The effect of Clp proteins on DnaK-dependent refolding of bacterial luciferases

A study was made of the refolding of bacterial luciferases of Vibrio fischeri, V. harveyi, Photobacterium phosphoreum, and Photorhabdus luminescens. By reaction rate, luciferases were divided into two groups. The reaction rate constants of fast luciferases of V. fischeri and Ph. phosphoreum were about tenfold higher than those of slow luciferases of Ph. luminescens and V. harveyi. The order of increasing luciferase thermostability was Ph. phosphoreum, V. fischeri, V. harveyi, and Ph. luminescens. The refolding of thermoinactivated luciferases completely depended on the active DnaK-DnaJ-GrpE chaperone system. Thermolabile fast luciferases of V. fischeri and Ph. phosphoreum showed highly efficient rapid refolding. Slower and less efficient refolding was characteristic of thermostable slow luciferases of V. harveyi and Ph. luminescens. Chaperones of the Clp family were tested for effect on the efficiency of DnaK-dependent refolding of bacterial luciferases in Escherichia coli cells. The rate and extent of refolding were considerably lower in the clpB mutant than in wild-type cells. In E. coli cells with mutant clpA, clpP, of clpX showed a substantially lower luciferase refolding after heat shock.     

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.     

Thermostability of firefly luciferases affects efficiency of detection by in vivo bioluminescence

Luciferase from the North American firefly (Photinis pyralis) is a useful reporter gene in vivo, allowing noninvasive imaging of tumor growth, metastasis, gene transfer, drug treatment, and gene expression. Luciferase is heat labile with an in vitro halflife of approximately 3 min at 37 degrees C. We have characterized wild type and six thermostabilized mutant luciferases. In vitro, mutants showed half-lives between 2- and 25-fold higher than wild type. Luciferase transfected mammalian cells were used to determine in vivo half-lives following cycloheximide inhibition of de novo protein synthesis. This showed increased in vivo thermostability in both wild-type and mutant luciferases. This may be due to a variety of factors, including chaperone activity, as steady-state luciferase levels were reduced by geldanamycin, an Hsp90 inhibitor. Mice inoculated with tumor cells stably transfected with mutant or wild-type luciferases were imaged. Increased light production and sensitivity were observed in the tumors bearing thermostable luciferase. Thermostable proteins increase imaging sensitivity. Presumably, as more active protein accumulates, detection is possible from a smaller number of mutant transfected cells compared to wild-type transfected cells.     

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.     

Bioluminescence of the insect pathogen Xenorhabdus luminescens.

Luminescence of batch cultures of Xenorhabdus luminescens was maximal when cultures approached stationary phase; the onset of in vivo luminescence coincided with a burst of synthesis of bacterial luciferase, the enzyme responsible for luminescence. Expression of luciferase was aldehyde limited at all stages of growth, although more so during the preinduction phase. Luciferase was purified from cultures of X. luminescens Hm to a specific activity of 4.6 x 10(13) guanta/s per mg of protein and found to be similar to other bacterial luciferases. The Xenorhabdus luciferase consisted of two subunits with approximate molecular masses of 39 and 42 kilodaltons. A third protein with a molecular mass of 24 kilodaltons copurified with luciferase, and in its presence, either NADH or NADPH was effective in stimulating luminescence, indicating that this protein is an NAD(P)H oxidoreductase. Luciferases from two other luminous bacteria, Vibrio harveyii (B392) and Vibrio cholerae (L85), were partially purified, and their subunits were separated in 5 M urea and tested for complementation with the subunits prepared from X. luminescens Hb. Positive complementation was seen with luciferase subunits among all three species. The slow decay kinetics of the Xenorhabdus luciferase were attributed to the alpha subunit.     

Bioluminescence of the insect pathogen Xenorhabdus luminescens

Luminescence of batch cultures of Xenorhabdus luminescens was maximal when cultures approached stationary phase; the onset of in vivo luminescence coincided with a burst of synthesis of bacterial luciferase, the enzyme responsible for luminescence. Expression of luciferase was aldehyde limited at all stages of growth, although more so during the preinduction phase. Luciferase was purified from cultures of X. luminescens Hm to a specific activity of 4.6 x 10(13) guanta/s per mg of protein and found to be similar to other bacterial luciferases. The Xenorhabdus luciferase consisted of two subunits with approximate molecular masses of 39 and 42 kilodaltons. A third protein with a molecular mass of 24 kilodaltons copurified with luciferase, and in its presence, either NADH or NADPH was effective in stimulating luminescence, indicating that this protein is an NAD(P)H oxidoreductase. Luciferases from two other luminous bacteria, Vibrio harveyii (B392) and Vibrio cholerae (L85), were partially purified, and their subunits were separated in 5 M urea and tested for complementation with the subunits prepared from X. luminescens Hb. Positive complementation was seen with luciferase subunits among all three species. The slow decay kinetics of the Xenorhabdus luciferase were attributed to the alpha subunit.     

Growth and luminescence of the bacterium Xenorhabdus luminescens from a human wound

Xenorhabdus luminescens, a newly isolated luminous bacterium collected from a human wound, was characterized. The effects of ionic strength, temperature, oxygen, and iron on growth and development of the bioluminescent system were studied. The bacteria grew and emitted light best at 33 degrees C in a medium with low salt, and the medium after growth of cells to a high density was found to have antibiotic activity. The emission spectrum peaked at 482 nm in vivo and at 490 nm in vitro. Both growth and the development of luminescence in X. luminescens required oxygen and iron. The isolated luciferase itself exhibited a temperature optimum at about 40 degrees C; after purification by affinity chromatography, it showed two bands (52 and 41 kilodaltons) on sodium dodecyl sulfate-polyacrylamide gel electrophoresis, indicative of an alpha and beta subunit structure. Reduced flavin mononucleotide (Km of 1.4 microM) and tetradecanal (Km of 2.1 microM) were the best substrates for the luciferase, and the first-order decay constant under these conditions at 37 degrees C was 0.79 s-1.     

Growth and luminescence of the bacterium Xenorhabdus luminescens from a human wound.

Xenorhabdus luminescens, a newly isolated luminous bacterium collected from a human wound, was characterized. The effects of ionic strength, temperature, oxygen, and iron on growth and development of the bioluminescent system were studied. The bacteria grew and emitted light best at 33 degrees C in a medium with low salt, and the medium after growth of cells to a high density was found to have antibiotic activity. The emission spectrum peaked at 482 nm in vivo and at 490 nm in vitro. Both growth and the development of luminescence in X. luminescens required oxygen and iron. The isolated luciferase itself exhibited a temperature optimum at about 40 degrees C; after purification by affinity chromatography, it showed two bands (52 and 41 kilodaltons) on sodium dodecyl sulfate-polyacrylamide gel electrophoresis, indicative of an alpha and beta subunit structure. Reduced flavin mononucleotide (Km of 1.4 microM) and tetradecanal (Km of 2.1 microM) were the best substrates for the luciferase, and the first-order decay constant under these conditions at 37 degrees C was 0.79 s-1.     

Control of luminescence decay and flavin binding by the LuxA carboxyl-terminal regions in chimeric bacterial luciferases.

Bacterial luciferases (LuxAB) can be readily classed as slow or fast decay luciferases based on their rates of luminescence decay in a single turnover assay. Luciferases from Vibrio harveyi and Xenorhabdus (Photorhabdus) luminescens have slow decay rates, and those from the Photobacterium genus, such as P. (Vibrio) fischeri, P. phosphoreum, and P. leiognathi, have rapid decay rates. By generation of an X. luminescens-based chimeric luciferase with a 67 amino acid substitution from P. phosphoreum LuxA in the central region of the LuxA subunit, the "slow" X. luminescens luciferase was converted into a chimeric luciferase, LuxA(1)B, with a significantly more rapid decay rate. Two other chimeras with P. phosphoreum sequences substituted closer to the carboxyl terminal of LuxA, LuxA(2)B and LuxA(3)B, retained the characteristic slow decay rates of X. luminescens luciferase but had weaker interactions with both reduced and oxidized flavins, implicating the carboxyl-terminal regions in flavin binding. The dependence of the luminescence decay on concentration and type of fatty aldehyde indicated that the decay rate of "fast" luciferases arose due to a high dissociation constant (K(a)) for aldehyde (A) coupled with the rapid decay of the resultant aldehyde-free complex via a dark pathway. The decay rate of luminescence (k(T)) was related to the decanal concentration by the equation: k(T) = (k(L)A + k(D)K(a))/(K(a) + A), showing that the rate constant for luminescence decay is equal to the decay rate via the dark- (k(D)) and light-emitting (k(L)) pathways at low and high aldehyde concentrations, respectively. These results strongly implicate the central region in LuxA(1)B as critical in differentiating between "slow" and "fast" luciferases and show that this distinction is primarily due to differences in aldehyde affinity and in the decomposition of the luciferase-flavin-oxygen intermediate.     

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.     

Codon-optimized Luciola italica luciferase variants for mammalian gene expression in culture and in vivo

Luciferases have proven to be useful tools in advancing our understanding of biologic processes. Having a multitude of bioluminescent reporters with different properties is highly desirable. We characterized codon-optimized thermostable green- and red-emitting luciferase variants from the Italian firefly Luciola italica for mammalian gene expression in culture and in vivo. Using lentivirus vectors to deliver and stably express these luciferases in mammalian cells, we showed that both variants displayed similar levels of activity and protein half-lives as well as similar light emission kinetics and higher stability compared to the North American firefly luciferase. Further, we characterized the red-shifted variant for in vivo bioluminescence imaging. Intramuscular injection of tumor cells stably expressing this variant into nude mice yielded a robust luciferase activity. Light emission peaked at 10 minutes post-d-luciferin injection and retained > 60% of signal at 1 hour. Similarly, luciferase activity from intracranially injected glioma cells expressing the red-shifted variant was readily detected and used as a marker to monitor tumor growth over time. Overall, our characterization of these codon-optimized luciferases lays the groundwork for their further use as bioluminescent reporters in mammalian cells.     

Identity of the emitter in the bacterial luciferase luminescence reaction: binding and fluorescence quantum yield studies of 5-decyl-4a-hydroxy-4a,5-dihydroriboflavin-5'-phosphate as a model

The excited state of 4a-hydroxy-4a,5-dihydroFMN has been postulated to be the emitter in the bacterial bioluminescence reaction. However, while the bioluminescence quantum yield of the luciferase emitter is about 0.16, chemiluminescence and fluorescence quantum yields of earlier flavin models mimicking the luciferase emitter were no more than 10(-5). To further examine the proposed chemical identity of the luciferase emitter, 5-decyl-4a-hydroxy-4a,5-dihydroFMN was prepared as a new flavin model. Both the wild-type Vibrio harveyi luciferase and a catalytically active alphaC106A mutant formed complexes with the flavin model at a 1:1 molar ratio with K(d) values at 2.4 and 1.2 microM, respectively. This flavin model inhibited the activity of both luciferases, suggesting that it was bound to the enzyme active center. While the free flavin model was itself only very weakly fluorescent, its binding to either luciferase species resulted in markedly enhanced fluorescence, peaking at 440 nm. The fluorescence quantum yields of 5-decyl-4a-hydroxy-4a,5-dihydroFMN bound to wild-type and alphaC106A luciferases were 0.08 and 0.05, respectively, which are about 50% of the respective emitter bioluminescence quantum yields of these two luciferases. The present findings clearly demonstrated that the luciferase active site was suitable for marked enhancement of fluorescence of 4a-hydroxyflavin and, hence, provides a strong support to the proposed identity of 4a-hydroxy-4a,5-dihydroFMN, in its exited state, as the luciferase emitter.     

Use of bacterial and firefly luciferases as reporter genes in DEAE-dextran-mediated transfection of mammalian cells.

The aim of this study was to compare three different luciferase genes by placing them in a single reporter vector and expressing them in the same mammalian cell type. The luciferase genes investigated were the luc genes from the fireflies Photinus pyralis (PP) and Luciola mingrelica (LM) and the lux AB5 gene, a translational fusion of the two subunits of the bacterial luciferase from Vibrio harveyi (VH). The chloramphenicol acetyltransferase (CAT) gene was also included in this study for comparison. The performances of the assay methods of the corresponding enzymes were evaluated using reference materials and the results of the expressed enzymes following transfection were calculated using calibration curves. All of the bioluminescent assays possess high reproducibility both within and between the batches (less than 15%). The comparison of the assay methods shows that firefly luciferases have the highest detection sensitivity (0.05 and 0.08 amol for PP and LM, respectively) whereas the VH bacterial luciferase has 5 amol and CAT 100 amol. On the other hand, the transfection of the various plasmids shows that the content of the expressed enzyme within the cells is much higher for CAT than for the other luciferase genes. VH luciferase is expressed at very low levels in mammalian cells due to the relatively high temperature of growing of the mammalian cells that seems to impair the correct folding of the active enzyme. PP and LM luciferases are both expressed at picomolar level but usually 10 to 70 times less in content with respect to CAT within the transfected cells. On the basis of these results the overall improvement in sensitivity related to the use of firefly luciferases as reporter genes in mammalian cells is about 30 to 50 times with respect to that of CAT.     

Firefly luciferase genes from the subfamilies Psilocladinae and Ototretinae (Lampyridae, Coleoptera)

Firefly luciferase genes have been isolated from approximately 20 species of Lampyrinae, Luciolinae, and Photurinae. These are mostly nocturnal luminescent species that use light signals for sexual communication. In this study, we isolated three cDNAs for firefly luciferase from Psilocladinae (Cyphonocerus ruficollis) and Ototretinae (Drilaster axillaris and Stenocladius azumai), which are diurnal non-luminescent or weakly luminescent species that may use pheromones for communication. The amino acid sequences deduced from the three cDNAs showed 81-89% identities to each other and 60-81% identities with known firefly luciferases. The three purified recombinant proteins showed luminescence and fatty acyl-CoA synthetic activities, as observed in other firefly luciferases. The emission maxima by the three firefly luciferases (λmax, 545-546 nm) were shorter than those by known luciferases from the nocturnal fireflies (λmax, 550-568 nm). These results suggest that the primary structures and enzymatic properties of luciferases are conserved in Lampyridae, but the luminescence colors were red-shifted in nocturnal species compared to diurnal species.     

Expression of luciferase genes from different origins in Bacillus subtilis

Summary A group of vectors for luciferase expression in Bacillus subtilis was constructed. So far, only bacterial luciferases have been expressed in Bacillus, but in this study we wanted also to express genes encoding eukaryotic luciferases to perform direct comparisons of the light levels produced by the two different systems in B. subtilis. The vectors constructed can replicate both in Escherichia coli and B. subtilis, and the luciferase expression is strictly regulated due to the dual plasmid system used. Nearly a 100-fold increase in light production compared to previous results was achieved when genes encoding bacterial luciferase were inserted into the constructs and transformed into B. subtilis. An additional tenfold increase in light production was obtained when luciferase genes from the North American firefly (Photinus pyralis) or a click beetle (Pyrophorus plagiophtalamus) were introduced in a similar fashion into B. subtilis. Measurement of the light emission was performed without disruption of bacterial cells in a real-time manner, which is a common feature when working with all of these constructions. Structures of the shuttle vector constructs and results from light emission measurements are presented.     

Probing the functionalities of alphaGlu328 and alphaAla74 of Vibrio harveyi luciferase by site-directed mutagenesis and chemical rescue

This work aimed at identifying essential residues on the alpha subunit of Vibrio harveyi luciferase and elucidating their functional roles. Four conserved alpha-subunit residues at the proposed luciferase active site were initially mutated to Ala. Screening of the in vivo bioluminescence of cells expressing these mutated luciferases allowed the work to focus on alphaGlu328 for additional mutations to Phe, Leu, Gln, His, and Asp. V. harveyi luciferase is known to contain, at the same proposed active site, an unusual cis-peptide linkage between alphaAla74 and alphaAla75. To explore the structure-function relationship, luciferase variants alphaA74F and alphaA74G were constructed. The six alphaGlu328-mutated and the two alphaAla74-mutated luciferase variants were purified and characterized with respect to Vmax, Michaelis constants, light and dark decays, quantum yield, and, for alphaE328F and alphaA74F, yield of the 4a-hydroperoxyFMN intermediate and the ability to oxidize aldehyde substrate. Results indicated that the structural integrities of both alphaGlu328 and alphaAla74 were essential to luciferase bioluminescence activity. Moreover, the essentiality of alphaGlu328 was linked to the acidic nature of its side chain. The low activity of alphaE328A was sensitive to chemical rescue by sodium acetate, an effect that was not reproduced by phosphate. The efficiency of activity rescue by acetate progressively increased at lower pH in the range from 6.0 to 8.0, supporting the interpretation of alphaGlu328 as a catalytic general acid. The rescuing effect of acetate was on a reaction step after the formation of the 4a-hydroperoxyFMN intermediate. The exact catalytic function of alphaGlu328 is unclear, but possibilities are discussed.     

Implication of a critical residue (Glu175) in structure and function of bacterial luciferase

Structural properties of a bacterial luciferase mutant, evolved by random mutagenesis, have been investigated. Bacterial luciferases (LuxAB) can be readily classed as slow or fast decay luciferases based on their rates of luminescence decay in a single turnover assay. By random mutagenesis, one of the mutants generated by a single mutation on LuxA at position 175 (E175G) resulted in the "slow decay" Xenorhabdus luminescens luciferase was converted into a luciferase with a significantly more rapid decay rate [Hosseinkhani, S., Szittner, R. and Meighen, E.A. (2005) Biochemical Journal 385, 575-580]. A single mutation (E175G), in a loop that connects alpha helix 5 and beta sheet 5 brought about changes in the kinetic and structural properties of the enzyme. Enhancement of tryptophan fluorescence was observed with a lower degree of fluorescence quenching by acrylamide upon mutation. Near- and far-UV circular dichroism spectra of the native and mutant forms suggested formation of an intermediate structure, further supported by 8-anilino-1-naphthalene-sulphonic acid (ANS) fluorescence which indicated lower exposure of hydrophobic residues as a result of mutation. Fluorescence quenching studies utilizing acrylamide indicated a more accessible fluor for the native form. Thus, the E175G point mutation appears to change the enzymatic decay rate by inducing a substantial tertiary structural change, without a large effect on secondary structural elements, as revealed by Fourier transform IR spectroscopy. Overall, the mutation caused structural changes that go beyond the simple change in orientation of Glu175.     

Activity coupling and complex formation between bacterial luciferase and flavin reductases.

Luminous bacteria contain several species of flavin reductases, which catalyze the reduction of FMN using NADH and/or NADPH as a reductant. The reduced FMN (i.e. FMNH(2)) so generated is utilized along with a long-chain aliphatic aldehyde and molecular oxygen by luciferase as substrates for the bioluminescence reaction. In this report, the general properties of luciferases and reductases from luminous bacteria are briefly summarized. Earlier and more recent studies demonstrating the direct transfer of FMNH(2) from reductases to luciferase are surveyed. Using reductases and luciferases from Vibrio harveyi and Vibrio fischeri, two mechanisms were uncovered for the direct transfer of reduced flavin cofactor and reduced flavin product of reductase to luciferase. A complex of an NADPH-specific reductase (FRP(Vh)) and luciferase from V. harveyi has been detected in vitro and in vivo. Both constituent enzymes in such a complex are catalytically active. The reduction of FRP(Vh)-bound FMN cofactor by NADPH is reversible, allowing the cellular contents of NADP(+) and NADPH as a factor for the regulation of the production of FMNH(2) by FRP(Vh) for luciferase bioluminescence. Other regulations of the activity coupling between reductase and luciferase are also discussed.