The Effect of Surface Charge Saturation on Heat‐induced Aggregation of Firefly Luciferase

We present here the effect of firefly luciferase surface charge saturation and the presence of some additives on its thermal‐induced aggregation. Three mutants of firefly luciferase prepared by introduction of surface Arg residues named as 2R, 3R and 5R have two, three and five additional arginine residues substituted at their surface compared to native luciferase; respectively. Turbidimetric study of heat‐induced aggregation indicates that all three mutants were reproducibly aggregated at higher rates relative to wild type in spite of their higher thermostability. Among them, 2R had most evaluated propensity to heat‐induced aggregation. Therefore, the hydrophilization followed by appearing of more substituted arginine residues with positive charge on the firefly luciferase surface was not reduced its thermal aggregation. Nevertheless, at the same condition in the presence of charged amino acids, e.g. Arg, Lys and Glu, as well as a hydrophobic amino acid, e.g. Val, the heat‐induced aggregation of wild type and mutants of firefly luciferases was markedly decelerated than those in the absence of additives. On the basis of obtained results it seems, relinquishment of variety in charge of amino acid side chains, they via local interactions with proteins cause to decrease rate and extent of their thermal aggregation.     

Site-specific incorporation of glycosylated serine and tyrosine derivatives into proteins

Glycosylation of proteins can have a dramatic effect on their physical, chemical, and biological properties. Analogues of dihydrofolate reductase and firefly luciferase containing glycosylated amino acids at single, predetermined sites have been elaborated. Misacylated suppressor tRNAs activated with glycosylated serine and tyrosine derivatives were used for suppression of the nonsense codons in a cell-free protein biosynthesizing system, thereby permitting the preparation of the desired glycosylated proteins. In this fashion, it was possible to obtain proteins containing both mono- and diglycosylated amino acids, including glycosylated serine and tyrosine moieties. For the modified firefly luciferases, the effect of these substitutions on the wavelength of the light emitted by firefly luciferase was investigated. The maximum wavelength for mutants containing peracetylated glycosylated serine derivatives at position 284 showed a red shift in the emission spectra. For mutants containing glycosylated tyrosines, the red shift was observed only when the carbohydrate moiety was fully deacetylated.     

Enhancement of thermostability of the Luciola mingrelica firefly luciferase by site-directed mutagenesis of nonconservative cysteine residues Cys62 and Cys146

Mutant forms of the firefly (Luciola mingrela) luciferase with point mutations Cys62Ser and Cys146Ser were obtained by site-directed mutagenesis. The mutations did not affect the catalytic activity and fluorescence spectra of the enzyme. The rate constants of the fast (k ₁) and slow (k ₂) stages of thermoinactivation of the wild-type and mutant enzymes were determined at 37°C in the absence and presence of 12 mM dithiothreitol (DTT). The thermostability of the mutant forms of luciferase increased several times compared to the wild-type enzyme. In the presence of DTT, k ₂ of the wild-type enzyme decreased three times whereas neither k ₁ nor k ₂ of the mutant forms changed. It was concluded that amino acid residues Cys62 and Cys146 play a major role in luciferase inactivation and that their substitution with Ser stabilizes the enzyme.     

Stabilization of <Emphasis Type="Italic">Luciola mingrelica</Emphasis> firefly luciferase by genetic engineering methods

The results of Luciola mingrelica firefly luciferase stabilization by genetic engineering methods are reviewed. The Cys62, Cys146, and Cys164 to Ser mutant enzymes with an enhanced thermostability and lower sensitivity to dithiothreitol were obtained by site-directed mutagenesis. The double mutant G216N, A217L was obtained, which displayed a higher thermostability and resistance to DMSO in comparison with WT luciferase. Random mutagenesis of the gene region encoding residues 1–225 and subsequent screening of the mutants resulted in the production of the mutant MT8 with a higher thermostability, as well as mutants MT3 and MT4 with higher resistance to dimethyl sulfoxide. The mutant 4TS was obtained by the method of directed evolution of the gene site encoding residues 130–390, which was shown to contain eight replacements after four cycles of mutagenesis and had two-fold higher specific activity, eight-fold lower K _m value for ATP, and stability at 42°C, which was 65-fold higher that of WT luciferase. The stabilization mechanism of this mutant is discussed.     

Recombinant firefly luciferase in Escherichia coli

The authentic recombinant luciferase, the luciferase with the structure similar to that of the native protein, was obtained using random mutagenesis, and its properties were studied in comparison with several fusion proteins. Thermoinactivation curves of the recombinant luciferases within the 10–50°C temperature interval showed that thermoinactivation involves reversible and irreversible steps. Immobilization of the recombinant Luciola mingrelica and Photinus pyralis firefly luciferases on BrCN-activated sepharose was carried out. Immobilization resulted in the preparation of enzymes with high catalytic activity. Physicochemical properties and analytical characteristics of the immobilized recombinant and native luciferases were studied. The catalytic properties of the immobilized recombinant L. mingrelica luciferase were close to those of the native luciferase but the former enzyme appeared to be significantly more stable. The immobilized recombinant luciferases can be used for ATP assay within 0.01–10000 nM range.     

Directed Improvement of Luciferin Regenerating Enzyme Binding Properties: Implication of Some Conserved Residues in Luciferin‐Binding Domain

Luciferin regenerating enzyme (LRE) contributes to in vitro recycling of d ‐luciferin to produce persistent and longer light emission by luciferase. Luciferin binding domains I and II among LREs regarded as potential candidates for luciferin‐binding sites. In this study, for the first time, amino acids T69, G75 and K77 located at luciferin binding domain I of LRE from L. turkestanicus (T‐LRE) substituted by using site‐directed mutagenesis. Single mutant T⁶⁹R increased luciferase light output more than two‐fold over a longer time in comparison with a wild‐type and other mutants of T‐LRE. Nevertheless, double mutant (K⁷⁷E/T⁶⁹R) increased the amount of bioluminescent signal more than two‐fold over a short time. In addition, G⁷⁵E, K⁷⁷E and G⁷⁵E/T⁶⁹R mutants did not improve luciferin–luciferase in vitro bioluminescence. Based on our results, addition of K⁷⁷E/G⁷⁵E and K⁷⁷E/G⁷⁵E/T⁶⁹R mutants caused intermediate changes in bioluminescence from in vitro luciferin–luciferase reaction. These findings indicated that the amino acids in question are possible to be located within T‐LRE active site. It may also be suggested that substituted Arg69 (Arg218) plays an important role in luciferin binding and the existence of Gly75 as well as Lys77 is essential for T‐LRE which has already evolved to have different functions in nature.     

The influence of Ala243 (Gly247), Arg215 and Thr226 (Asn230) on the bioluminescence spectra and pH-sensitivity of railroad worm,click beetle and firefly luciferases

Among beetle luciferases, the pH-sensitive firefly luciferases have been studied extensively. Much less is known about pH-insensitive luciferases, which include click beetle and railroad worm luciferases. Previously, we found that the residues R215 and T226 (N230) are important for green light emission. Here we show that the conserved residue A243 in pH-insensitive luciferases and the corresponding G247 in pH-sensitive luciferases affect the emission spectrum and influence pH-sensitivity. In contrast to railroad worm green light-emitting (PxvGR) and firefly luciferases, the substitution of R215 in Pyrearinus termitilluminans click beetle luciferase (Pte) had no effect on the spectrum, showing that R215 is not essential for green light emission in all beetle luciferases. A homology-based model of Pte luciferase shows that R215 and T226 are close enough to interact. To investigate if there was an interaction between these conserved residues, double mutants were constructed. The double substitution R215S/T226N in Pte luciferase abolished the activity. In PxvGR luciferase the same double mutant resulted in a redshift (lambda(max) = 595 nm), whose magnitude was lower than the value expected for an additive effect. These results suggest that the effects of R215S and T226N are partially interdependent. The double substitution T226N/A243G had an additive redshift effect on the spectrum of PxvGR luciferase, whereas it had a smaller effect on the spectrum of Pte luciferase. Altogether, these results suggest that the above substitutions have different effects on the active site of click beetle and railroad worm luciferases.     

CLONING, EXPRESSION and SEQUENCE ANALYSIS OF cDNA FOR THE LUCIFERASES FROM THE JAPANESE FIREFLIES, Pyrocoelia tniyako AND Hotaria parvula

Abstract— Cloning and sequence analysis of cDNA for the luciferases of Pyrocoelia miyako and Hotaria parvula were carried out (GenBank accession numbers L39928 and L39929, respectively). The amino acid sequence, deduced from the nucleotide sequence, showed P. miyako luciferase to consist of 548 amino acid residues with a molecular weight of 60955, while the luciferase of H. parvula consisted of 548 amino acid residues with a molecular weight of 60 364. Pyrocoelia miyako luciferase showed 82.1 % homology with the luciferase of Photinus pyralis and less than 70% homology with other firefly luciferases, whereas H. parvula luciferase showed 98%, 82.5% and 81.2% homology with the luciferases of Luciola mingrelica, Luciola lateralis and Luciola cruciata, respectively. Two regions in the enzymes were found to be highly conserved. The amino acid sequences were used to construct a phylogenetic tree, which showed that the fireflies could be divided into two groups.     

PIGMENT COMPLEXES OF LIGHT-HARVESTING CHLOROPHYLL a/b BINDING PROTEIN ARE STABILIZED BY A SEGMENT IN THE CARBOXYTERMINAL HYDROPHILIC DOMAIN OF THE PROTEIN*

In order to identify segments of light-harvesting chlorophyll a/6-binding protein (LHCP) that are important for pigment binding, we have tested various LHCP mutants regarding their ability to form stable pigment-protein complexes in an in vitro reconstitution assay. Deletion of 10 C-terminal amino acids in the LHCP precursor, pLHCP, did not significantly affect pigment binding, whereas deletion of one additional amino acid, a tryptophan, completely abolished the formation of stable pigment-protein complexes. This tryptophan, however, can be exchanged with other amino acids in full-length pLHCP without noticeably altering the stability or spectroscopic properties of pigment complexes made with these mutants. Thus, the tryptophan residue is not likely to be involved in a highly specific interaction stabilizing the complex. A double mutant of LHCP lacking 66 N-terminal and 6 C-terminal amino acids still forms pigmented complexes that are virtually identical to those formed with the full-length protein concerning their pigment composition and spectroscopic properties. We conclude that about 30% of the polypeptide chain in LHCP is not involved in pigment binding.     

Alteration of the formate dehydrogenase isoelectric point by rational design

In order to extend the pH stability optimum for NAD⁺-dependent formate dehydrogenase (FDH, EC 1.2.1.2) from the bacterium Pseudomonas sp. 101 (PseFDH), four mutant enzymes with Lys112Pro, Lys231Ala, Lys231Ser, and Lys317Asn substitutions were obtained by site-directed mutagenesis. The choice of the mutation sites and the types of substituting amino acids were based on the alignment of amino acid sequences of FDHs from various sources and the analysis of the three-dimensional structure of PseFDH. The kinetic properties and temperature stability were studied for all obtained mutant forms. It is shown that the substitutions in positions 112 and 231 slightly improved the kinetic properties; meanwhile, the Lys317Asn mutant possessed a decreased affinity for the coenzyme. A thermal stability assay for the obtained mutants revealed that the substitutions in positions 112 and 231 result in just a slight destabilization of the enzyme, while Lys317Asn substitution causes a significant decrease in thermal stability. The isoelectric point was decreased by 0.1 points for all obtained mutant forms.     

A new firefly luciferase with bimodal spectrum: identification of structural determinants of spectral pH-sensitivity in firefly luciferases

Fireflies emit flashes in the green-yellow region of the spectrum for the purpose of sexual attraction. The bioluminescence color is determined by the luciferases. It is well known that the in vitro bioluminescence color of firefly luciferases can be shifted toward the red by lower pH and higher temperature; for this reason they are classified as pH-sensitive luciferases. However, the mechanism and structural origin of pH sensitivity in fireflies remains unknown. Here we report the cloning of a new luciferase from the Brazilian twilight active firefly Macrolampis sp2, which displays an unusual bimodal spectrum. The recombinant luciferase displays a sensitive spectrum with the peak at 569 nm and a shoulder in the red region. Comparison of the bioluminescence spectra of Macrolampis, Photinus and Cratomorphus firefly luciferases shows that the distinct colors are determined by the ratio between green and red emitters under luciferase influence. Comparison of Macrolampis luciferase with the highly similar North American Photinus pyralis luciferase (91%) showed few substitutions potentially involved with the higher spectral sensitivity in Macrolampis luciferase. Site-directed mutagenesis showed that the natural substitution E354N determines the appearance of the shoulder in the red region of Macrolampis luciferase bioluminescence spectrum, helping to identify important interactions and residues involved in the pH-sensing mechanism in firefly luciferases.     

Firefly Luciferase Mutants Allow Substrate‐Selective Bioluminescence Imaging in the Mouse Brain

Bioluminescence imaging is a powerful approach for visualizing specific events occurring inside live mice. Animals can be made to glow in response to the expression of a gene, the activity of an enzyme, or the growth of a tumor. But bioluminescence requires the interaction of a luciferase enzyme with a small‐molecule luciferin, and its scope has been limited by the mere handful of natural combinations. Herein, we show that mutants of firefly luciferase can discriminate between natural and synthetic substrates in the brains of live mice. When using adeno‐associated viral (AAV) vectors to express luciferases in the brain, we found that mutant luciferases that are inactive or weakly active with d ‐luciferin can light up brightly when treated with the aminoluciferins CycLuc1 and CycLuc2 or their respective FAAH‐sensitive luciferin amides. Further development of selective luciferases promises to expand the power of bioluminescence and allow multiple events to be imaged in the same live animal.     

A fusion protein of <Emphasis Type="Italic">Luciola mingrelica</Emphasis> luciferase with a biotin-binding domain: Production,properties, and application

A plasmid encoding a fusion protein (4TS-bccp87) composed of a thermostable mutant of the Luciola mingrelica firefly luciferase (4TS) and 87 carboxy-terminal amino acid residues of the biotin-binding domain (bccp87) from E. coli was constructed using genetic-engineering techniques. It was established that fusion-protein expression in BL21(DE3) E. coli resulted in 60% of the biotinylated form. The catalytic properties, thermostability, and bioluminescence spectra of the fusion protein were shown to be similar to that of the initial luciferase. The possibility of using the streptavidin-biotinylated luciferase complex for defining the Salmonella typhimurium cell concentration in the range from 10⁴ to 5 × 10⁶ CFU/ml by enzyme immunoassay was shown.     

Quantum Yields and Kinetics of the Firefly Bioluminescence Reaction of Beetle Luciferases

Quantum yields of firefly bioluminescence reactions were determined for beetle luciferases from the three main families of luminous beetles emitting different bioluminescence colors. Quantum yield (QY) was significantly correlated with luminescence spectrum. The green light-emitting luciferase of the Brazilian click beetle, Pyrearinus termitilluminans, whose luminescence spectrum had the shortest peak wavelength of all the luciferases investigated, had the highest QY (0.61). Mutant analyses of active site-substituted Pyrocoelia miyako luciferases showed that, although k_cat was decreased by the mutations, the QY was not significantly affected.     

Synthesis of Firefly Luciferin Analogues and Evaluation of the Luminescent Properties

Five new firefly luciferin ( 1 ) analogues were synthesized and their light emission properties were examined. Modifications of the thiazoline moiety in 1 were employed to produce analogues containing acyclic amino acid side chains ( 2 – 4 ) and heterocyclic rings derived from amino acids ( 5 and 6 ) linked to the benzothiazole moiety. Although methyl esters of all of the synthetic derivatives exhibited chemiluminescence activity, only carboluciferin ( 6 ), possessing a pyrroline‐substituted benzothiazole structure, had bioluminescence (BL) activity (λ_max=547 nm). Results of bioluminescence studies with AMP‐carboluciferin (AMP=adenosine monophosphate) and AMP‐firefly luciferin showed that the nature of the thiazoline mimicking moiety affected the adenylation step of the luciferin–luciferase reaction required for production of potent BL. In addition, BL of 6 in living mice differed from that of 1 in that its luminescence decay rate was slower.     

紫外吸收光谱法研究Asp44在稳定肌红蛋白结构中的作用

为了了解肌红蛋白Mb表面44位天冬氨酸(Asp)残基对稳定蛋白结构的影响,用聚合酶链式反应(PCR)定点突变的技术将Mb基因上的第44位天冬氨酸的密码子GAT突变成赖氨酸的密码子AAA,获得突变体D44K。突变体蛋白在大肠杆菌BL21-DE3中成功表达并且得到纯化。用紫外-可见光谱研究野生型肌红蛋白及其突变体D44K的耐热、耐酸的变性过程。结果表明,用碱性氨基酸赖氨酸(Lys)取代酸性氨基酸Asp44残基,增强了肌红蛋白耐热、耐酸能力,说明Asp44具有稳定肌红蛋白结构的作用。为进一步研究蛋白表面氨基酸对蛋白质结构、功能的影响提供重要的试验依据。