Development of Luciferin Analogues Bearing an Amino Group and Their Application as BRET Donors

We systematically synthesized bioluminogenic substrates bearing an amino group on benzothiazole, quinoline, naphthalene, and coumarin scaffolds. They emit bioluminescence in various colors: red, orange, yellow, and green. An amino‐substituted coumarylluciferin derivative, coumarylaminoluciferin (CAL), showed the shortest bioluminescence wavelength among substrates reported so far. Further, the fluorescence of CAL did not exhibit solvatochromism, which suggests that its bioluminescence is not susceptible to environmental factors. We applied CAL as an energy‐donor substrate for a bioluminescence resonance energy transfer (BRET) system with click beetle red luciferase (CBRluc), a mutant of firefly luciferase, as the energy‐donor enzyme and yellow fluorescent protein (YFP) as the energy‐acceptor fluorophore, and obtained a clearly bimodal bioluminescence spectrum. Stable bioluminescence that is not influenced by environmental factors is highly desirable for reliable measurements in biological assays.     

A Novel Streptavidin–luciferase Fusion Protein: Preparation,Properties and Application in Hybridization Analysis of DNA

A streptavidin–luciferase fusion protein comprising the thermostable mutant form of firefly luciferase Luciola mingrelica and minimal core streptavidin was constructed. The streptavidin–luciferase fusion was mainly produced in a tetrameric form with high luciferase and biotin‐binding activities. It was shown that fusion has the same K_m values for ATP and luciferin and the bioluminescence spectra as initial luciferase. The linear dependence of the bioluminescence signal on the content of the fusion was observed within the range of 10^?18–10^?13 mol per well. Successful application of obtained fusion in a biospecific bioluminescence assay based on biotin–streptavidin interactions was demonstrated by the example of a specific DNA hybridization analysis. A DNA hybridization analysis for Escherichia coli cells identification was developed using unique for these cells gadB fragment encoding glutamate decarboxylase. The amplified biotinylated GadB fragments were hybridized with the immobilized oligonucleotide probes; then, the biotin in the DNA duplexes was detected using the streptavidin–luciferase fusion protein. To reach the high sensitivity of the assay, we optimized the conditions of the assay. It was shown that the use of Pluronic for plate modification resulted in a significant reduction in the DNA detection limit which finally was 0.4 ng per well.     

The Bioluminescence Resonance Energy Transfer from Firefly Luciferase to a Synthetic Dye and its Application for the Rapid Homogeneous Immunoassay of Progesterone

The sensitive BRET system for the homogeneous immunoassay of a low‐molecular weight antigen was developed using progesterone as an example. Two thermostable mutants of the Luciola mingrelica firefly luciferase (Luc)—the “red” mutant with λ_max.em = 590 nm (RedLuc) and the “green” mutant with λ_max.em = 550 nm (GreenLuc)—were tested as the donors. The water‐soluble Alexa Fluor 610× (AF) dye was selected as the acceptor because its two absorption maxima, located at 550 and 610 nm, are close to the bioluminescence maxima of the GreenLuc and RedLuc, respectively. The methods for the synthesis of the luciferase–progesterone (Luc–Pg) conjugate and the conjugate of the dye and the polyclonal antiprogesterone antibody (AF–Ab) were developed. Both conjugates retained their functional properties, had high antigen–antibody binding activity, and demonstrated a high BRET signal. The homogeneous immunoassay system based on the BRET from the firefly luciferase to the synthetic dye was established to assay progesterone as a model antigen. Optimization of the assay conditions, the composition of the reaction mixture, and the concentrations of the donor and the acceptor made it possible to reach the minimum detectable progesterone concentration of 0.5 ng mL^?1.     

Development of a Quadruple Imaging Modality by Using Nanoparticles

The combination of nanotechnology with molecular imaging has great potential for the development of diagnostics and therapeutics, and multimodal imaging enables versatile applications from cell tracking in animals to clinical applications. Herein, we report a multimodal nanoparticle imaging system that is capable of concurrent fluorescence, bioluminescence, bioluminescence resonance energy transfer (BRET), positron emission tomography (PET) and magnetic resonance (MR) imaging in vivo. A cobalt–ferrite nanoparticle surrounded by rhodamine (MF) was conjugated with luciferase (MFB) and p‐SCN? bn? NOTA (2‐(4‐isothiocyanatobenzyl)‐1,4,7‐triazacyclonane‐1,4,7‐triacetic acid) followed by ⁶⁸GaCl₃ (magnetic‐fluorescent‐bioluminescent‐radioisotopic particle, MFBR). Confocal microscopy revealed good transfection efficiency of MFB into cells and BRET was also observed in MFB. A good correlation among rhodamine, luciferase, and ⁶⁸GaCl₃ was found in MFBR, and the activities of each imaging modality increased dose‐dependently with the amount of MFBR in the C6 cells. In vivo optical images were acquired from the thighs of mice after intramuscular and subcutaneous injections of MFBR‐laden cells. MicroPET and MR images showed intense radioactivity and ferromagnetic intensities with MFBR‐laden cells. The multimodal imaging strategy could be used as potential imaging tools to track cells.     

Tyr72 and Tyr80 are Involved in the Formation of an Active Site of a Luciferase of Copepod Metridia longa

Luciferase of copepod Metridia longa (MLuc) is a naturally secreted enzyme catalyzing the oxidative decarboxylation of coelenterazine with the emission of light. To date, three nonallelic isoforms of different lengths (17–24 kDa) for M. longa luciferase have been cloned. All the isoforms are single‐chain proteins consisting of a 17‐residue signal peptide for secretion, variable N‐terminal part and conservative C‐terminus responsible for luciferase activity. In contrast to other bioluminescent proteins containing a lot of aromatic residues which are frequently involved in light emission reaction, the C‐terminal part of MLuc contains only four Phe, two Tyr, one Trp and two His residues. To figure out whether Tyr residues influence bioluminescence, we constructed the mutants with substitution of Tyr to Phe (Y72F and Y80F). Tyrosine substitutions do not eliminate the ability of luciferase to bioluminescence albeit significantly reduce relative specific activity and change bioluminescence kinetics. In addition, the Tyr replacements have no effect on bioluminescence spectrum, thereby indicating that tyrosines are not involved in the emitter formation. However, as it was found that the intrinsic fluorescence caused by Tyr residues is quenched by a reaction substrate, coelenterazine, in concentration‐dependent manner, we infer that both tyrosine residues are located in the luciferase substrate‐binding cavity.     

Luciferase-streptavidin fusion proteins: Preparation and properties

We constructed plasmids encoding genes of fusion proteins of a thermostable mutant of Luciola mingrelica firefly luciferase (Luc) and streptavidin (SA) with the polyhistidine sequence (His₆) at the N- or C-terminus of the protein: SA-Luc-His₆, His₆-SA-Luc, Luc-SA-His₆. Fusion proteins were produced and purified; their composition, luciferase activity, thermal stability, bioluminescence spectra, and biotin-binding capacity were investigated. Streptavidin introduction does not affect the bioluminescence spectra, but it decreases the thermal stability twofold at 47°C. It was shown by size-exclusion chromatography that, depending on the plasmid structure, the fusion proteins were expressed as dimers, tetramers, and larger oligomers, which differ in luciferase activity and biotin-binding capacity. The His₆-SA-Luc fusion protein demonstrated the most optimal properties.     

Global DNA Methylation Level Monitoring by methyl-CpG Binding Domain-Fused Luciferase

DNA methylation is an epigenetic modification that represses gene expression. In cancer cells, alterations of the DNA methylation state in promoter regions and repetitive DNA sequences are observed; therefore, DNA methyltransferase inhibitors have been the focus of interest as potential anticancer drugs. We previously reported a simple global DNA methylation level-sensing assay using methyl-CpG binding domain (MBD) fused to luciferase (MBD-luciferase). In the assay, the MBD-luciferase binds to methyl-CpG sites on genomic DNA. Subsequently, bioluminescence resonance energy transfer (BRET) between the luciferase and a fluorescent DNA intercalating dye generates a signal that is dependent on DNA methylation level. In this study, we investigated whether global DNA hypomethylation induced by a DNA methyltransferase inhibitor or nutrient can be monitored by the BRET assay. 5-Aza-2′-deoxycytidine and folic acid were utilized as the DNA-methyltransferase inhibitor and nutrient that affect DNA methylation in cells. The HeLa cells were cultured with the inhibitor or in folic acid-deficient medium and their global DNA methylation levels measured. Both time- and concentration-dependent hypomethylation were detected by the BRET assay. These results demonstrate that global DNA hypomethylation can be monitored by the BRET assay, indicating that the assay is applicable to cell-based screening of DNA-methyltransferase inhibitors.     

Activities, kinetics and emission spectra of bacterial luciferase-fluorescent protein fusion enzymes

A new approach to alter bacterial bioluminescence color was developed by fusing Vibrio harveyi luciferase with the coral Discosoma sp. fluorescent protein mOrange, a homolog of the Aequorea green fluorescent protein. Attachment of mOrange to the N- or C-terminus of luciferase α or β subunit, via a 5 or 10 residue linker, produced fully active fusion enzymes. However, only the fusion of mOrange to the N-terminus of luciferase α produced a new 560 nm emission. The differences in emission color by two such fusion enzymes from that of the wild-type luciferase (λ(max) 490 nm) were evident by eye or photographically with the aid of cut-off optical filters. In nonturnover reactions, light decay rates of fusion enzyme remained the same when monitored as the full-spectrum light or at 480 nm (from the luciferase emitter) or 570 nm (from mOrange). No 560 nm emission component was observed with a mixture of luciferase and free mOrange. These findings support that the 560 nm emission by the fusion enzyme was due to bioluminescence resonance energy transfer from luciferase to mOrange. We believe that the same approach could also alter the bacterial bioluminescence color by covalent attachment of other suitable fluorescent proteins or chromophores to luciferase.     

Covalent split protein fragment-DNA hybrids generated through N-terminus-specific modification of proteins by oligonucleotides

Semisynthetic protein-DNA hybrid molecules have recently attracted much attention as valuable tools for bioanalytical chemistry and nanobiotechnology. Here we describe a synthetic method for conjugating oligonucleotides to the N-terminus of recombinant proteins. Our strategy involves the conversion of amine-terminated oligonucleotides to thioester-functionalized oligonucleotides by using a bifunctional reagent bearing an N-hydroxysuccinimide ester and benzyl thioester group, followed by native chemical ligation with proteins containing an N-terminal cysteine. We applied this technique to construct split luciferase fragment-DNA hybrid systems in which the catalytic activity of split luciferase is restored by the re-assembly of each fragment through a specific DNA-protein or DNA-DNA interaction. Split protein fragment-DNA hybrids will offer new opportunities to explore the potential of protein-DNA conjugates for various applications.     

Rapid,single-step nucleic acid detection

A rapid detection method for nucleic acid based on bioluminescence resonance energy transfer (BRET) from the luminescence donor Renilla luciferase to an acceptor quantum dot upon oligonucleotide probe hybridization has been developed. Utilizing a competitive assay, we detected the target nucleic acid by correlating the BRET signal with the amount of target present in the sample. This method allows for the detection of as little as 4 pmol (20 nM) of nucleic acid in a single-step, homogeneous format both in vitro in a buffer matrix as well as in a cellular matrix. Using this method, one may perform nucleic acid detection in as little as 30 min, showing much improvement over time-consuming blotting methods and solid-phase methods which require multiple wash steps to remove unbound probe. This is the first report on the use of quantum dots as a BRET acceptor in the development of a nucleic acid hybridization assay. An erratum to this article can be found at     

Split-luciferase complementary assay: applications,recent developments,and future perspectives

Bioluminescent systems are considered as potent reporter systems for bioanalysis since they have specific characteristics, such as relatively high quantum yields and photon emission over a wide range of colors from green to red. Biochemical events are mostly accomplished through large protein machines. These molecular complexes are built from a few to many proteins organized through their interactions. These protein–protein interactions are vital to facilitate the biological activity of cells. The split-luciferase complementation assay makes the study of two or more interacting proteins possible. In this technique, each of the two domains of luciferase is attached to each partner of two interacting proteins. On interaction of those proteins, luciferase fragments are placed close to each other and form a complemented luciferase, which produces a luminescent signal. Split luciferase is an effective tool for assaying biochemical metabolites, where a domain or an intact protein is inserted into an internally fragmented luciferase, resulting in ligand binding, which causes a change in the emitted signals. We review the various applications of this novel luminescent biosensor in studying protein–protein interactions and assaying metabolites involved in analytical biochemistry, cell communication and cell signaling, molecular biology, and the fate of the whole cell, and show that luciferase-based biosensors are powerful tools that can be applied for diagnostic and therapeutic purposes.     

An Integrated Approach toward NanoBRET Tracers for Analysis of GPCR Ligand Engagement

Gaining insight into the pharmacology of ligand engagement with G-protein coupled receptors (GPCRs) under biologically relevant conditions is vital to both drug discovery and basic research. NanoLuc-based bioluminescence resonance energy transfer (NanoBRET) monitoring competitive binding between fluorescent tracers and unmodified test compounds has emerged as a robust and sensitive method to quantify ligand engagement with specific GPCRs genetically fused to NanoLuc luciferase or the luminogenic HiBiT peptide. However, development of fluorescent tracers is often challenging and remains the principal bottleneck for this approach. One way to alleviate the burden of developing a specific tracer for each receptor is using promiscuous tracers, which is made possible by the intrinsic specificity of BRET. Here, we devised an integrated tracer discovery workflow that couples machine learning-guided in silico screening for scaffolds displaying promiscuous binding to GPCRs with a blend of synthetic strategies to rapidly generate multiple tracer candidates. Subsequently, these candidates were evaluated for binding in a NanoBRET ligand-engagement screen across a library of HiBiT-tagged GPCRs. Employing this workflow, we generated several promiscuous fluorescent tracers that can effectively engage multiple GPCRs, demonstrating the efficiency of this approach. We believe that this workflow has the potential to accelerate discovery of NanoBRET fluorescent tracers for GPCRs and other target classes.     

A Semisynthetic Bioluminescence Sensor for Ratiometric Imaging of Metal Ions In Vivo Using DNAzymes Conjugated to An Engineered Nano-Luciferase

DNA-based probes have gained significant attention as versatile tools for biochemical analysis, benefiting from their programmability and biocompatibility. However, most existing DNA-based probes rely on fluorescence as the signal output, which can be problematic due to issues like autofluorescence and scattering when applied in complex biological materials such as living cells or tissues. Herein, we report the development of bioluminescent nucleic acid (bioLUNA) sensors that offer laser excitation-independent and ratiometric imaging of the target in vivo. The system is based on computational modelling and mutagenesis investigations of a genetic fusion between circular permutated Nano-luciferase (NLuc) and HaloTag, enabling the conjugation of the protein with a DNAzyme. In the presence of Zn²⁺, the DNAzyme sensor releases the fluorophore-labelled strand, leading to a reduction in bioluminescent resonance energy transfer (BRET) between the luciferase and fluorophore. Consequently, this process induces ratiometric changes in the bioluminescent signal. We demonstrated that this bioLUNA sensor enabled imaging of both exogenous Zn²⁺ in vivo and endogenous Zn²⁺ efflux in normal epithelial prostate and prostate tumors. This work expands the DNAzyme sensors to using bioluminescence and thus has enriched the toolbox of nucleic acid sensors for a broad range of biomedical applications.     

Sensing Protein Surfaces with Targeted Fluorescent Receptors

A methodology for creating fluorescent molecular sensors that respond to changes that occur on the surfaces of specific proteins is presented. This approach, which relies on binding cooperatively between a specific His‐tag binder and a nonspecific protein‐surface receptor, enabled the development of a sensor that can track changes on the surface of a His‐tag‐labeled calmodulin (His‐CaM) upon interacting with metal ions, small molecules, and protein binding partners. The way this approach was used to detect dephosphorylation of an unlabeled calmodulin‐dependent protein kinase II (CaMKII), and the binding of Bax BH3 to His‐tagged B‐cell lymphoma 2 (Bcl‐2) protein is also presented.     

Luciferase‐Induced Photouncaging: Bioluminolysis

Bioluminescence resonance energy transfer (BRET) has been widely used for studying dynamic processes in biological systems such as protein–protein interactions and other signaling events. Aside from acting as a reporter, BRET can also turn on functions in living systems. Herein, we report the application of BRET to performing a biorthogonal reaction in living cells; namely, releasing functional molecules through energy transfer to a coumarin molecule, a process termed bioluminolysis. An efficient BRET from Nanoluc‐Halotag chimera protein (H‐Luc) to a coumarin substrate yields the excited state of coumarin, which in turn triggers hydrolysis to uncage a target molecule. Compared to the conventional methods, this novel uncaging system requires no external light source and shows fast kinetics (t_1/2<2 min). We applied this BRET uncaging system to release a potent kinase inhibitor, ibrutinib, in living cells, highlighting its broad utility in controlling the supply of bioactive small molecules in vivo.     

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.     

ENERGY TRANSFER VIA PROTEIN-PROTEIN INTERACTION IN RENILLA BIOLUMINESCENCE

Abstract—Radiationless energy transfer is known to play biologically important roles in both photosynthesis and bioluminescence. In photosynthesis, accessory pigments serve as "antennae", transferring excitation energy into the "reaction centers". In the bioluminescent coelenterates, energy is transferred from the site of reaction via an accessory protein known as the green-fluorescent protein (GFP). Coelenterate bioluminescence systems such as that of the sea pansy, Renilla , are well characterized biochemically, and their energy transfer process can be duplicated in vitro using isolated and purified components. We have measured efficient in vitro energy transfer from the electronic excited state of the enzyme-bound oxyluciferin to the green-fluorescent protein at protein concentrations of 0.1 μ M . We have also demonstrated a 1:l complex between these proteins, under conditions of energy transfer, by the chromato-graphic technique of Hummel and Dreyer. These observations indicate that bioluminescent energy transfer is mediated via protein-protein interaction. Furthermore, with inter-species cross-reaction studies and protein modification techniques we have shown that the interaction between luciferase and GFP is highly specific. These features make the Renilla system an attractive alternative to the photosynthetic systems as a tool for studying radiationless energy transfer.     

QM/MM Study on the Light Emitters of Aequorin Chemiluminescence,Bioluminescence, and Fluorescence: A General Understanding of the Bioluminescence of Several Marine Organisms

Aequorea victoria is a type of jellyfish that is known by its famous protein, green fluorescent protein (GFP), which has been widely used as a probe in many fields. Aequorea has another important protein, aequorin, which is one of the members of the EF‐hand calcium‐binding protein family. Aequorin has been used for intracellular calcium measurements for three decades, but its bioluminescence mechanism remains largely unknown. One of the important reasons is the lack of clear and reliable knowledge about the light emitters, which are complex. Several neutral and anionic forms exist in chemiexcited, bioluminescent, and fluorescent states and are connected with the H‐bond network of the binding cavity in the protein. We first theoretically investigated aequorin chemiluminescence, bioluminescence, and fluorescence in real proteins by performing hybrid quantum mechanics and molecular mechanics methods combined with a molecular dynamics method. For the first time, this study reported the origin and clear differences in the chemiluminescence, bioluminescence and fluorescence of aequorin, which is important for understanding the bioluminescence not only of jellyfish, but also of many other marine organisms (that have the same coelenterazine caved in different coelenterazine‐type luciferases).     

Luciferin‐Regenerating Enzyme Crystal Structure Is Solved but its Function Is Still Unclear

Contribution of luciferin‐regenerating enzyme (LRE) for in vitro recycling of D‐luciferin has been reported. According to crystal structure of LRE, it is a beta‐propeller protein which is a type of all β‐protein architecture. In this overview, reinvestigation of the luciferase‐based LRE assays and its function is reported. Until now, sequence of LRE genes from four different species of firefly has been reported. In spite of previous reports, T‐LRE (from Lampyris turkestanicus) was cloned and expressed in Escherichia coli as well as Pichia pastoris in a nonsoluble form as inclusion body. According to recent investigations, bioluminescent signal of soluble T‐LRE–luciferase‐coupled assay increased and then reached an equilibrium state in the presence of D‐cysteine. In addition, the results revealed that both D‐ and L‐cysteine in the absence of T‐LRE caused a significant increase in bioluminescence intensity of luciferase over a long time. Based on activity measurements and spectroscopic results, D‐cysteine increased the activity of luciferase due to its redox potential and induction of conformational changes in structure and kinetics properties. In conclusion, in spite of previous reports on the effect of LRE (at least T‐LRE) on luciferase activity, most of the increase in luciferase activity is caused by direct effect of D‐cysteine on structure and activity of firefly luciferase. Moreover, bioinformatics analysis cannot support the presence of LRE in peroxisome of photocytes in firefly lanterns.     

Buffer enhanced bioluminescence resonance energy transfer sensor based on Gaussia luciferase for in vitro detection of protease

Bioluminescence resonance energy transfer (BRET) has gained favors in recent years as a detection technology for protease activity due to its extreme reliability, high sensitivity and low intrinsic backgrounds. Because of the sensitivity of the donors, substrates and the acceptors, it is expected that BRET systems are sensitive to buffer environments. However, no systematic study has been reported on how buffer components would affect the BRET ratio, and thus affect the determination of protease activity based on BRET. We present here that several environmental factors, including buffer agents, pH and divalent metal ions, influenced BRET ratio significantly, when humanized Gaussia luciferase (hGluc) was utilized as the donor and enhanced yellow fluorescence protein (EYFP) as the acceptor. Based on these findings, an enhancing solution was optimized to improve the performance of the BRET sensor for analysis of enterokinase activity in vitro, resulting in 10-fold and 7-fold improvement of the sensitivity and the detection limit, respectively. We anticipate the system will be applicable for improving performance of other in vitro BRET protease sensors, especially when the optimal conditions for protease activity would severely affect the BRET signal.