directly to its N terminus, or alternatively, as a fusion to the C terminus of a maltose-binding protein domain (Ma1E) with the peptide substrate on its N terminus. To maximize the yield of biotinylated protein, the vector is designed to express the substrate in a coupled translation arrangement with the enzyme     

Cloning and characterization of the Bacillus subtilis birA gene encoding a repressor of the biotin operon.

The Bacillus subtilis birA gene, which regulates biotin biosynthesis, has been cloned and characterized. The birA gene maps at 202 degrees on the B. subtilis chromosome and encodes a 36,200-Da protein that is 27% identical to Escherichia coli BirA protein. Three independent mutations in birA that lead to deregulation of biotin synthesis alter single amino acids in the amino-terminal end of the protein. The amino-terminal region that is affected by these three birA mutations shows sequence similarity to the helix-turn-helix DNA binding motif previously identified in E. coli BirA protein. B. subtilis BirA protein also possesses biotin-protein ligase activity, as judged by its ability to complement a conditional lethal birA mutant of E. coli.     

A hotspot of spontaneous and UV-induced illegitimate recombination during formation ofλbio transducing phage

To study the mechanism of spontaneous and UV-induced illegitimate recombination, we examined the formation of theλbio specialized transducing phage inEscherichia coli. Because mostλbio transducing phages have double defects in thered andgam genes and have the capacity to form a plaque on anE. coli P2 lysogen (Spi^? phenotype), we selectedλbio transducing phage by their Spi^? phenotype, rather than using thebio marker. We determined sequences of recombination junctions ofλbio transducing phages isolated with or without UV irradiation and deduced sequences of parental recombination sites. The recombination sites were widely distributed onE. coli bio andλ DNAs, except for a hotspot which accounts for 57% of UV-inducedλbio transducing phages and 77% of spontaneously inducedλbio transducing phages. The hotspot sites onE. coli andλ DNAs shared a short homology of 9 bp. In addition, we detected direct repeat sequences of 8 by within and near both thebio andλ hotspots. ArecA mutation did not affect the frequency of the recombination at the hotspot, indicating that this recombination is not a variant ofrecA-dependent homologous recombination. We discuss a model in which the short homology as well as the direct repeats play essential roles in illegitimate recombination at the hotspot.     

Biotin regulatory (bir) mutations of Escherichia coli

Most mutants selected for derepression of the biotin operon required elevated concentrations of biotin for growth. Mutant extracts were deficient in holoenzyme synthetase activity.     

DNA-binding and enzymatic domains of the bifunctional biotin operon repressor (BirA) of Escherichia coli

The negative regulation of the biotin biosynthetic (bio) operon in Escherichia coli is mediated by the bifunctional birA gene product, which serves as the bio repressor and biotin-activating enzyme. Nucleotide sequence analysis of 18 mutations in the birA gene was employed to study the DNA-binding and enzymatic functions of the BirA protein. The results indicate that a predicted helix-turn-helix structure, from amino acid (aa) positions 18 to 39 within the 321-aa BirA protein, may be responsible for sequence-specific DNA binding, whereas the temperature-sensitive mutations affecting biotin activation are found in two regions from aa positions 83-119 and 189-235.     

The Escherichia coli Yej transporter is required for the uptake of translation inhibitor microcin C

Microcin C (McC), a peptide-nucleotide antibiotic, targets aspartyl-tRNA synthetase. By analyzing a random transposon library, we identified Escherichia coli mutants resistant to McC. Transposon insertions were localized to a single locus, yejABEF, which encodes components of a putative inner membrane ABC transporter. Analysis of site-specific mutants established that all four components of the transporter are required for McC sensitivity. Since aspartyl-tRNA synthetase in yej mutant extracts was fully sensitive to McC, we conclude that yej mutations interfere with McC uptake and that YejABEF is the only inner membrane transporter responsible for McC uptake in E. coli. Other substrates of YejABEF remain to be identified.     

Improved biotin,thiamine, and lipoic acid biosynthesis by engineering the global regulator IscR

Biotin, thiamine, and lipoic acid are industrially important molecules naturally synthesized by microorganisms via biosynthetic pathways requiring iron-sulfur (FeS) clusters. Current production is exclusively by chemistry because pathway complexity hinders development of fermentation processes. For biotin, the main bottleneck is biotin synthase, BioB, a S-adenosyl methionine-dependent radical enzyme that converts dethiobiotin (DTB) to biotin. BioB overexpression is toxic, though the mechanism remains unclear. We identified single mutations in the global regulator IscR that substantially improve cellular tolerance to BioB overexpression, increasing Escherichia coli DTB-to-biotin biocatalysis by more than 2.2-fold. Based on proteomics and targeted overexpression of FeS-cluster biosynthesis genes, FeS-cluster depletion is the main reason for toxicity. We demonstrate that IscR mutations significantly affect cell viability and improve cell factories for de novo biosynthesis of thiamine by 1.3-fold and lipoic acid by 1.8-fold. We illuminate a novel engineering target for enhancing biosynthesis of complex FeS-cluster-dependent molecules, paving the way for industrial fermentation processes.