Bioluminescence Spectra of Native and Mutant Firefly Luciferases as a Function of pH

Bioluminescence spectra of the wild-type recombinant Luciola mingrelica firefly luciferase and its mutant form with the His433Tyr point mutation were obtained within the pH 5.6-10.2 interval. The spectra are shown to be a superposition of the spectra of the three forms of the electronically excited reaction product oxyluciferin: ketone (lambdamax = 618 nm), enol (lambdamax = 587 nm), and enolate-ion (lambdamax = 556 nm). The shift in lambdamax by 40 nm to the red region in the mutant luciferase bioluminescence at the pH optimum of enzyme activity (pH 7.8) is explained by the change in the relative content of different oxyluciferin forms due to the shift in the ketone <--> enol <--> enolate equilibria. A computer model of the luciferase-oxyluciferin-AMP complex was constructed and the structure of amino acid residues participating in the equilibrium is proposed. Computer models of the protein region near the His433 residue for the wild type and mutant luciferases are also proposed. Comparison of the models shows that the His433Tyr mutation increases flexibility of the polypeptide loop that binds the N and C domains of luciferase. As a result, the flexibility of the C domain amino acid residues in the emitter microenvironment increases, and this increase may be the reason for the observed differences in the bioluminescence spectra of the native and mutant luciferases.     

Random mutagenesis of Luciola mingrelica firefly luciferase. Mutant enzymes with bioluminescence spectra showing low pH sensitivity

Most firefly luciferases demonstrate a strong pH-dependence of bioluminescence spectra. Gene region encoding first 225 residues of Luciola mingrelica luciferase was subjected to random mutagenesis, and four mutants with altered pH-sensitivity of bioluminescence spectra were isolated. F16L substitution showed distinctly lower pH-dependence of bioluminescence spectra, and Y35N,H and F16L/A40S substitutions resulted in the enzymes with bioluminescence spectra virtually independent from pH in the range of 6.0-7.8. The structural explanation is proposed for the effect of mutations on pH-sensitivity of bioluminescence spectra.     

ΔFlucs: Brighter Photinus pyralis firefly luciferases identified by surveying consecutive single amino acid deletion mutations in a thermostable variant

The bright bioluminescence catalyzed by Photinus pyralis firefly luciferase (Fluc) enables a vast array of life science research such as bio imaging in live animals and sensitive in vitro diagnostics. The effectiveness of such applications is improved using engineered enzymes that to date have been constructed using amino acid substitutions. We describe ΔFlucs: consecutive single amino acid deletion mutants within six loop structures of the bright and thermostable ×11 Fluc. Deletion mutations are a promising avenue to explore new sequence and functional space and isolate novel mutant phenotypes. However, this method is often overlooked and to date there have been no surveys of the effects of consecutive single amino acid deletions in Fluc. We constructed a large semi‐rational ΔFluc library and isolated significantly brighter enzymes after finding ×11 Fluc activity was largely tolerant to deletions. Targeting an “omega‐loop” motif (T352‐G360) significantly enhanced activity, altered kinetics, reduced Km for D‐luciferin_, altered emission colors, and altered substrate specificity for redshifted analog DL‐infraluciferin. Experimental and in silico analyses suggested remodeling of the Ω‐loop impacts on active site hydrophobicity to increase light yields. This work demonstrates the further potential of deletion mutations, which can generate useful Fluc mutants and broaden the palette of the biomedical and biotechnological bioluminescence enzyme toolbox.     

Improved practical usefulness of firefly luciferase by gene chimerization and random mutagenesis

To improve the practical usefulness of the firefly luciferase, we performed gene chimerization between Photinus pyralis luciferase and a thermostable variant of Luciola cruciata luciferase. One chimeric luciferase showed low K(m) value for substrate ATP and similar stability to thermostable L. cruciata luciferase. We then introduced random mutations in the corresponding gene and screened for increased catalytic efficiency. Amino acid replacement of Thr219, Val239 and Val290 affected the kinetic parameters. Therefore, we combined these three mutations. One mutant, ABcT219I,V239I, showed high catalytic efficiency comparable to P. pyralis luciferase and high stability similar to thermostable L. cruciata luciferase. The pH-dependence of the bioluminescence emission spectra was also examined. In contrast to wild-type firefly luciferases characterized to date, the mutant did not show the pH-dependent red spectrum shift.     

Mutational analysis of the Vibrio fischeri LuxI polypeptide: critical regions of an autoinducer synthase.

Synthesis of the Vibrio fischeri autoinducer, a signal involved in the cell density-dependent activation of bioluminescence, is directed by the luxI gene product. The LuxI protein catalyzes the synthesis of N-acyl-homoserine lactones from S-adenosylmethionine and acylated-acyl carrier protein. We have gained an appreciation of the LuxI regions and amino acid residues involved in autoinducer synthesis by isolating and analyzing mutations generated by random and site-specific mutagenesis of luxI. By random mutagenesis we isolated 13 different single amino acid substitutions in the LuxI polypeptide. Eleven of these substitutions resulted in no detectable autoinducer synthase activity, while the remaining two amino acid substitutions resulted in reduced but detectable activity. The substitutions that resulted in no detectable autoinducer synthase activity mapped to two small regions of LuxI. In Escherichia coli, wild-type luxI showed dominance over all of the mutations. Because autoinducer synthesis has been proposed to involve formation of a covalent bond between an acyl group and an active-site cysteine, we constructed site-directed mutations that altered each of the three cysteine residues in LuxI. All of the cysteine mutants retained substantial activity as an autoinducer synthase in E. coli. Based on the analysis of random mutations we propose a model in which there are two critical regions of LuxI, at least one of which is an intimate part of an active site, and based on the analysis of site-directed mutations we conclude that an active-site cysteine is not essential for autoinducer synthase activity.     

Bioluminescence and chemiluminescence literature: 1987 literature,part III

In studying beetle bioluminescence in the early 1960s, Dr McElroy and his colleagues found that the Jamaican click beetle, Pyrophorus plagiophthalamus, was capable of emitting different colours of light. They further found that the luciferin substrate used by this beetle was the same as that in the firefly, demonstrating that the different colours of bioluminescence were due to differences in the structure of the luciferases. We have recently cloned cDNAs from this beetle species which code for at least four different luciferases. The luciferases are distinguishable by their different colours of bioluminescence when expressed in Escherichia coli. The sequence differences between these different luciferases are few, so the amino acids responsible for the different colours of emission must also be few. Through the construction of hybrid luciferases, by rearranging fragments of the original cDNA clones, we have identified some of these amino acid determinants of colour.     

Separation of enzymatic functions and variation of spin state of rice allene oxide synthase-1 by mutation of Phe-92 and Pro-430

Rice allene oxide synthase-1 mutants carrying F92L, P430A or F92L/P430A amino acid substitution mutations were constructed, recombinant mutant and wild type proteins were purified and their substrate preference, UV–vis spectra and heme iron spin state were characterized. The results show that the hydroperoxide lyase activities of F92L and F92L/P430A mutants prefer 13-hydroperoxy substrate to other hydroperoxydienoic acids or hydroperoxytrienoic acids. The Soret maximum was completely red-shifted in P430A and F92L/P430A mutants, but it was partially shifted in the F92L mutant. ESR spectral data showed that wild type, F92L and P430A mutants occupied high and low spin states, while the F92L/P430A mutant occupied only low spin state. The extent of the red shift of the Soret maximum increased as the population of low spin heme iron increased, suggesting that the spectral shift reflects the high to low transition of heme iron spin state in rice allene oxide synthase-1. Relative to wild type allene oxide synthase-1, the hydroperoxide lyase activities of F92L and F92L/P430A are less sensitive to inhibition by imidazole with (13S or 9S)-hydroperoxydienoic acid as substrate and more sensitive than wild type with (13S)-hydroperoxytrienoic acid as substrate. Our results suggest that hydroperoxydienoic acid is the preferred substrate for the hydroperoxide lyase activity and (13S)-hydroperoxytrienoic acid is the preferred substrate for allene oxide synthase activity of allene oxide synthase-1.     

Solution structure and dynamics of LuxU from Vibrio harveyi, a phosphotransferase protein involved in bacterial quorum sensing

The marine bacterium Vibrio harveyi controls its bioluminescence by a process known as quorum sensing. In this process, autoinducer molecules are detected by membrane-bound sensor kinase/response regulator proteins (LuxN and LuxQ) that relay a signal via a series of protein phosphorylation reactions to another response regulator protein, LuxO. Phosphorylated LuxO indirectly represses the expression of the proteins responsible for bioluminescence. Integral to this quorum sensing process is the function of the phosphotransferase protein, LuxU. LuxU acts to shuttle the phosphate from the membrane-bound proteins, LuxN and LuxQ, to LuxO. LuxU is a 114 amino acid residue monomeric protein. Solution NMR was used to determine the three-dimensional structure of LuxU. LuxU contains a four-helix bundle topology with the active-site histidine residue (His58) located on alpha-helix C and exposed to solution. The active site represents a cluster of positively charged residues located on an otherwise hydrophobic protein face. NMR spin-relaxation experiments identify a collection of flexible residues localized on the same region of LuxU as His58. The studies described here represent the first structural characterization of an isolated, monomeric bacterial phosphotransferase protein.     

Confirmation of color determination factors for Ser286 derivatives of firefly luciferase from Luciola cruciata (LUC-G)

The bioluminescence color of firefly luciferase including its mutants ranges from green to red (530–640 nm) and is affected by the species of firefly, the reaction conditions, and by the substitution of amino acids. Although there is a general agreement that the microenvironment mechanism is the dominant model for the color determination of firefly luciferase, a complete mechanism has not been shown, partially due to the lack of comprehensive data on which amino acid positions alter the bioluminescent color. In this paper, a mutant library of position serine 286 (S286) in Luciola cruciata luciferase (LUC-G) was constructed and characterized. The substitution of S286 resulted in a drastic red shift in bioluminescence color (>600 nm), and only glycine (G) and alanine (A) mutants remained yellow-green. To explain this color difference, molecular dynamics (MD) calculations of 3 S286 derivatives (S286G, S286N, and S286I), in addition to wild type (WT), were performed. The active site rigidity and active site hydrogen bonding networks were compared to WT for each derivative. The results suggested that both factors affected the active site environment and affected the difference in bioluminescence colors in LUC-G S286 derivatives.     

Pharmacological investigation of the bioluminescence signaling pathway of the dinoflagellate Lingulodinium polyedrum: evidence for the role of stretch‐activated ion channels

Dinoflagellate bioluminescence serves as a whole‐cell reporter of mechanical stress, which activates a signaling pathway that appears to involve the opening of voltage‐sensitive ion channels and release of calcium from intracellular stores. However, little else is known about the initial signaling events that facilitate the transduction of mechanical stimuli. In the present study using the red tide dinoflagellate Lingulodinium polyedrum (Stein) Dodge, two forms of dinoflagellate bioluminescence, mechanically stimulated and spontaneous flashes, were used as reporter systems to pharmacological treatments that targeted various predicted signaling events at the plasma membrane level of the signaling pathway. Pretreatment with 200 μM Gadolinium III (Gd³⁺), a nonspecific blocker of stretch‐activated and some voltage‐gated ion channels, resulted in strong inhibition of both forms of bioluminescence. Pretreatment with 50 μM nifedipine, an inhibitor of L‐type voltage‐gated Ca²⁺ channels that inhibits mechanically stimulated bioluminescence, did not inhibit spontaneous bioluminescence. Treatment with 1 mM benzyl alcohol, a membrane fluidizer, was very effective in stimulating bioluminescence. Benzyl alcohol‐stimulated bioluminescence was inhibited by Gd³⁺ but not by nifedipine, suggesting that its role is through stretch activation via a change in plasma membrane fluidity. These results are consistent with the presence of stretch‐activated and voltage‐gated ion channels in the bioluminescence mechanotransduction signaling pathway, with spontaneous flashing associated with a stretch‐activated component at the plasma membrane.     

Prospects for resonance assignments in multidimensional solid-state NMR spectra of uniformly labeled proteins

Summary The feasibility of assigning the backbone ¹⁵N and ¹³C NMR chemical shifts in multidimensional magic angle spinning NMR spectra of uniformly isotopically labeled proteins and peptides in unoriented solid samples is assessed by means of numerical simulations. The goal of these simulations is to examine how the upper limit on the size of a peptide for which unique assignments can be made depends on the spectral resolution, i.e., the NMR line widths. Sets of simulated three-dimensional chemical shift correlation spectra for artificial peptides of varying length are constructed from published liquid-state NMR chemical shift data for ubiquitin, a well-characterized soluble protein. Resonance assignments consistent with these spectra to within the assumed spectral resolution are found by a numerical search algorithm. The dependence of the number of consistent assignments on the assumed spectral resolution and on the length of the peptide is reported. If only three-dimensional chemical shift correlation data for backbone ¹⁵N and ¹³C nuclei are used, and no residue-specific chemical shift information, information from amino acid side-chain signals, and proton chemical shift information are available, a spectral resolution of 1 ppm or less is generally required for a unique assignment of backbone chemical shifts for a peptide of 30 amino acid residues.     

Bovine serum albumin displays luciferase-like activity in presence of luciferyl adenylate: insights on the origin of protoluciferase activity and bioluminescence colours.

Luciferyl adenylate, the key intermediate in beetle bioluminescence, is produced through adenylation of d-luciferin by beetle luciferases and also by mealworm luciferase-like enzymes which produce a weak red chemiluminescence. However, luciferyl adenylate is only weakly chemiluminescent in water at physiological pH and it is unclear how efficient bioluminescence evolved from its weak chemiluminescent properties. We found that bovine serum albumin (BSA) and neutral detergents enhance luciferyl adenylate chemiluminescence by three orders of magnitude, simulating the mealworm luciferase-like enzyme chemiluminescence properties. These results suggest that the beetle protoluciferase activity arose as an enhanced luciferyl adenylate chemiluminescence in the protein environment of the ancestral AMP-ligase. The predominance of luciferyl adenylate chemiluminescence in the red region under most conditions suggests that red luminescence is a more primitive condition that characterized the original stages of protobioluminescence, whereas yellow-green bioluminescence may have evolved later through the development of a more structured and hydrophobic active site.     

Structure-function studies on the active site of the coelenterazine-dependent luciferase from Renilla

Renilla luciferase (RLUC) is a versatile tool for gene expression assays and in vivo biosensor applications, but its catalytic mechanism remains to be elucidated. RLUC is evolutionarily related to the alpha/beta hydrolase family. Its closest known homologs are bacterial dehalogenases, raising the question of how a protein with a hydrolase fold can function as a decarboxylating oxygenase. Molecular docking simulations with the coelenterazine substrate against an RLUC homology model as well as a recently determined RLUC crystal structure were used to build hypotheses to identify functionally important residues, which were subsequently tested by site-directed mutagenesis, heterologous expression, and bioluminescence emission spectroscopy. The data highlighted two triads of residues that are critical for catalysis. The putative catalytic triad residues D120, E144, and H285 bear only limited resemblance to those found in the active site of aequorin, a coelenterazine-utilizing photoprotein, suggesting that the reaction scheme employed by RLUC differs substantially from the one established for aequorin. The role of H285 in catalysis was further supported by inhibition using diethylpyrocarbonate. Multiple substitutions of N53, W121, and P220--three other residues implicated in product binding in the homologous dehalogenase Sphingomonas LinB--also supported their involvement in catalysis. Together with luminescence spectra, our data lead us to propose that the conserved catalytic triad of RLUC is directly involved in the decarboxylation reaction of coelenterazine to produce bioluminescence, while the other active-site residues are used for binding of the substrate.     

Probing the roles of conserved arginine-44 of Escherichia coli dihydrofolate reductase in its function and stability by systematic sequence perturbation analysis

Sequence perturbation analysis is a powerful method to reveal roles of an amino acid residue in function and stability of a protein. By using and improving this method, we studied roles of highly conserved Arg44 of Escherichia coli dihydrofolate reductase (DHFR) in its function and stability. Here, we introduced systematic amino acid substitutions at this position and found that all 19 kinds of amino acid substitutions were tolerated, but the mutations significantly reduced the enzymatic activity and the binding affinity toward the cofactor NADPH. Moreover, the mutational effects on the cofactor binding affinity were well correlated with those on the catalytic activity, indicating that the R44X mutations affect the catalytic activity mainly by modulating the cofactor binding affinity. On the other hand, thermal denaturation measurements showed that most mutations stabilized the protein. Comparison between the mutational effects and various amino acid indices taken from the AAindex database indicated that hydrophobicity and polarity are key determinants of amino acids favorable at this position. These results suggest that through electrostatic interactions Arg44 plays a functional role in retaining the cofactor binding affinity at the cost of the protein stability.     

Novel BRCA1 gene mutations in breast cancer patients from St. Petersburg

Screening of patients with familial breast cancer from St. Petersburg for BRCA1 gene mutations resulted in identification of three mutations (414del3, 276delA, and A622V) and two polymorphisms (P871L and S1436S). Mutations 4146del3 and 276delA are novel, never previously described elsewhere. Deletion 2761delA produces a reading frame shift, premature protein synthesis termination and can cause predisposition for breast cancer. Deletion 414de13 does not cause a frame shift, but can result both in the disappearance of amino acid residue (D1343del) in the BRCA1 protein and in alteration of folding of the protein, entailing loss of its functional activity. Two variants of nucleotide sequence observed in the number of patients were classified as DNA polymorphisms (P871L and S1436S) rather than mutations as they were not tightly associated with the increased risk of breast cancer.     

Bioluminescent monitoring of turbulent bioconvection.

Under adjusted experimental conditions, open-to-air cultures of lux gene-engineered Ralstonia eutropha (wholecell biosensors of copper) exhibit bioconvection, which accounts for fluctuating bioluminescence. The power spectrum of bioluminescence intensity fluctuations recorded from a cylindrical sample 9 mm in diameter and approximately 10 mm in height is characterized by a dominant low-frequency oscillation (with a characteristic period of approximately 8-12 min), which is occasionally accompanied by a few weaker oscillations. The corresponding spectral peaks emerge on a high-noise background. The spectra of bioluminescence intensity fluctuations qualitatively resemble the spectra of temperature or fluid velocity fluctuations in an appropriate turbulent thermal convection system. It has been suggested that in a bioconvective system, like in thermal convection systems, the emergence of oscillation reflects the large-scale convective circulation that spans the height of the cylindrical cell. The velocity of large-scale bioconvective circulation was estimated to be 37-48 microm/s. The occasional emergence of weaker-than-dominant oscillations was explained through the coexistence and interaction of the large-scale circulation with, presumably, a gene-expression-related cyclic process (with a characteristic period of approximately 25-50 min).     

A case of primary selective hypoaldosteronism carrying three mutations in the aldosterone synthase (Cyp11b2) gene

An infant with a clinical phenotype of early onset hypoaldosteronism has been screened for mutation analysis of the Cyp11b2 gene encoding aldosterone synthase enzyme. We have described a novel nonsense mutation in exon 3 (c.508C>T) that gave rise to a shorter protein (Q170X) and two known concurrent missense mutations (c.594A>C in exon 3 and c.1157T>C in exon 7) that led to substitution of glutamic acid for aspartic acid at amino acid position 198 (E198D) and of valine for alanine at amino acid position 386 (V386A). The father, who carried E198D plus V386A mutations, showed a fractional sodium excretion of 1.25% that was unmodified by dietary salt restriction, suggesting a mild haploinsufficiency. We examined by in silico analysis the effect of the mutations on the secondary and tertiary structures of aldosterone synthase to explain the inefficient enzymatic activity. The Q170X mutation produced a truncated protein, which was consequently associated with a loss of catalytic activity. As predicted by JPred web system and Dock 6.3 software, the concurrent expression of E198D and V386A mutations induced a significant secondary structure rearrangement and a shift of the heme group and the 18-hydroxycorticosterone substrate from their optimal placement.     

Engineering the C-terminus of firefly luciferase as an indicator of covalent modification of proteins

Protein kinase recognition sequences and proteinase sites were engineered into the cDNA encoding firefly luciferase from Photinus pyralis in order to establish whether these modified proteins could be developed as bioluminescent indicators of covalent modification of proteins. Two key domains of the luciferase were modified in order to identify regions of the protein in which peptide sequences may be engineered whilst retaining bioluminescent activity; one between amino acids 209 and 227 and the other at the C-terminus, between amino acids 537 and 550. Mutation of amino acids between residues 209 and 227 reduced bioluminescent activity to less than 1% of wild-type recombinant. In contrast engineering peptide sequences at the C-terminus resulted in specific activities ranging from 0.06–120% of the wild-type recombinant. Addition of cyclic AMP dependent protein kinase catalytic subunit, to a variant luciferase incorporating the kinase recognition sequence, LRRASLG, with a serine at amino-acid position 543 resulted in a 30% reduction in activity. Alkaline phosphatase treatment restored activity. The bioluminescent activity of a variant luciferase containing a thrombin recognition sequence, LVPRES, with the cleavage site positioned between amino acid 542 and 543, decreased by 50% when incubated in the presence of thrombin. The results indicate regions within luciferase where peptide sequences may be engineered while retaining bioluminescent activity and have shown changes in bioluminescent activity when these sites are subjected to covalent modification. Changes in secondary structure, charge and length at the C-terminus of luciferase disrupt the microenvironment of the active site, leading to alterations in light emission. This has important implications both in understanding the evolution of beetle bioluminescence and also in the development of bioluminescent indicators of the covalent modification of proteins.     

Role of Conservative Residue Cys158 in the Formation of an Active Photoprotein Complex of Obelin

Using site directed mutagenesis, the conservative residue Cys158 of recombinant apoobelin was substituted for serine (C158S, S-mutant) or alanine (C158A, A-mutant). These point mutations resulted in significant changes in the apoobelin structure accompanied by slowing of photoprotein complex formation, decrease of its stability, and changing of its bioluminescence characteristics. The enzymatic properties of the photoprotein decreased in the series: wild-type protein > S-mutant > A-mutant. This is consistent with rank of nucleophilicity SH > OH > CH₃ of cysteine, serine, and alanine side chain functional groups, respectively. Possible mechanisms of the involvement of the apoobelin Cys158 SH-group in the formation of the enzyme–substrate complex are considered.     

PHOTOINHIBITION OF MECHANICALLY STIMULABLE BIOLUMINESCENCE IN THE AUTOTROPHIC DINOFLAGELLATE CERATIUM FUSUS (PYRROPHYTA)1

Ceratium fusus (Ehrenb.) Dujardin was exposed to light of different wavelengths and photon flux densities (PFDs) to examine their effects on mechanically stimulable bioluminescence (MSL). Photoinhibition of MSL was proportional to the logarithm of PFD. Exposure to I μmol photons·m^?2s^?1 of broadband blue light (ca. 400–500 nm) produced near-complete photoinhibition (≥90% reduction in MSL) with a threshold at ca. 0.01 μmol photons·m^?2·s^?1. The threshold of photoinhibition was ca. an order of magnitude greater for both broadband green (ca. 500–580 nm) and red light (ca. 660–700 nm). Exposure to narrow spectral bands (ca. 10 nm half bandwidth) from 400 and 700 nm at a PFD of 0.1 μmol photons·m^?2·s^?1 produced a maximal response of photoinhibition in the blue wavelengths (peak ca. 490 nm). A photoinhibition response (≥ 10%) in the green (ca. 500–540 nm) and red wavelengths (ca. 680 nm) occurred only at higher PFDs (1 and 10 μmol photons·m^?2·s^?1). The spectral response is similar to that reported for Gonyaulax polyedra Stein and Pyrocystis lunula Schütt and unlike that of Alexandrium tamarense (Lebour) Balech et Tangen. The dinoflagellate's own bioluminescence is two orders of magnitude too low to result in self-photoinhibition. The quantitative relationships developed in the laboratory predict photoinhibition of bioluminescence in populations of C. fusus in the North Atlantic Ocean.