Effects of 3' end deletions from the Vibrio harveyi luxB gene on luciferase subunit folding and enzyme assembly: generation of temperature-sensitive polypeptide folding mutants

Ten recombinant plasmids have been constructed by deletion of specific regions from the plasmid pTB7 that carries the luxA and luxB genes, encoding the alpha and beta subunits of luciferase from Vibrio harveyi, such that luciferases with normal alpha subunits and variant beta subunits were produced in Escherichia coli cells carrying the recombinant plasmids. The original plasmid, which conferred bioluminescence (upon addition of exogenous aldehyde substrate) on E. coli carrying it, was constructed by insertion of a 4.0-kb HindIII fragment of V. harveyi DNA into the HindIII site of plasmid pBR322 [Baldwin, T.O., Berends, T., Bunch, T. A., Holzman, T. F., Rausch, S. K., Shamansky, L., Treat, M. L., & Ziegler, M. M. (1984) Biochemistry 23, 3663-3667]. Deletion mutants in the 3' region of luxB were divided into three groups: (A) those with deletions in the 3' untranslated region that left the coding sequences intact, (B) those that left the 3' untranslated sequences intact but deleted short stretches of the 3' coding region of the beta subunit, and (C) those for which the 3' deletions extended from the untranslated region into the coding sequences. Analysis of the expression of luciferase from these variant plasmids has demonstrated two points concerning the synthesis of luciferase subunits and the assembly of those subunits into active luciferase in E. coli. First, deletion of DNA sequences 3' to the translational open reading frame of the beta subunit that contain a potential stem and loop structure resulted in dramatic reduction in the level of accumulation of active luciferase in cells carrying the variant plasmids, even though the luxAB coding regions remained intact.     

The nucleotide sequence of the luxA and luxB genes of Xenorhabdus luminescens HM and a comparison of the amino acid sequences of luciferases from four species of bioluminescent bacteria

The luxA and luxB genes of bioluminescent bacteria encode the alpha and beta subunits of luciferase, respectively. Sequences of the luxA and luxB genes of Xenorhabdus luminescens, the only terrestrial bioluminescent bacterium known, were determined and the amino acid sequence of luciferase deduced. The alpha subunit was found to contain 360 amino acids and has a calculated molecular weight of 41,005 Da, while the beta subunit contains 327 amino acids and has a calculated molecular weight of 37,684 Da. Alignment of this luciferase with the luciferases of three marine bacteria showed 196 (or 55%) conserved residues in the alpha subunit and 114 (or 35%) conserved residues in the beta subunit. The highest degree of homology between any two species was between the luciferases of X. luminescens and Vibrio harveyi with 84% identity in the alpha subunits and 59% identity in the beta subunits.     

Polycistronic mRNAs code for polypeptides of the Vibrio harveyi luminescence system.

DNA coding for the alpha and beta subunits of Vibrio harveyi luciferase, the luxA and luxB genes, and the adjoining chromosomal regions on both sides of these genes (total of 18 kilobase pairs) was cloned into Escherichia coli. Using labeled DNA coding for the alpha subunit as a hybridization probe, we identified a set of polycistronic mRNAs (2.6, 4, 7, and 8 kilobases) by Northern blotting; the most prominent of these was the one 4 kilobases long. This set of mRNAs was induced during the development of bioluminescence in V. harveyi. Furthermore, the same set of mRNAs was synthesized in E. coli by a recombinant plasmid that contained a 12-kilobase pair length of V. harveyi DNA and expressed the genes for the luciferase subunits. A cloned DNA segment corresponding to the major 4-kilobase mRNA coded for the alpha and beta subunits of luciferase, as well as a 32,000-dalton protein upstream from these genes that could be specifically modified by acyl-coenzyme A and is a component of the bioluminescence system. V. harveyi mRNA that was hybridized to and released from cloned DNA encompassing the luxA and luxB genes was translated in vitro. Luciferase alpha and beta subunits and the 32,000-dalton polypeptide were detected among the products, along with 42,000- and 55,000-dalton polypeptides, which are encoded downstream from the lux genes and are thought to be involved in luminescence.     

Structure and properties of luciferase from Photobacterium phosphoreum

The nucleotide sequences of the luxA and luxB genes coding for the alpha and beta subunits, respectively, of luciferase from Photobacterium phosphoreum have been determined. The predicted amino acid sequences of the alpha and beta subunits were shown to be significantly different from other bacterial luciferases with 62 to 88% identity with the alpha subunits and 47 to 71% identity with the beta subunits of other species. Expression of the different luciferases appear to correlate with the number of modulator codons. Kinetic properties of P. phosphoreum luciferase were shown to reflect the bacterium's natural cold temperature habitat.     

Cloning and nucleotide sequences of lux genes and characterization of luciferase of Xenorhabdus luminescens from a human wound.

Xenorhabdus luminescens HW is the only known luminous bacterium isolated from a human (wound) source. A recombinant plasmid was constructed that contained the X. luminescens HW luxA and luxB genes, encoding the luciferase alpha and beta subunits, respectively, as well as luxC, luxD, and a portion of luxE. The nucleotide sequences of these lux genes, organized in the order luxCDABE, were determined, and overexpression of the cloned luciferase genes was achieved in Escherichia coli host cells. The cloned luciferase was indistinguishable from the wild-type enzyme in its in vitro bioluminescence kinetic properties. Contrary to an earlier report, our findings indicate that neither the specific activity nor the size of the alpha (362 amino acid residues, Mr 41,389) and beta (324 amino acid residues, Mr 37,112) subunits of the X. luminescens HW luciferase was unusual among known luminous bacterial systems. Significant sequence homologies of the alpha and beta subunits of the X. luminescens HW luciferase with those of other luminous bacteria were observed. However, the X. luminescens HW luciferase was unusual in the high stability of the 4a-hydroperoxyflavin intermediate and its sensitivity to aldehyde substrate inhibition.     

Isolation of the lux genes from Photobacterium leiognathi and expression in Escherichia coli

Genes necessary for luminescence (lux genes) in the marine bacterium Photobacterium leiognathi, strain PL721, were isolated and expressed in Escherichia coli. A 15-kb fragment obtained from a partial digestion of PL721 DNA with HindIII was cloned into the plasmid pACYC184, resulting in the hybrid plasmid pSD721. When pSD721 was transformed into E. coli ED8654, the resulting transformants were luminous with no additions to the cells, indicating that it contained the structural genes coding for the alpha and beta subunits of luciferase (luxA and luxB), and for components involved in aldehyde biosynthesis. Hybridization analysis with luxA and luxB 32P probes confirmed the location of these two genes on the 15-kb insert. When pSD721 was transformed into four different strains of E. coli, luminescence expression varied widely in amount and in pattern. In some strains, luminescence developed like an autoinducible system, and at maximum induction was very bright, even with no addition of aldehyde, while in others, luminescence was 100-fold less, and no induction was seen. In no case was luminescence affected by shifts in temperature, osmolarity, or iron concentration. These results indicate that, while the complete lux regulon is apparently contained on the 15-kb cloned fragment, the regulation of the lux regulon in pSD721 is subject to host controls by E. coli, controls which vary widely among different E. coli strains.     

Expression of the cloned subunits of bacterial luciferase from separate replicons

The lux A and lux B genes of Vibrio harveyi, encoding the alpha and beta subunits of bacterial luciferase, were cloned individually into Escherichia coli in two different compatible plasmids. Active luciferase was formed in an amount equal to that produced in cells carrying a plasmid with the cloned genes on a single fragment.     

Nucleotide sequence, expression, and properties of luciferase coded by lux genes from a terrestrial bacterium

The lux genes required for expression of luminescence have been cloned from a terrestrial bacterium, Xenorhabdus luminescens, and the nucleotide sequences of the luxA and luxB genes coding for the alpha and beta subunits of luciferase determined. The lux gene organization was closely related to that of marine bacteria from the Vibrio genus with the luxD gene being located immediately upstream and the luxE downstream of the luciferase genes, luxAB. A high degree of homology (85% identity) was found between the amino acid sequences of the alpha subunits of X. luminescens luciferase and the luciferase from a marine bacterium, Vibrio harveyi, whereas the beta subunits of the two luciferases had only 60% identity in amino acid sequence. The similarity in the sequences of the alpha subunits of the two luciferases was also reflected in the substrate specificities and turnover rates with different fatty aldehydes supporting the proposal that the alpha subunit almost exclusively controls these properties. The luciferase from X. luminescens was shown to have a remarkably high thermal stability being stable at 45 degrees C (t 1/2 greater than 3 h) whereas V. harveyi luciferase was rapidly inactivated at this temperature (t 1/2 = 5 min). These results indicate that the X. luminescens lux system may be the bacterial bioluminescent system of choice for application in coupled luminescent assays and expression of lux genes in eukaryotic systems at higher temperatures.     

Generation of thermostable monomeric luciferases from Photorhabdus luminescens

Bacterial luciferases and the genes encoding these light-emitting enzymes have an increasing number of applications in biological sciences. Temperature lability and the heterodimeric nature of these luciferases have been the major obstacles for their widespread use, for instance, as genetic reporters. Escherichia coli expressing wild-type Photorhabdus luminescens luciferase was found to produce eight times more light than the corresponding Vibrio harveyi luciferase clone in vivo at 37 degrees C. Three monomeric luciferases were created by translationally fusing the two genes encoding luxA and luxB proteins of P. luminescens. These clones were equally active in producing light in vivo when cultivated at 37 degrees C compared to cultivation at 30 degrees C. The fusion containing the longest linker showed the highest activity. In vitro, the monomeric luciferases were less active having at best 20% of activity of the wild-type enzyme due to the partial formation of insoluble aggregates. The results suggest that P. luminescens luciferase and monomeric derivatives thereof should be more suitable than the corresponding V. harveyi enzyme to be used as reporters in cell types which need cultivation at elevated temperatures.     

Engineering of monomeric bacterial luciferases by fusion of luxA and luxB genes in Vibrio harveyi

Luciferase (Lux)-encoding sequences are very useful as reporter genes. However, a drawback when applying Vibrio harveyi Lux as a reporter enzyme in eukaryotic cells, is that it is a heterodimeric enzyme, thus requiring simultaneous synthesis of both Lux subunits to be active. To overcome this disadvantage, luxA and luxB genes encoding the A and B subunits of this light-emitting heterodimeric Lux, were fused and expressed in Escherichia coli. Comparative analysis of four fused monomeric Lux enzymes by in vivo enzyme assay, immunoblotting and partial enzyme purification, showed that the fused Lux were active both as AB or as BA monomers, albeit at different levels (up to 80% activity for AB and up to 2% for BA, as compared with the wild type binary A + B construct). One of the LuxAB fusion proteins was stably expressed in calli of Nicotiana tabacum, and displayed very high Lux activity, thus demonstrating its potential as a reporter enzyme in eukaryotic systems.     

Nucleotide sequence of the luxB gene of Vibrio harveyi and the complete amino acid sequence of the beta subunit of bacterial luciferase

The nucleotide sequence of the 1.30-kilobase EcoRI/BglII fragment from Vibrio harveyi carrying the majority of the luciferase beta subunit coding region (luxB gene) has been determined. The EcoRI/BglII fragment was derived from a 4.0-kilobase HindIII fragment carrying both luxA and luxB which was detected in a genomic clone bank based on the expression of bioluminescence from colonies of Escherichia coli carrying V. harveyi HindIII fragments in plasmid pBR322 (Baldwin, T. O., Berends, T., Bunch, T. A., Holzman, T. F., Rausch, S. K., Shamansky, L., Treat, M. L., and Ziegler, M. M. (1984) Biochemistry 23, 3663-3667). The entire alpha subunit coding sequence (luxA gene) and the amino-terminal 13 codons of the beta subunit sequence (luxB gene) were contained on a 1.85-kilobase EcoRI fragment, the sequence of which has been reported (Cohn, D. H., Mileham, A. J., Simon, M. I., Nealson, K. H., Rausch, S. K., Bonam, D., and Baldwin, T. O. (1985) J. Biol. Chem. 260, 6139-6146). The beta subunit coding sequence was found to terminate 972 bases past the start of the luxB coding sequence. The beta subunit had a calculated molecular weight of 36,349 and comprised a total of 324 amino acid residues; the alpha beta dimer had a molecular weight (alpha + beta) of 76,457. There were 27 base pairs separating the stop codon of the beta subunit structural gene and a 340-base open reading frame extending to (and beyond) the distal BglII site. Approximately two-thirds of the beta subunit was sequenced by protein chemical techniques. The amino acid sequence predicted from the DNA sequence, with few exceptions, confirmed the chemically determined sequence, and the measured amino acid composition was in excellent agreement with the composition implied from the DNA sequence.     

Construction of cloning vectors using the Vibrio harveyi luminescence genes luxA and luxB as markers

A synthetic oligodeoxyribonucleotide harboring four new restriction sites was inserted into the luxB gene of Vibrio harveyi. This insertion did not disrupt the reading frame. An active beta-subunit was synthesized since a plasmid with both the luxA and mutated luxB genes conferred upon Escherichia coli the bacterial luciferase (Lux) phenotype in the presence of an aldehyde. Ligation of a piece of foreign DNA at these new cloning sites in the vector extinguish the Lux phenotype of the transformed bacteria. Therefore, the plasmid was used as a cloning vector, and recombinant DNA-containing bacteria were detected by the loss of bioluminescence. To create more versatile plasmids, the intergenic region of phage f1 was inserted outside of the lux genes. The selection by loss of bioluminescence presents several advantages over the white/blue selection of the lacZ gene on indicator plates.     

Enzymes assembled from Aquifex aeolicus and Escherichia coli leucyl-tRNA synthetases

Aquifex aeolicus alphabeta-LeuRS is the only known heterodimeric LeuRS, while Escherichia coli LeuRS is a canonical monomeric enzyme. By using the genes encoding A. aeolicus and E. coli LeuRS as PCR templates, the genes encoding the alpha and beta subunits from A. aeolicus alphabeta-LeuRS and the equivalent amino- and carboxy-terminal parts of E. coli LeuRS (identified as alpha' and beta') were amplified and recombined using suitable plasmids. These recombinant plasmids were transformed or cotransformed into E. coli to produce five monomeric and five heterodimeric LeuRS mutants. Seven of these were successfully overexpressed in vivo and purified, while three dimeric mutants with the beta' part of E. coli LeuRS were not successfully expressed. The seven purified mutants catalyzed amino acid activation, although several exhibited reduced aminoacylation properties. Removal of the last 36 residues of the alpha subunit of the A. aeolicus enzyme was determined to be deleterious for tRNA charging. Indeed, subunit exchange showed that the cross-species-specific recognition of A. aeolicus tRNA(Leu) occurs at the alpha subunit. None of the mixed E. coli-A. aeolicus enzymes were as thermostable as the native alphabeta-LeuRS. However, the fusion of the two alpha and beta peptides from A. aeolicus as a single chain analogous to canonical LeuRS resulted in a product more resistant to heat denaturation than the original enzyme.     

Construction and testing of a bacterial luciferase reporter gene system forin Vivo measurement of nonsense suppression inStreptomyces

A reporter gene system, based on luciferase genes from Vibrio harvei, was constructed for measurement of translation nonsense suppression in Streptomyces. Using the site-directed mutagenesis the TCA codon in position 13 of the luxB gene was replaced by all of the three stop codons individually. By cloning of luxA and luxB genes under the control of strong constitutive Streptomyces promoter ermE* in plasmid pUWL201 we created Wluxl with the wild-type sequence and pWlux2, pWlux3 and pWlux4 plasmids containing TGA-, TAG- and TAA-stop codons, respectively. Streptomyces lividans TK 24 was transformed with the plasmids and the reporter system was tested by growth of the strain in the presence of streptomycin as a translation accuracy modulator. Streptomycin increased nonsense suppression on UAA nearly 10-fold and more than 20-fold on UAG. On the other hand, UGA, the most frequent stop signal in Streptomyces, the effect was negligible.     

Cloning and expression of the Photobacterium phosphoreum luminescence system demonstrates a unique lux gene organization

The organization of the lux structural genes (A-E) in Photobacterium phosphoreum has been determined and a new gene designated as luxF discovered. The P. phosphoreum luminescence system was cloned into Escherichia coli using a pBR322 vector and identified by cross-hybridization with Vibrio fischeri lux DNA. The lux genes were located by specific expression of P. phosphoreum DNA fragments in the T7-phage polymerase/promoter system in E. coli and identification of the labeled polypeptide products. The luxA and luxB gene products (luciferase subunits) were shown to catalyze light emission in the presence of FMNH2, O2, and aldehyde. The luxC, luxD, and luxE gene products (fatty acid reductase subunits) responsible for aldehyde biosynthesis could be specifically acylated with 3H-labeled fatty acids. The order of the lux genes in P. phosphoreum was found to be luxCDABFE with luxF coding for a new polypeptide of 26 kDa. The presence of a new gene in the P. phosphoreum luminescence system between luxB and luxE as compared to the organization of the lux structural gene in V. fischeri and Vibrio harveyi (luxCDABE) demonstrates that the luminescent systems in the marine bacteria have significantly diverged. The discovery of the luxF gene provides the basis for elucidating the role of its gene product in the expression of luminescence in different marine bacteria.     

An Escherichia coli biosensor strain for amplified and high throughput detection of antimicrobial agents

We report here the construction of a bacterial reporter system for high-throughput screening of antimicrobial agents. The test organism is the Escherichia coli K-12 strain carrying luciferase genes luxC, luxD, luxA, luxB, and luxE from the bioluminescent bacterium Photorhabdus luminescens in a runaway replication plasmid. The replication of the plasmid can be induced, resulting in a change of the plasmid copy number from 1-2/cell to several hundreds per cell within tens of minutes. This increase in plasmid copies is independent of the replication of the host cells. The system will therefore amplify the effects of antibiotics inhibiting bacterial replication machinery, such as fluoroquinolones, and the inhibitory effects can be measured in real time by luminometry. The biosensor was compared with a strain engineered to emit light constitutively, and it was shown to be much more sensitive to various antibiotics than conventional overnight cultivation methods. The approach shows great potential for high-throughput screening of new compounds.