Expression, purification and characterization of the secreted luciferase of the copepod Metridia longa from Sf9 insect cells

Metridia luciferase is a secreted luciferase from a marine copepod and uses coelenterazine as a substrate to produce a blue bioluminescence (λ_max = 480 nm). This luciferase has been successfully applied as a bioluminescent reporter in mammalian cells. The main advantage of secreted luciferase as a reporter is the capability of measuring intracellular events without destroying the cells or tissues and this property is well suited for development of high throughput screening technologies. However because Metridia luciferase is a Cys-rich protein, Escherichia coli expression systems produce an incorrectly folded protein, hindering its biochemical characterization and application for development of in vitro bioluminescent assays. Here we report the successful expression of Metridia luciferase with its signal peptide for secretion, in insect (Sf9) cells using the baculovirus expression system. Functionally active luciferase secreted by insect cells into the culture media has been efficiently purified with a yield of high purity protein of 2–3 mg/L. This Metridia luciferase expressed in the insect cell system is a monomeric protein showing 3.5-fold greater bioluminescence activity than luciferase expressed and purified from E. coli. The near coincidence of the experimental mass of Metridia luciferase purified from insect cells with that calculated from amino acid sequence, indicates that luciferase does not undergo post-translational modifications such as phosphorylation or glycosylation and also, the cleavage site of the signal peptide for secretion is at VQA-KS, as predicted from sequence analysis.     

The use of the luciferase reporter system forin planta gene expression studies

The properties of the firefly luciferase (LUC) make it a very good nondestructive reporter to quantify and image transgene promoter activity in plants. The short half-life of the LUC mRNA and protein, and the very limited regeneration of the LUC protein after reacting with luciferin, enables monitoring of changes in gene activity with a high time resolution. However, the ease at which luciferase activity is measuredin planta, using a light sensitive camera system (2D-luminometer), contrasts sharply with the complications that arise from interpreting the results. A variegated pattern of luciferase activity, that is often observed inin planta measurements, might either be caused by differences in influx, availability of the substrates (luciferin, oxygen, ATP) or by local differences in reporter gene activity. Here we tested the possible contribution of differences in the availability of each substrate to the variegatedin planta luciferase activity, and we show whenin planta luciferase activity is measured under substrate equilibrium conditions and can be related to the promoter activity of the reporter gene. Furthermore, we demonstrate the effects of protein stability, apparent half-life of luciferase activity, regeneration of luciferase and pH on thein vivo andin vitro luciferase measurements. The combined results give the prerequisites for the correct utilisation of the luciferase reporter system, especially forin vivo gene expression studies in plant research.     

Thein vivo pattern of firefly luciferase expression in transgenic plants

Expression of the firefly luciferase gene in transgenic plants produces light emission patterns when the plants are supplied with luciferin. We explored whether inin vivo pattern of light emission truly reveals the pattern of luciferase gene expression or whether it reflects other parameters such as the availability of the substrate, luciferin, or the tissue-specific distribution of organelles in which luciferase was localized. The tissue-specific distribution of luciferase activity and thein vivo pattern of light were examined when the luciferase gene was driven by different promoters and when luciferase was redirected from the peroxisome, where it is normally targeted, to the chloroplast compartment. It was found that the distribution of luciferase activity closely correlated with the tissue-specific pattern of luciferase mRNA. However, thein vivo light pattern appeared to reflect not only tissue-specific distribution of luciferase activity, but also the pattern of luciferin uptake.     

Expression of the Renilla reniformis Luciferase Gene in Mammalian Cells

A cDNA encoding the Renilla reniformis luciferase was expressed in simian and murine cells in a transient and stable manner, respectively. Light emission catalyzed by luciferase was detected from transfected cells both in vitro and in vivo. This work establishes the Renilla luciferase gene as a new efficient marker of gene expression in mammalian cells.     

Construction and testing of an intron-containing luciferase reporter gene from<Emphasis Type="Italic">Renilla reniformis</Emphasis>

We describe a newRenilla reniformis luciferase reporter gene,RiLUC, which was designed to allow detection of luciferase activity in studies involvingAgrobacterium-based transient expression studies. TheRLUC gene was altered to contain a modified intron from the castor bean catalase gene while maintaining consensus eukaryotic splicing sites recognized by the plant spliceosome.RLUC andRiLUC reporter genes were fused to the synthetic plant SUPER promoter. Luciferase activity within agrobacteria containing the SUPER-RLUC construct increased during growth in culture. In contrast, agrobacteria harboring the SUPER-RiLUC gene fusion showed no detectable luciferase activity. Agrobacteria containing these gene fusions were cotransformed with a compatible normalization plasmid containing a cauliflower mosaic virus 35S promoter (CaMV) joined to the firefly luciferase coding region (FiLUC) and infused into tobacco leaf tissues through stomatal openings. The kinetics of luciferase production from theRLUC orRiLUC reporters were consistent, with expression of theRiLUC gene being limited to transiently transformed plant cells.RiLUC activity from the reporter gene fusions was measured transiently and within stably transformed tobacco leaf tissues. Analysis of stably transformed tobacco plants harboring either reporter gene fusion showed that the intron altered neither the levels of luciferase activity nor tissue-specific expression patterns driven by the SUPER promoter. These results demonstrate that theRiLUC reporter gene can be used to monitor luciferase expression in transient and stable transformation experiments without interference from contaminating agrobacteria.     

EVOLUTION OF BIOLUMINESCENCE IN MARINE DINOFLAGELLATES

Bioluminescence is broadly distributed in marine dinoflagellates and has been intensively studied in Lingulodinium (Gonyaulax) polyedra. In this species, bioluminescence is regulated in a circadian fashion; the enzyme (luciferase) and the luciferin (substrate)‐binding protein are synthesized and degraded on a daily basis. Synthesis of both proteins is regulated at the level of translation. The L. polyedra luciferase gene is composed of three contiguous domains that are greater than 75% identical at the nucleic acid level. Possible explanations for the high degree of sequence conservation include: (1) the domains evolved through a recent duplication event; (2) the sequence similarity is maintained by a molecular process such as gene conversion; or (3) there is a functional role associated with the primary nucleic acid sequence, such as in the translational regulation of luciferase expression. The phylogenetic relationship of dinoflagellates predicted from 18S rDNA genes provides a framework for examining the molecular evolution of the regulation of luciferase expression and of genes encoding luciferase and the luciferin‐binding protein. In particular, we are examining the evolution of the circadian rhythm of bioluminescence and of luciferase abundance, the presence/absence of the luciferin‐binding protein, and the molecular structure of the luciferase gene. We anticipate that this approach will distinguish between regions of the luciferase molecule that are conserved for enzyme function versus those concerned with the regulation of protein expression. In addition, it will provide insight into the evolution of the regulatory processes and pathways.     

Mutant firefly luciferase enzymes resistant to the inhibition by sodium chloride

Objectives

Firefly luciferase, one of the most extensively studied enzymes, has numerous applications. However, luciferase activity is inhibited by sodium chloride. This study was aimed at obtaining mutant luciferase enzymes resistant to the sodium chloride inhibition.

Results

We first obtained two mutant luciferase enzymes whose inhibition were alleviated and determined the mutations to be Val288Ile and Glu488Val. Under medical dialysis condition (140 mM sodium chloride), the wild type was inhibited to 44% of its original activity level. In contrast, the single mutants, Val288Ile and Glu488Val, retained 67% and 79% of their original activity, respectively. Next, we introduced Val288Ile and Glu488Val mutations into wild-type luciferase to create a double mutant using site-directed mutagenesis. Notably, the double mutant retained its activity more than 95% of that in the absence of sodium chloride.

Conclusions

The mutant luciferase, named luciferase CR, was found to retain its activity in various concentrations of sodium chloride. The luciferase CR may be extensively useful in any bioassay which includes firefly luciferase and is employed in the presence of sodium chloride.

     

Introduction of a plant intron into the luciferase gene ofPhotinus pyralis

We describe a new luciferase reporter gene,luc ^INT, for early detection of luciferase activity inAgrobacterium transformation studies, and present improved techniques for the extraction of luciferase that decrease the time needed to quantitate luciferase activity. Theluc ^INT reporter gene combines the PIV2 intron fromGUS ^INT withluc ^*, the modified luciferase gene.luc ^INTis expressed in plant cells but not inAgrobacterium, allowing earlier detection of gene expression in the presence ofAgrobacterium during transformations in tobacco leaf discs. Stable expression levels ofluc ^INT andluc ^* in tobacco suspension cultures are compared for two different promoters. The nucleotide sequence data for the gene will appear in the EMBL, GenBank and DDBJ Nucleotide Sequence Databases under the accession number U84006.     

Expression and quantification of firefly luciferase under control of Rhizobium meliloti symbiotic promoters

We have tested the use of firefly luciferase for monitoring regulated symbiotic nitrogen fixation gene expression. Broad-host-range plasmids carrying translational fusions of Rhizobium meliloti nifH, fixA and nifA promoters were constructed. Despite low levels of promoter activity the absence of Escherichia coli endogenous luminescence and the high sensitivity of the bioluminescent assay for firefly luciferase allowed rapid screening for functional luciferase expression. Plasmids containing symbiotic promoter-luc fusions were established in R. meliloti. Luciferase activity was detected and measured in both vegetative and symbiotic cells giving comparable results with those obtained by beta-galactosidase assays. In addition, the luciferase assay was quicker, more sensitive and could be carried out with unrestricted cells. Furthermore, bioluminescence was high enough in alfalfa nodules containing nifH—luc fusion to be observed by a dark-adapted eye and photographed.     

Expression of firefly luciferase gene in Erwinia amylovora

In this study we describe an ef?cient stable genetic transformation of the phytopathogenic bacterium Erwinia amylovora using a recombinant expression vector encoding the ?re?y luciferase gene of Photinus pyralis, which is further controlled by IPTG‐inducible promoter. Stably transformed E. amylovora cells maintain the same infectivity as the wild‐type strain and, after induction with IPTG, produce luciferase. Luminescence produced by the action of luciferase on an exogenous substrate was easily detectable by a simple and rapid bioluminescent assay (BL). The transformed E. amylovora strain maintains the same high emission level, even after passage in pears, until about 15 days post‐infection. Our ?ndings therefore show that the luciferase assay can be conveniently used to follow the bacterial movement in plant tissue and its dissemination in controlled environments.     

AtLTP1 luciferase expression during carrot somatic embryogenesis

The carrot (Daucus carota L.) EP2 gene encodes a Lipid Transfer Protein (LTP) which is expressed during protoderm formation in developing embryos. To develop a vital reporter system for gene expression during somatic embryo development a 1.1 kB fragment of the Arabidopsis thaliana LTP1 promoter was fused to the firefly luciferase (LUC) coding sequence. The AtLTP1 luciferase expression pattern in transformed carrot suspension cultures was identical to the expression pattern of the endogenous carrot EP2 gene. Cell tracking experiments revealed that all somatic embryos were derived from AtLTP1 luciferase expressing cell clusters. However, not all cell clusters that expressed the AtLTP1 luciferase reporter gene developed into a somatic embryo, suggesting that initiation of an embryogenic pathway in tissue culture does not always lead to development of a somatic embryo.     

Secretion of firefly luciferase in E.coli

Summary A DNA segment carrying the full-length, intronless firefly luciferase gene was inserted into the high expression secretion vector, pIN-III -ompA. Upon induction of gene expression, luciferase activity was detected in extracts prepared from periplasmic fractions. The results indicated that the OmpA signal peptide was able to direct secretion of firefly luciferase across the cytoplasmic membrane. This has important implications for using this luciferase as a reporter in studying protein export and targeting.     

L5 luciferase reporter mycobacteriophages: a sensitive tool for the detection and assay of live mycobacteria

Recombinant bacteriophages provide efficient delivery systems for introducing reporter genes into specific bacterial hosts. We have constructed mycobacteriophage L5 recombinants carrying the firefly luciferase gene inserted into the tRNA region of the phage genome. Infection of Mycobacterium smegmatis by these phages results in expression of the luciferase gene and light emission. Fortuitously, the luciferase gene is expressed continuously in lysogens surviving infection. Synthesis of luciferase from a mycobacterial promoter created by cloning enables the detection of extremely small numbers of M. smegmatis cells. These reporter phages can be used to discriminate between drug-sensitive and drug-resistant strains of M. smegmatis, and may provide tools for the rapid identification and classification of antimycobacterial agents.     

Luciferase of Luciola mingrelica fireflies. Kinetics and regulation mechanism

Biochemical properties, spectral parameters of bioluminescence and reaction kinetics for Luciola mingrelica firefly luciferase are described and analysed. The kinetic scheme of the enzymatic process is proposed and discussed. Allosteric regulation of luciferase activity by ATP and its analogues is considered and binding Mg²⁺ to luciferase shown to increase its activity. Regulation mechanism of luciferase activity by phospholipids is analysed and choline-containing phospholipids shown to be specific luciferase activators. Some properties of firefly luciferae and the luciferase synthesized during firefly mRNA translation in frog oocytes are compared.     

Bovine serum albumin interacts with bacterial luciferase

Bovine serum albumin (BSA) affects the amount of light obtained from bacterial luciferase by competing with luciferase for one of the luciferase substrates, the aldehyde. At low aldehyde concentrations BSA behaves as an inhibitor, but at high aldehyde concentrations BSA relieves substrate inhibition. BSA reversibly binds decanal with a K_si = 3.36 μmol/l, approximately half the affinity of luciferase for decanal (K_M = 1.5 μmol/l). BSA also increased the rate of intermediate II dark decay. The data suggest that this involves a direct protein-protein (BSA-luciferase) interaction.     

The construction of a glucose-sensing luciferase

A novel luminescence-based glucose-sensing molecule was created by combining a galactose-/glucose-binding protein (GGBP) with luciferase. The glucose-sensing luciferase (GlcLuc) was constructed using a GGBP fused with a large domain and a small domain of Firefly luciferase (Lluc and Sluc). The luminescence intensity-based analysis with E. coli recombinant protein showed that the GlcLuc had luciferase activity in glucose or galactose in a concentration-dependent manner (K_d = 3.9 μM for glucose and 11 μM for galactose), and that the increase in the activity saturated within one minute after the injection of the ligands. These results indicated that the conformation change of the GGBP moiety following the ligand binding effectively induced the reconstitution of the GGBP-fused split luciferase. The Asp459Asn mutation, which was expected to lead to a glucose specific binding ability, was then introduced into the GlcLuc. The GlcLuc mutant showed the luciferase activity increasing only with the increase of glucose concentration, but not with that of galactose. Our results demonstrate that the GGBP fused with a split luciferase, which is reconstituted rapidly and specifically in the presence of glucose, provides a novel glucose-sensing system based on luminescence and may also contribute to the construction of luminescence-based sensing molecules for other substrates using other PBPs.     

Luciferase cDNA from Japanese firefly,Luciola cruciata: Cloning,structure and expression in Escherichia coli

We have cloned the cDNA for luciferase from lantern poly(A)⁺ RNA of a Japanese firefly, Luciola cruciata (Genji botaru in Japanese). This cDNA directed the synthesis of enzymatically active luciferase under the control of the lac promoter in Escherichia coli. The amino acid sequence predicted from the cDNA sequence shows that Genji firefly luciferase consists of 548 amino acids and has a molecular weight of 60,024. Considerable sequence homology was found upon the comparison of the Genji and North American firefly luciferases.     

The use of luciferase as a reporter for response of plant cells to the fireblight pathogen Erwinia amylovora

Summary We have introduced the gene encoding luciferase from Photinus pyralis into pear and tobacco cells in order to judge the reaction of plant tissue to damaging conditions such as incubation at high temperature or inoculation with a pathogen. The constitutive expression of the luciferase gene via a strong promoter slowly decreased during propagation of the transformed pear cell line. After various stress treatments the resulting luciferase activity and the ATP content of the plant cells were determined by bioluminescence and found to correspond to each other. Inoculation of transformed pear cells with Erwinia amylovora resulted in a continuous decrease of luciferase activity in contrast to tobacco cells, where the enzyme activity was significantly higher in the first period after inoculation with bacteria compared to the untreated control cells. The pattern of the luciferase activity reflected the slow damage of the host-plant cells by E. amylovora and the elevated metabolism of the non-host cells after inoculation with the pathogen.Abbreviations 2,4-D 2,4-dichloro-phenoxyacetic acid - CaMV Cauliflower mosaic virus - DTT dithiothreitol - EDTA ethylenediaminetetraacetate - FDA fluorescein diacetate - HEPES (hydroxyethyl)piperazine(ethanesulfonic acid) - HR hypersensitive reaction - Tris tris (hydroxymethyl)amino-methane