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.     

Affinity purification of bacterial luciferase and NAD(P)H:FMN oxidoreductases by FMN-sepharose for analytical applications

A modified purification method for bacterial luciferases and NAD(P)H:FMN oxidoreductases is described which uses FMN-Sepharose alone or coupled to DEAE ion exchange chromatography for the simultaneous purification of luciferase and the various oxidoreductases from Vibrio harveyi, a bright mutant of Vibrio harveyi, Vibrio fischeri, and Photobacterium phosphoreum. This purification method is compared with DEAE-Sepharose CI 6B fractionations from these organisms. Both methods allow the separation of oxidoreductases specific for either NADH or NADPH. The use of FMN-Sepharose coupled to DEAE-Sepharose fractionation allows the isolation of highly purified enzymes. Lacking interfering factors, these are very suitable for various analytical applications based on bacterial bioluminescence enzymes. The partially purified enzymes from the affinity column have higher specific activities than those obtained using DEAE-Sepharose.     

Trigger factor-dependent refolding of bacterial luciferases in Escherichia coli: Kinetics, efficiency, and effect of bichaperone system

The main parameters of the trigger-factor-dependent refolding process of thermally inactivated bacterial luciferases were determined. It has been demonstrated that TF-dependent refolding is less efficient and more time consuming than DnaKJE-dependent refolding. An increase in the cellular concentration of TF was found to result in a dramatic decrease in the maximum level of refolding of thermally inactivated bacterial luciferases. Additionally, the efficiency of TF-dependent refolding was shown to decrease with an increase in the thermal stability of the substrate, that is, the level of TF-dependent refolding is significantly higher for thermolabile luciferases than for thermostable luciferases. For example, the maximum TF-dependent refolding level was determined as 30–40% for thermolabile luciferases from Aliivibrio fischeri and Photobacterium leiognathi, 10% in the case of luciferase from Vibrio harveyi, which is characterized by an average thermal stability, and finally 0.5% in the case of highly stable at high temperatures luciferase from Photorhabdus luminescens. An effect of the DnaKJE-ClpB bichaperone system on the efficiency of TF-dependent refolding was investigated. The ClpB component of the bichaperone system was shown to negatively affect the process efficiency, that is, TF-dependent refolding of bacterial luciferases was found to be far more efficient in E. coli clpB::kan cell strains than in E. coli clpB⁺ strains.     

Trigger factor assists the refolding of heterodimeric but not monomeric luciferases

The refolding of thermally inactivated protein by ATP-independent trigger factor (TF) and ATP-dependent DnaKJE chaperones was comparatively analyzed. Heterodimeric (αβ) bacterial luciferases of Aliivibrio fischeri, Photobacterium leiognathi, and Vibrio harveyi as well as monomeric luciferases of Vibrio harveyi and Luciola mingrelica (firefly) were used as substrates. In the presence of TF, thermally inactivated heterodimeric bacterial luciferases refold, while monomeric luciferases do not refold. These observations were made both in vivo (Escherichia coli ΔdnaKJ containing plasmids with tig gene) and in vitro (purified TF). Unlike TF, the DnaKJE chaperone system refolds both monomeric and heterodimeric luciferases with equal efficiency.     

Growth and luminescence of luminous bacteria promoted by agents of microbial origin

The examination of four species of luminous bacteria Photobacterium leiognathi, Photobacterium phosphoreum, Vibrio fischeri and Vibrio harveyi has enabled us to reveal some nutrient medium components effecting growth, luminescence intensity and luciferase synthesis. These agents are nucleic components (nucleotides, nucleosides and amine bases), amino acids and vitamins, which are part of hydrolysates from the biomass of various lithotrophic microorganisms, hydrogen-oxidizing, ironoxidizing and carboxydobacteria. The effect of promoting agents essentially alters the physiological state and ultrastructure of the cells of luminous bacteria and increases luciferase biosynthesis two- to three-fold compared to a control.     

Sensitivity of dark mutants of various strains of luminescent bacteria to reactive oxygen species

Recent studies indicated that bioluminescence of the marine bacterium Vibrio harveyi may both stimulate DNA repair and contribute to detoxification of deleterious oxygen derivatives. Therefore, it was also proposed that these reactions can be considered biological roles of bacterial luminescence and might act as evolutionary drives in development of luminous systems. However, experimental evidence for the physiological role of luciferase in protection of cells against oxidative stress has been demonstrated only in one bacterial species, raising the question whether this is a specific or a more general phenomenon. Here we demonstrate that in the presence of various oxidants (hydrogen peroxide, cumene hydroperoxide, t-butyl hydroperoxide and ferrous ions) growth of dark mutants of different strains of Vibrio fischeri and Photobacterium leiognathi is impaired relative to wild-type bacteria, though to various extents. Deleterious effects of oxidants on the mutants could be reduced (with different efficiency) by addition of antioxidants, A-TEMPO or 4OH-TEMPO. These results support the hypotheses that (1) activities of bacterial luciferases may detoxify deleterious oxygen derivatives, and (2) significantly different efficiencies of this reaction are characteristic for various luciferases.     

Induction of luciferase synthesis in Beneckea harveyi by other marine bacteria

It has been previously demonstrated that luciferase synthesis in the luminous marine bacteria, Beneckea harveyi and Photobacterium fischeri is induced only when sufficient concentrations of metabolic products (autoinducers) of these bacteria accumulate in growth media. Thus, when cells are cultured in liquid medium there is a lag in luciferase synthesis. A quantitative bioassay for B. harveyi autoinducer was developed and it was shown that many marine bacteria produce a substance that mimics its action, but in different amounts, (20–130% of the activity produced by B. harveyi) depending on the species and strain. This is referred to as alloinduction. None of the bacteria tested produced detectable quantities of inducer for P. fischeri luciferase synthesis. These findings may have significance with respect to the ecology of B. harveyi and P. fischeri.Non-Standard Abbreviation AB medium autoinducer bioassay medium     

Site-directed mutagenesis of bacterial luciferase: Analysis of the ‘essential’ thiol

It has been appreciated for many years that the luciferase from the luminous marine bacterium Vibrio harveyi has a highly reactive cysteinyl residue which is protected from alkylation by binding of flavin. Alkylation of the reactive thiol, which resides in a hydrophobic pocket, leads to inactivation of the enzyme. To determine conclusively whether the reactive thiol is required for the catalytic mechanism, we have constructed a mutant by oligonucleotide directed site-specific mutagenesis in which the reactive cysteinyl residue, which resides at position 106 of the α subunit, has been replaced with a seryl residue. The resulting α106Ser luciferase retains full activity in the bioluminescence reaction, although the mutant enzyme has a ca 100-fold increase in the FMNH₂ dissociation constant. The α106Ser luciferase is still inactivated by N-ethylmaleimide, albeit at about 1/10 the rate of the wild-type (α106Cys) enzyme, demonstrating the existence of a second, less reactive, cysteinyl residue that was obscured in the wild-type enzyme by the highly reactive cysteinyl residue at position α106. An α106Ala variant luciferase was also active, but the α106Val mutant enzyme was about 50-fold less active than the wild type. All three variants (Ser, Ala and Val) appeared to have somewhat reduced affinities for the aldehyde substrate, the valine mutant being the most affected. It is interesting to note that the α106 mutant luciferases are much less subject to aldehyde substrate inhibition than is the wild-type V. harveyi luciferase, suggesting that the molecular mechanism of aldehyde substrate inhibition involves the Cys at α106.     

The cytochromes of luminous bacteria and their coupling to bioluminescence

Vibrio fischeri andV. harveyi possess cytochromes a, b, and c, whereasPhotobacterium leiognathi andP. phosphoreum also contain cytochrome d. In all, cytochrome a as well as some of c binds carbon monoxide. Carbon monoxide does not inhibit bioluminescence (in vivo or in vitro), but carbonyl cyanidem-chlorophenylhydrazone inhibits only in vivo bioluminescence. This inhibition is due to dissipation of the proton motive force which indirectly inhibits bioluminescence by interruption of aldehyde recycling. Bioluminescence is thereby indirectly coupled to the proton motive force.     

Luminous bacteria synthesize luciferase anaerobically

Four species of luminous bacteria, Photobacterium phosphoreum, P. leiognathi, P. fischeri and Beneckea harveyi (two strains of each), were shown to synthesize luciferase anaerobically. One of these, P. phosphoreum, produced as much luciferase anaerobically as it did aerobically, and all four species were found to grow almost equally rapidly under the two sets of conditions. Previous work with B. harveyi and P. fischeri had shown that aerobic luciferase synthesis can proceed only after an inhibitor in the complex medium has been removed and a species-specific autoinducer secreted. All strains tested also removed the inhibitor and secreted an autoinducer anaerobically. The small amount of luciferase produced anaerobically by some strains is thus apparently not due either to lack of removal of inhibitor or to insufficient production of autoinducer but may involve an oxygen-dependent control mechanism.Abbreviations LU light units - OD optical density     

Induction of fatty aldehyde dehydrogenase activity during the development of bioluminescence in Beneckea harveyi.

Bioluminescence rises very rapidly in the later stages of growth of $\text{Beneckea harveyi}$ due to the induction of luciferase activity. This enzyme catalyzes the $\text{in vitro}$ oxidation of FMNH₂ and a long chain aliphatic aldehyde resulting in the emission of light. The present experiments report the discovery of an aldehyde dehydrogenase in $\text{Beneckea harveyi}$ which is remarkably similar to luciferase in its specificity for long chain aliphatic aldehydes. Furthermore, the activity of this enzyme is shown to be induced at the same time as luciferase thus providing strong evidence for a functional implication of aldehyde dehydrogenase in the bioluminescent system of $\text{Beneckea harveyi}$.     

Distribution and Identification of Luminous Bacteria from the Sargasso Sea

Vibrio fischeri and Lucibacterium harveyi constituted 75 of the 83 luminous bacteria isolated from Sargasso Sea surface waters. Photobacterium leiognathi and Photobacterium phosphoreum constituted the remainder of the isolates. Luminescent bacteria were recovered at concentrations of 1 to 63 cells per 100 ml from water samples collected at depths of 160 to 320 m. Two water samples collected at the thermocline yielded larger numbers of viable, aerobic heterotrophic and luminous bacteria. Luminescent bacteria were not recovered from surface microlayer samples. The species distribution of the luminous bacteria reflected previously recognized growth patterns; i.e., L. harveyi and V. fischeri were predominant in the upper, warm waters (only one isolate of P. phosphoreum was obtained from surface tropical waters).     

The effect of camphor on bacterial bioluminescence

Summary The inhibitory effect of camphor on bioluminescence of both bacteria and bacterial luciferase has been examined. The camphor has been shown to be a substrate of cytochrome P-450 of the luminous bacteria Photobacterium fischeri. The inhibition of the luminescence reaction provided evidence for the competitive nature of the interaction of camphor and aliphatic aldehyde at the binding site for luciferase. Camphor is also supposed to interact with P-450. The findings indicate that the hydroxylation process of camphor affects the kinetics of the luminescence.     

Role of Hsp70 (DnaK-DnaJ-GrpE) and Hsp100 (ClpA and ClpB) chaperones in refolding and increased thermal stability of bacterial luciferases in Escherichia coli cells

The role of chaperones Hsp70 (DnaK–DnaJ–GrpE) and Hsp100 (ClpA–ClpB–ClpX) in refolding of thermoinactivated luciferase from the marine bacterium Photobacterium fischeri and the terrestrial bacterium Photorhabdus luminescens has been studied. These luciferases are homologous, but differ greatly in the rate of thermal inactivation and the rate constant for the luminescence reaction. It was shown that refolding of thermoinactivated luciferases is completely determined by the DnaK–DnaJ–GrpE system. However these luciferases markedly differ in the rate and degree of refolding. The degree of refolding of thermolabile quick Ph. fischeri luciferase reaches 80% of the initial level over several minutes, whereas renaturation of thermostable slow Ph. luminescens luciferase proceeds substantially slower (the degree of renaturation reaches only 7-8% of the initial level over tens of minutes). The measurement of the rate of thermal inactivation of luciferases in vivo in the cells of Escherichia coli wild strain and strains containing mutations in genes clpA, clpB, clpX showed that Ph. luminescens luciferase revealed reduced thermostability in mutant strain E. coli clpA^–. It was shown that this effect was not connected with DnaK-dependent refolding. In the case of thermolabile Ph. fischeri luciferase, mutation in gene clpA has no effect on the shape of the curve of thermal inactivation. These data suggest that denatured Ph. luminescens luciferase has enhanced affinity with respect to chaperone ClpA in comparison with DnaK, whereas thermolabile Ph. fischeri luciferase is characterized by enhanced affinity with respect to chaperone DnaK. Denatured luciferase bound to ClpA does not aggregate and following refolding proceeds probably spontaneously and very quickly (over 1-2 min). It is evident that the process under discussion requires ATP, since the addition of uncoupler of oxidative phosphorylation carbonyl cyanide 3-chlorophenylhydra-zone results in a sharp decrease in thermal stability of luciferase to the level typical of the enzyme in vitro. The enhanced thermosensitivity of luciferases was observed also in E. coli containing mutations in gene clpB. However, this effect, which takes place for Ph. fischeri luciferase as well as for Ph. LuminescensM luciferase, is determined by DnaK-dependent refolding and probably connected with the ability of chaperone ClpB to provide disaggregation of the proteins, resulting in their interaction with chaperones of the Hsp70 family (DnaK–DnaJ–GrpE).     

Differences in nucleotide specificity and catalytic mechanism between Vibrio harveyi aldehyde dehydrogenase and other members of the aldehyde dehydrogenase superfamily

The fatty aldehyde dehydrogenase (Vh-ALDH) isolated from the luminescent bacterium, Vibrio harveyi, differs from other aldehyde dehydrogenases in its high affinity for NADP⁺. The binding of NADP⁺ appears to arise from the interaction of the 2′-phosphate of the adenosine moiety of NADP⁺ with a threonine (T175) in the nucleotide recognition site just after the β_B strand as well as with an arginine (R210) that pi stacks over the adenosine moiety. The active site of Vh-ALDH contains the usual suspects of a cysteine (C289), two glutamates (E253 and E377) and an asparagine (N147) involved in the aldehyde dehydrogenase mechanism. However, Vh-ALDH has one polar residue in the active site that distinguishes it from other ALDHs; a histidine (H450) is in close contact with the cysteine nucleophile. As a glutamate has been implicated in promoting the nucleophilicity of the active site cysteine residue in ALDHs, the close contact of a histidine with the cysteine nucleophile in Vh-ALDH raises the possibility of alternate routes to increase the reactivity of the cysteine nucleophile. The effects of mutation of these residues on the different functions catalyzed by Vh-ALDH including acylation, (thio)esterase, reductase and dehydrogenase activities should help define the specific roles of the residues in the active site of ALDHs.     

Relationship of the luminous bacterial symbiont of the Caribbean flashlight fish,Kryptophanaron alfredi (family Anomalopidae) to other luminous bacteria based on bacterial luciferase (luxA) genes

Flashlight fishes (family Anomalopidae) have light organs that contain luminous bacterial symbionts. Although the symbionts have not yet been successfully cultured, the luciferase genes have been cloned directly from the light organ of the Caribbean species, Kryptophanaron alfredi. The goal of this project was to evaluate the relationship of the symbiont to free-living luminous bacteria by comparison of genes coding for bacterial luciferase (lux genes). Hybridization of a luxAB probe from the Kryptophanaron alfredi symbiont to DNAs from 9 strains (8 species) of luminous bacteria showed that none of the strains tested had lux genes highly similar to the symbiont. The most similar were a group consisting of Vibrio harveyi, Vibrio splendidus and Vibrio orientalis. The nucleotide sequence of the luciferase subunit gene luxA of the Kryptophanaron alfredi symbiont was determined in order to do a more detailed comparison with published luxA sequences from Vibrio harveyi, Vibrio fischeri and Photobacterium leiognathi. The hybridization results, sequence comparisons and the mol% G+C of the Kryptophanaron alfredi symbiont luxA gene suggest that the symbiont may be considered as a new species of luminous Vibrio related to Vibrio harveyi.The nucleotide sequence reported in this article has been deposited in Genbank under accession number M36597     

Planktonic Luminous Bacteria of Vellar Estuary,South India

Distribution of planktonic luminous bacteria in relation to environmental parameters was investigated at two stations located in the Vellar Estuary. Luminous microflora showed a pronounced seasonal cycle with very low counts during monsoon months followed by an increase in post monsoon and peak counts during summer. The population density of these procaryotes was remarkably high ranging from 3.5 to 33.1 colony forming units per ml. They constituted 2.1 to 52.1 % of the total bacterial counts. Salinity appeared to govern the distribution of luminous procaryotes as their counts corresponded well with fluctuations in salinity. Taxonomic affiliation of the isolates revealed predominance of Vibrio harveyi. Vibrio fischeri and Photobacterium leiognathi exhibited sparse distribution.     

Analogs of the autoinducer of bioluminescence inVibrio fischer

The enzymes for luminescence inVibrio fischeri are induced only when a sufficient concentration of a metabolic product (autoinducer) specifically produced by this species accumulates. It has previously been shown that the autoinducer is 3-oxohexanoyl homoserine lactone and that it enters the cells by simple diffusion. To further study the mechanism of induction, we have synthesized several analogs of the autoinducer. The analogs were tested withV. fischeri for their inducing activity and for their ability to inhibit the action of the natural autoinducer. The compounds were found to display various combinations of inducing and inhibiting abilities. None of the compounds tested appeared to have any effect on cells ofV. harveyi strain MAV orPhotobacterium leiognathi strain 721, but several of the compounds decreased light output byP. phosphoreum strain 8265. These studies show that 1) the site of action of the autoinducer is not highly sterically constrained 2) the autoinducers of other species of luminous bacteria are likely to be quite different from that ofV. fischeri and 3) a simple mode in which one autoinducer molecule binds to a single receptor protein site and thus initiates luciferase synthesis is inadequate. The analogs should prove useful in the study of the binding site and mode of action of the autoinducer.Abbreviations SWC sea water complete     

Utilities of Luminous Bacteria from the Black Sea

Luminous bacteria, isolated from summer specimens of water of the Black Sea, have been identified as strains of Photobacterium phosphoreum and Vibrio fischeri (two of each). Morphological, physiological, and biochemical properties of the four strains have been characterized, and the kinetic behavior of luciferases isolated therefrom has been studied. The sensitivity of the luminescence of the strains to certain toxic agents has been compared to that of the test strain Ph. phosphoreum (Cohn) Ford. The results obtained indicate that the new strains show promise as bioindicators.     

Mobilization of cloned luciferase genes into Vibrio harveyi luminescence mutants

A recombinant plasmid which carried a 5 kb fragment of Vibrio harveyi DNA containing the luxA and luxB genes was mobilized from Escherichia coli into luminescence-deficient mutants of V. harveyi. The cloned genes complemented a temperature sensitive luciferase mutation, but failed to complement lesions in two different aldehyde deficient mutants. Expression of the cloned genes was not subject to autoinduction in either E. coli or in V. harveyi.